genetics and breeding of groundnut -...
TRANSCRIPT
Faujdar Singh and D.L. Oswalt
International Crops Research Institute for the Semi-Arid Tropics Patancheru, Andhra Pradesh 502 324, India
1991
Ski l l Development Series no. 4
Compiled by
Genetics and Breeding of Groundnut
ICRISAT
Human Resource Development Program
Genetics and Breeding of Groundnut
Compiled by
Faujdar Singh and D.L. Oswalt
Skill Development Series no.4
International Crops Research Institute for the Semi-Arid Tropics Patancheru, Andhra Pradesh 502 324, India
1991
Human Resource Development Program
ICRISAT
Human Resource Development Program
Publications in this Skill Development Series (SDS) are issued semiformally for limited distribution to program participants, colleagues, and collaborators. Copies may be requested by the SDS number. Constructive criticism from readers is welcomed by: Program Leader, Human Resource Development Program, ICRISAT.
Information has been taken from published and unpublished reports. This publication should not be cited as a reference.
Comments, suggestions, and encouragement from Dr S.N. Nigam, Dr S.L. Dwivedi, Dr A.K. Singh, Dr D. McDonald, and Dr Y. L. Nene for compiling this document are gratefully acknowledged. T h a n k s to Mr S.V. Prasad Rao and Mrs Jagatha Seetharaman for computerization of this m a n u s c r i p t .
Acknowledgements
CONTENTS
Introduction 5
Genetic Studies in Groundnut 5
Qualitative Inheritance 5 Linkage Studies 9 Quantitative Inheritance 9 Heritability and Genetic Advance 9 Gene Effects 11 Heterosis 13 Character A s s o c i a t i o n 14 Genotype x Environment (GxE) Interactions 15
Groundnut Breeding 16
Germplasm Collection and Evaluation 17 Hybridization 17 Choice of Selection Procedures for Groundnut 21
Utilization of Wild Species 22
Mutation Breeding 23
MP 1. E s t a b l i s h i n g Groundnut Crossing Nurseries 25 MP 2. Emasculation and Crossing in Groundnut 27 MP 3. Handling Crosses of Groundnut 29 MP 4. Incorporation of Genes from Wild Diploids
into Cultivated Groundnut 32 MP 5. Induced Mutagenesis 35 MP 6. Handling the Mutation Breeding Population 37
References 38
Evaluation 50
Inheritance studies of plant and flower characters (Table 1 ) , p o d and seed characters (Table 2 ) , and disease resistance (Table 3) are summarized while linkage studies are discussed separately.
T a b l e 1 . I n h e r i t a n c e s t u d i e s o f p l a n t a n d f l o w e r c h a r a c t e r s i n g r o u n d n u t .
Character (s) Genetics Reference (s)
Growth habit
Spreading (S) vs b u n c h ( B ) t y p e
Spreading dominant S x B = 3S:1B (monogenic)
Patel et a l . 1 9 3 6 ; Dalai 1962; Jadhav and Shinde 1979
Spreading digenic B x S = 15S :1B (duplicate) B x B = 9S :7B (complementary)
Hayes 1933 Patel et al. 1936; Dalai 1962
Bunch type dominant S x B = 3B:1S (monogenic) Hassan and Srivastava
1966a;Balaiah et a l . 1 9 7 7
Semispreading (SS) dominant B x SS = 3SS :1S (monogenic) Balaiah et al. 1977
Growth habit determined by four genes Essomba et al. 1987
SDS no. 4 HRDP 5
Qualitative inheritance
Detailed literature reviews of the inheritance of characters in groundnut have been reported by Hammons (1973) , Wynne and Coffelt (1982), Reddy (1988), and Wynne and Halward (1991).
Genetic Studies in Groundnut
The objective of a crop breeding program is to create variability and select the desirable genotype (s) for cultivation or for breeding p u r p o s e s . Groundnut, being a highly self-pollinated crop, requires special attention in emasculation, crossing, and selection as these p r o c e s s e s require special skills and may be time consuming. Genetic studies assist the breeder in understanding the inheritance mechanism and enhance the efficiency of a breeding program. Considerable progress has b e e n made in genetics and plant breeding of groundnut during the last three decades (see reviews Wynne and Gregory 1981; Wynne and Coffelt 1982; Norden et a l . 1982; Reddy 1988; and Wynne and Halward 1 9 8 9 ) . An attempt has been made to compile the recorded experiences of groundnut breeders and geneticists. Questions are provided to assist in self evaluation of selected skills by the, readers.
Introduction
Table 1. Continued
Character(s) Genetics Reference(s)
Plant type
Spanish Controlled by duplicate genes (Va1 Va1, va2 va2) Hull 1937
Valencia Controlled by double recessive genes (va1 va1, va2 va2) Hull 1937
Runner Controlled by duplicate genes (va1 va1, Va2 Va1) Hull 1937
Dwarfism Recessive to tall (monogenic) Duplicate (15 tall:1 dwarf)
Hull 1937; Bhuiyan 1984 Hayes 1933; Husted 1934; Mohammad et al. 1966; Balaiah et al. 1977
Stem pigmentation Dark or purple dominant to light color (monogenic) 3 dark:l light
Hayes 1933; Patil 1966; Balaiah et al. 1977; Jadhav and Shinde 1979
Purple and green pigmentation controlled by one and two duplicate genes Essomba et al. 1987
Leaf color Dark green foliage dominant to light green (monogenic)
Badami 1923; Dalai 1962
Leaf shape Elliptical-recessive to elliptical-oblong
Hassan 1964
Marrow leaf dominant to normal (monogenic)
Balaiah et al. 1977
Red color of leaf veins dominant to its absence
Hayes 1933
Inflorescence On main stem controlled by two sets of duplicate loci with epistatic action Sequential flowering -controlled by duplicate pairs of recessive genes - monogenic recessive to alternate
Hammons 1971; Wynne 1975 Mouli and Kale 1982
Mouli et a l . 1 9 8 6
Corolla color Dark dominant to light
Orange incomplete dominant to white
Hayes 1933; Patil 1965; Bilquez and Lecomte 1969; Jadhav and Shinde 1979
Kumar and Joshi 1943
Yellow dominant to white controlled by duplicate genes (15 yellow:1 white) Yellow incomplete dominant to white or controlled by additive genes (9 yellow:6 pale yellow:1 white)
Patil 1966; Jadhav and Shinde 1979
Habib et al. 1980
King petal shape
Boat shape dominant to broad or scoop shape (monogenic)
Srivastava 1968
Nodulation Determined by three genes
Nonadditive genes
Essomba et al. 1987; Dutta and Reddy 1988 Phillips et al. 1989
6 HRDP SDS no. 4
T a b l e 2 . I n h e r i t a n c e s t u d i e s o f p o d a n d s e e d c h a r a c t e r s i n g r o u n d n u t .
Character(s) Genetics Reference(s)
Pad size Large pod dominant to small Small pod dominant to large (duplicate gene)
Balaiah et al. 1977 Cahaner 1978
Pod constriction Absence is dominant to its presence (digenic)
Badami 1928
Trigenically inherited Hassan 1964
Controlled by three nuclear and one cytoplasmic factor, complementary duplicate Coffelt and Hammons 1974a
Seed size Large seed is dominant to small seed size Hassan 1964; Balaiah et al.
1977
Controlled by five pairs of genes, four having isodirectional effect Martin 1967
Seed shape Long seed shape dominant to short (digenic); duplicate 15 longs 1 short
Hayes 1933
Flat end of seed dominant to smooth Sibale 1985
Seed number Fewer than three seeds pod-1 dominant to three or more seeds/pod (monogenic) Balaiah et al. 1977
Testa color Monogenic Red x brown = Red Brick red x light tan = Red Red x light rose = Red White x pink or red = 3 whites: 1 red or pink (monogenic)
Badami 1928 Stokes and Hull 1930 Patil 1966
Norden et al. 1988; Branch 1989
Digenic 15:1 ratio Flesh x white = 15F:1W White x red = 15R:1W Pink x white = 15Pk:lW Purple x rose = 15P:lr
Rose x light rose = 15R:llr White x red = 9R:3Rs:4W
Higgins 1940 Higgins 1940 Hammons 1957; 1972 Prasad and Srivastava 1967 Prasad and Srivastava 1967 Srivastava 1968
Purple color inherited by three pairs of genes
Patel et al. 1936; Mohammed et al. 1966; Srivastava 1968
White and purple color inherited by four or five pairs of genes
Hammons 1963; Prasad and Srivastava 1967; Srivastava 1968
White seed coat color dominant to pink or red (monogenic) Norden et al. 1988
Seed dormancy Incomplete dominance to non dormancy (monogenic)
Stokes and Hull 1930; Lin and Lin 1971
Protein content High protein content dominant to low protein Shany 1977
Oil content Low oil content dominant to high oil Shany 1977
Two recessive genes (Ol1 and Ol2) controls high oleic acid character Moore and Knauft 1989
Note: Seed size and testa color are reported as governed by more than three genes.
7 HRDP SDS no. 4
T a b l e 3 . I n h e r i t a n c e s t u d i e s o n d i s e a s e r e s i s t a n c e i n g r o u n d n u t .
Character (s) Genetics Reference (s)
Groundnut rosette A pair of independent comple- de Berchoux 1960; virus (GRV) mentary genes 1 resistant : 15 Nigam and Bock 1990
susceptible
Early and late Resistance is recessive Smartt 1964; Sharief leafspot 1972
Controlled by two or more nuclear genes
Sharief et al. 1978
Quantitatively inherited Sharief et al. 1978; Kornegay et al. 1980; Norden 1980
Additive gene
Multiple recessive genes
Anderson et al. 1986; Green 1985
nonadditive gene action Influenced by cytoplasmic
Nevill 1982
factors, and additive genes Coffelt and Porter Resistance to early and late leafspots independently
1982; 1986
inherited Anderson et al. 1985
Rust Resistance recessive to susceptibility and controlled by two or three genes Bromfield and Bailey 1972 Controlled by duplicate Nigam et al. 1980; recessive genes
Resistance recessive to susceptibility and controlled in additive fashion F2
ratio 1 resistant: 6 inter-
Knauft and Norden 1983; Knauft 1987
mediates 9 susceptible Controlled by additive, additive x additive, and
Tiwari et al. 1984
additive x dominant gene effects Reddy et al. 1987
Necrotic etch Resistance dominant to normal condition with digenic ratio 15 nondiseased : 1 diseased Hammons 1980
Sclerotinia blight Controlled by cytoplasmic Coffelt and Porter 1982 factors
Seed coat Monogenic, duplicate additive splitting and complementary Bovi et al. 1983
Verticillium wilt Duplicate recessive de Berchoux 1960
8 HRDP SDS no. 4
Badami (1923) observed linkage between violet color and hardiness in stems and thin pericarp with small seed. Patel et a l . (1936) reported a n o n r a n d o m assortment of growth habit and branching type in a cross between 'Philippine white' (spreading branched type) and 'Corientes 3' (bunched, and nonbranched type) with a crossover value of 3 0 % . Patil (1965) reported linkage between growth habit and p o d reticulation with a crossover value of 4 0 % ; and stem hairiness with pod reticulation w i t h a crossover value of 3 1 % . Coffelt and Hammons (1973) reported linkage between small seed size and albino seedlings.
Stalker et a l . (1979) reported linkages of late maturity, small seed size, separate p o d cell, and low yield with leafspot resistance in crosses involving cultivated groundnut and wild species (A. c a r d e n a s i i ) .
Balaiah et a l . (1984) suggested linkage involving the genes controlling the growth habit, b r a n c h i n g number of primaries, number of secondaries, p i g m e n t a t i o n on the shoot, and leaflet shape. The crossover between the loci controlling these characters ranges from 6 to 3 9 % . Mouli et a l . (1984) reported linkage between the bifurcate nature of leaf and small size of leaflet. A locus for testa v a r i e g a t i o n (V) and one of the t w o genes controlling nodulation (N) were reported to be linked (Dashiell 1 9 8 3 ) .
Estimates of heritability, genetic advance, gene e f f e c t s , and h e t e r o s i s , h a v e b e e n reported in groundnut.
9 SDS no. 4 HRDP
Heritability and Genetic Advance High heritability combined with high genetic advance was considered an indication of additive genetic variance (Johanson et a l . 1 9 5 5 ) . However, it was reported that heritability values were highly influenced by the environment in groundnut (Lin et a l . 1 9 7 1 ) . T h e heritability and genetic advance estimates are listed in Table 4.
Linkage Studies
Quantitative Inheritance
Table 4. Heritability (H - broad sense and h - narrow sense) and genetic advance (G) studies in groundnut.
Character(s) Component(s) Reference(s)
Pod yield plant-1 High (H) Lin et al. 1971; Reddy 1968; Majumdar et al. 1969; Dixit et al. 1970; Sangha 1973b; Patra 1975; Sandhu and Khera 1976; Lakshmaiah 1978; Gibori et al. 1978
High (h) Moderate (h) Low (H)
Wynne and Rawling 1978; Cahaner 1978 Basu et al. 1986a Bernard 1960; Lin 1966
Mature pods plant-1 High (H) Kulkarni and Albuquerque 1967; Majumdar et al. 1969; Lin et a l . 1 9 7 1 ; Basu and Ashokraj 1969; Alam et al. 1985; Sandhu and Khera 1976; Sivasubramaniam et al. 1977
High (H and G) Dholaria and Joshi 1972; Sangha 1973a; Kushwaha and Tawar 1973; Alam et al. 1985
Low (H) Lin et al. 1971
100 pod mass High (H) Cahaner 1978; Basu and Ashokraj 1969; Dixit et al. 1970
Low (H) Hammons 1974; Lakshmaiah 1978; Xiang et al. 1984
100 seed mass High (H) Basu and Ashokraj 1969; Dixit et al. 1970; Sangha 1973b
High (H and G) Dholaria and Joshi 1972; Sangha 1973a; Kushwaha and Tawar 1973; Badwal et al. 1967; Badwal and Gupta 1968
Moderate (H) and high (G) Alam et al. 1985
Pod length High (H) Kushwaha and Tawar 1973
High (h) Low (H)
Wynne and Rawling 1978 Sibale 1985
Pod breadth High (H) Kushwaha and Tawar 1973
Seeds pod-1 Low (H) Hammons 1974
Days to 50% flowering High (H) Basu and Ashokraj 1969
Primary branches High (H) Kulkarni and Albuquerque 1967; Majumdar et al. 1969; Dixit et al. 1970; Raman and Sreerangaswamy 1970
Plant height High (H) Kulkarni and Albuquerque 1967; Dixit et al. 1970; Alam et al. 1985; Basu et al. 1986a
Secondary branches plant"'
High (H and G) Alam et al. 1985; Reddy 1968; Dixit et al. 1970; Raman and Sreerangaswamy 1970
Maturity Low (H) Mohammed et al. 1978
Note: High and low values of heritability are in relation to the characters studied in the experiment.
10 SDS no. 4 HRDP
Gene Effects
The most common designs used by the geneticist to study the genetic parameters and their interpretations are line x tester, diallel, triallel, and quadriallel. These designs give estimates of gene effects and general and specific combining ability effects for the parents and crosses involving the p a r e n t s . The general combining ability (GCA) effect is attributed to additive gene effect and additive x additive gene interactions that are fixable and could be easily exploited through selection. On the other hand, a specific combining ability (SCA) effect is due to dominance and epistasis (additive x dominance and dominance x dominance) that is not fixable. The other m e t h o d s useful for genetic analyses are the generation mean analysis, N o r t h Carolina designs (NCI, N C I I , N C I I I ) , and their m o d i f i c a t i o n s . The genetic studies on quantitative traits are summarized in Table 5.
SDS no. 4 11 HRDP
W h e n the additive gene effect for a trait is high, the character under consideration could be improved using simple selection p r o c e d u r e s . Therefore, plants with desirable traits could be selected even in the early generations. Thus procedures like p u r e line selection, pedigree selection, and their modification are u s e f u l .
W h e n dominance or over dominance gene effects are predominant, the best way is to utilize F 1S as commercial h y b r i d s . This option is not available to groundnut b r e e d e r s , because it is a cleistogamous crop. However, recurrent selection procedures could be used to b r i n g the desirable additive genes into broad b a s e d p o p u l a t i o n s .
When epistasis is involved, all selections should be deferred until the F 5 generation. However, on the basis of early-generation testing one can discard the low-yielding and undesirable crosses for economic traits (poor seed quality) or those susceptible to biotic and abiotic factors. Therefore, use of bulk population selection and/or its modifications like bulk-pedigree and single seed descent selection procedures are recommended. However, additive x additive epistasis, b e i n g an interaction of fixable gene effects, could be fixed and thus p r o v i d e an opportunity to select desirable p l a n t s .
Fisher (1918) p a r t i t i o n e d genetic variance into additive effect, dominance, and epistasis, i.e., interactions, additive x additive, additive x dominance, and dominance x dominance. Interactions and gene effects other than additive are also referred to as nonadditive. The implication of gene effects in plant breeding has been dealt with as follows:
-
-
-
T a b l e 5 . G e n e t i c v a r i a n c e s a n d g a n a e f f e c t s t u d i e s i n g r o u n d n u t .
character(s) Genetic component(s) Reference(s)
Pod yield GCA variance' > SCA Wynne et al. 1970, 1975; Wynne 1976; Garet 1976; Gibori et al. 1978; Habib et al. 1985
Nonadditive
Additive and non additive Additive gene effect
Schilling 1986; Sandhu and Khera 1976 Mohammed et al. 1978 Sridharan and Marappan 1980; Basu et al. 1987
Pod number plant-1 GCA variance > SCA Nonadditive
SCA variance > GCA
Habib et al. 1985 Sandhu and Khera 1976; Dwivedi et al. 1989 Khanorkar et al. 1984
100 pod mass (mean pod mass)
Additive and nonadditive Nonadditive
Schilling 1986
Duplicate gene Cahaner et al. 1979
100 seed mass Additive and nonadditive Nonadditive Additive
Reddy et al. 1986 Sandhu and Khera 1976 Sridharan and Marappan 1980
Seeds pod-1 Nonadditive Schilling 1986
Pod length Nonadditive Additive
Schilling 1986 Dwivedi et al. 1989
Pod size Nonadditive Additive and nonadditive
Schilling 1986 Mohammed et al. 1978
Plant height GCA variance > SCA Additive SCA > GCA
Habib et al. 1985 Sridharan and Marappan 1980 Khanorkar et al. 1984
Primary branches plant-1
GCA variance > SCA SCA variance > GCA Additive and nonadditive Additive dominant genes
Habib et al. 1985 Khanorkar et al. 1984 Reddy et al. 1986 Cahaner et al. 1979
Secondary branches plant-1
Additive and nonadditive Reddy et al. 1986
Days to 50% flowering Additive and nonadditive Additive
Reddy et al. 1986 Basu et al. 1987
Days to maturity GCA variance > SCA Additive
Habib et al. 1985 Basu et al. 1987
Shelling percentage GCA variance > SCA Additive SCA variance > GCA
Labana et al. 1981 Basu et al. 1987 Dwivedi et al. 1989
Oil content SCA variance > GCA Basu et al. 1988
Protein content SCA variance > GCA Basu et al. 1988
Iodine value SCA variance > GCA Basu et al. 1988
Nitrogen fixation Epistasis (nonadditive) Phillips et al. 1989; Nigam et al. 1980
(Note: GCA variance indicates additive genetic variance; SCA variance indicates nonadditive genetic variance.)
12 HRDP SDS no. 4
A c o n s i d e r a b l e amount of h e t e r o s i s (Table 6) h a s b e e n reported in
g r o u n d n u t . In general crosses involving Valencia x Spanish p a r e n t s
h a d h i g h h e t e r o s i s for p o d y i e l d and its component c h a r a c t e r s .
T a b l e 6 . E s t i m a t e s o f h e t e r o s i s o v e r a i d - p a r e n t ( M P ) a n d b e t t e r p a r e n t ( B P ) i n g r o u n d n u t .
Character(s) Cross Heterosis Reference (s)
Pod yield Spanish x Virginia Valencia x Spanish Subspecific group
Virginia x Spanish Virginia x Virginia
Spanish x Spanish
Positive High High F1 37.02% more over BP High heterosis Moderate heterosis 37.44 to 95.33% over MP; and 4.20 to 70.3% over BP High positive; Heterosis 5.2 to 30.5% over MP
Higgins 1940 Wynne et al. 1970 Coffelt and Hammons 1974 Raju 1978 Raju et al. 1981
Sridharan and Marappan 1980 Basu et al. 1986c
Isleib and Wynne 1983
Top mass Virginia x Spanish Virginia x Valencia
Positive Syakudo and Kwabata 1963
Pod length Virginia x Spanish Virginia x Valencia
F1 equal to MP value Upto 11.2% over MP
Syakudo and Kwabata 1963 Isleib and Wynne 1983
Branch number F1 superior to BP Hassan and Srivastava 1966a
Leaflet length F1 superior to BP Hassan and Srivastava 1966a
Days to 50% flowering
Valencia x Virginia F1 superior to MP Parker et al. 1970
Vegetative characters
Virginia x Valencia High heterosis Wynne et al. 1970
100-pod mass plant-1
Virginia x Spanish F1 higher than BP Heterosis ranges 6.38 to 30.2% over MP; and 35.8 to 165.2 % over BP
Garet 1976 Sridharan and Marappan 1980 Dwivedi et al. 1989
100 seed mass
Virginia x Spanish Virginia x Spanish Virginia x Virginia
F1 higher than BP F1 high heterosis Moderate heterosis Heterosis ranges 6.38 to 30.2% over MP
Garet 1976 Raju et al. 1979 Raju et al. 1979
Sridharan and Marappan 1980
Pods plant-1 Virginia x Spanish F1 higher than BP; 20.5% more over BP; 23.33 to 87.5% over MP; and to 38.4 over BP
Garet 1976 Raju 1978 Sridharan and Marappan 1980
Mature pods Spanish x Spanish Up to 17.5% over MP Isleib and Wynne 1983
Shelling percentage
Virginia x Spanish F1 higher than BP; Ranges from -23.3% to +10.3% over BP
Garet 1976
Dwivedi et al. 1989
13 SDS no. 4 HRDP
T a b l e 5 suggests that b o t h a d d i t i v e a n d n o n a d d i t i v e genetic
v a r i a n c e s a r e important in the inheritance of economic traits of
g r o u n d n u t . H o w e v e r , their estimations w i l l d e p e n d o n t h e p a r e n t s
involved in c r o s s e s . T h e conclusions d e r i v e d for o n e set of crosses
m a y o r m a y not h o l d t r u e for a n o t h e r .
Heterosis
Character Association The knowledge of the nature and magnitude of the association among characters are important for indirect selection when the desirable character has low heritability. The efficiency of indirect selection is measured as a correlated response (CRY).
CRY = ix x hx x hy x rg x Py. Where ix = selection intensity; hx and hy = heritability of characters x and y;
rg = genetic correlation between x and y characters; and Py = p h e n o t y p i c standard deviation of y in that the
correlated change is sought through selection on x.
W h e n a selection is to be made on several characters using the simultaneous selection model (Singh 1972) the use of a correlation study is h e l p f u l in avoiding undesirable changes in other correlated characters while selecting for some characters (Table 7 ) .
Table 7. Summary of character association studies in groundnut.
Character Correlated with Reference (s)
I. Positive correlations with:
Pod yield Number of mature pods plant-1
Alam et al. 1985; Deshmukh et al. 1986; Dholaria et al. 1973; Chandola et al. 1973; Nevano 1924; Dorairaj 1962; Jaswal and Gupta 1966; Lin et al. 1969; Bhargava et al. 1970; Dholaria and Joshi 1972; Phadnis et al. 1973; Kushwaha and Tawar 1973; Patra 1980; Yadava et al. 1981, 1984; Sandhu and Khera 1977; Coffelt and Hammons 1974b; Liao et al. 1989
Number and mass of seeds plant-1
Phadnis et al. 1973; Dholaria et al. 1973; Redona and Lantican 1986
Secondary branches plant-1 Lakshmaiah et al. 1983; Alam et al. 1985; Sandhu and Khera 1977
Primary branches plant-1 Chandola et al. 1973; Prasad 1981; Balkishan 1979; Bhargava et al. 1970; Khangura and Sandhu 1972; Sandhu and Khera 1977
Shelling (%) Kataria et al. 1984; Raju et al. 1981; Khangura and Sandhu 1972; Patra 1980; Yadava et al. 1984
100 seed mass Deshmukh et al. 1986
Number of pods plant-1 Phaokantarakorn and Waranyuwat 1987; Liao et al. 1989
Days to maturity Alam et al. 1985
14 HRDF SDS no. 4
continued
Table 7. Continued
II. Path-coefficient studies:
A. Direct effects
Yield Primary branches Khangura and Sandhu 1972; Yadava et al. 1984
Secondary branches Lakshmaiah et al. 1983
Mature pods plant-1 Deshmukh et al. 1986; Badwal and Singh 1973; Chandola et al. 1973; Sandhu and Khera 1977; Raju 1978; Balkishan 1979; Lakshmaiah et al. 1983; Yadava et al. 1984; Nigam et al. 984
100 seed mass Badwal and Singh 1973; Yadava et al. 1984; Deshmukh et al. 1986
Number of seeds pod-1 Balkishan 1979
Days to maturity Yadava et al. 1984
B. Indirect affect via:
Yield Secondary branches Shelling (%) Badwal and Singh 1973
III. Negative correlation with protein content:
Oil content Tai and Young 1975
Genotype X Environment (GxE) Interactions
G x E interaction has considerable influence on the p r o g r e s s of crop improvement. H i g h y i e l d i n g cultivars w i t h the least genotype x environment interactions are normally d e s i r a b l e . However, w h e n a cultivar is to be selected for a specific environment, the G x E interactions are desirable. Chen and W a n (1968) observed cultivar x y e a r and cultivar x location interactions w e r e low for y i e l d and the cultivar x y e a r x location interaction w a s highly significant. Several studies indicated that cultivar x y e a r x location interactions w e r e significant for y i e l d and y i e l d components in groundnut (Chen and W a n 1968; Tai and Hammons 1 9 7 8 ; O j o m o and Adelana 1970; Sangha and Jaswal 1975; W y n n e and Isleib 1 9 7 8 ) . Thus n o advantage could b e gained by subdividing the p r o d u c t i o n areas into subareas for breeding or testing p u r p o s e s (Wynne and Isleib 1 9 7 8 ) .
Further significant linear and nonlinear components of g e n o t y p e x environment interactions w e r e reported for 100 seed m a s s , oil content, and shelling p e r c e n t a g e . T h e m a g n i t u d e of the linear component of G x E w a s h i g h for p o d y i e l d , 100 seed m a s s a n d oil c o n t e n t . T h e nonlinear component w a s important for d a y s to maturity and p o d y i e l d (Kumar et a l . 1 9 8 4 ) . T h e stability p a r a m e t e r s for the different traits w e r e governed by an independent genetic system (Yadava and Kumar 1978a, 1978b, and 1 9 7 9 ) . Shorter and N o r m a n (1983) m a d e an environmental classification b a s e d on cultivar x environment i n t e r a c t i o n s . This indicated that there w e r e no temporal or closely
SDS no. 4 15 HRDP
related regional environment groups w i t h similar cultivar x environment interactions, and concluded that lower critical p e r c e n t a g e differences b e t w e e n n e w and established cultivars in p r e r e l e a s e trials can be obtained by adding environments rather t h a n r e p l i c a t i o n s .
Pod yield, p e r c e n t a g e of sound m a t u r e seeds, and p e r c e n t a g e of extra large seeds studied in F4 and in F5 generations showed that p o p u l a t i o n s of individual cross and lines w i t h i n the cross w e r e significantly different for all the c h a r a c t e r s . Populations of different crosses interacted w i t h the y e a r , location, and environments for all t r a i t s , w h e r e a s lines w i t h i n a cross interacted w i t h the environment for all the traits except p o d y i e l d (Wynne and Coffelt 1 9 8 0 ) . Reddy et a l . (1984) observed that seasonal differences in groundnut y i e l d s w e r e m o r e p r o n o u n c e d than varietal d i f f e r e n c e s . T h e m a g n i t u d e of variety x season interaction w a s h i g h in the Virginia type, b e i n g less interactive than the Spanish t y p e . An individual variety w i t h stability across the locations w a s identified.
Schilling et a l . (1983) developed multilines u s i n g sibling lines composited b e t w e e n the F 4 and F 5 g e n e r a t i o n s . T h e relationships among sibling c o m p o n e n t s of t w o groundnut m u l t i l i n e s across the environment w e r e calculated. For one m u l t i l i n e three component lines did not differ significantly from t h e m u l t i l i n e nor did d e v i a t i o n s from regression a n d stability variances differ among c o m p o n e n t s . Conversely, components of the second m u l t i l i n e d i s p l a y e d significant variability for y i e l d , regression coefficient ( b ) , and deviation from regression (S2d) . T h e data indicated that the compositional scheme for groundnut m u l t i l i n e s is a feasible method to circumvent G x E interaction.
N o r d e n et a l . (1986) studied the stability of four groundnut m u l t i l i n e s and their component lines. They found highly significant interactions of g e n o t y p e s (population) w i t h environments for p o d y i e l d , p e r c e n t a g e of fancy p o d s , 100 seeds m a s s , p e r c e n t a g e of extra large s e e d s , and sound m a t u r e seed yield. Large differences in y i e l d and market quality traits w e r e not found b e t w e e n s i b - l i n e s . However, differences w e r e found in stability estimated from regression coefficients and deviation from regression of m u l t i l i n e s compared to their component lines. This w a s possibly due to a buffering action resulting from greater genetic variability. Multilines did not h a v e greater stability in all cases, but the d i f f e r e n c e b e t w e e n t h e m u l t i l i n e and its least stable component line w a s generally greater than the d i f f e r e n c e b e t w e e n the multiline and its most stable component line. T h u s , the chances of improving t h e y i e l d stability and market acceptability of a groundnut cultivar w e r e increased w h e n the m u l t i l i n e a p p r o a c h w a s followed.
T h e m a i n b r e e d i n g g o a l s should meet the requirements of a grower, a p r o c e s s o r , and a consumer. A grower requires h i g h y i e l d , pest resistance a n d tolerance of environmental stresses, and y i e l d stability. A p r o c e s s o r requires u n i f o r m m a t u r i t y favorable to m e c h a n i z a t i o n a n d p r o c e s s i n g characteristics. T h e consumer requires g o o d quality oil and groundnut seeds w i t h a c c e p t a b l e shape, size, c o l o r , and taste for confectionery p u r p o s e s (Wynne and Gregory 1 9 8 1 ; B r a n c h 1 9 7 9 ) .
16 SDS no. 4 HRDF
Groundnut Breeding
A large number of groundnut accessions are available in the national programs of many c o u n t r i e s . ICRISAT maintains a world collection of over 12 000 accessions of groundnut from 92 countries of which 6 0 % were obtained from the USA, South America (Peru, Bolivia, Brazil, A r g e n t i n a ) ; western Africa (Senegal, Burkina Faso, M a l i , N i g e r i a ) , southern Africa (Zambia, Zimbabwe, Mozambique, T a n z a n i a ) , and Asia (India and Indonesia) (V. Ramanatha Rao, ICRISAT, personal communication 1 9 8 8 ) .
A germplasm line could be used directly as a variety, if it is found suitable. When some collections have genetic variability, they are subjected to selection (pure line or mass selection) to isolate desirable genotypes. The third way to use the germplasm accession is as a parent to transfer the desirable characteristics into established genotypes or to obtain the transgressive segregants.
Bailey (1968) estimated that 7 5 - 8 0 % of the groundnut cultivars grown in the USA were derived wholly or in part from selections introduced from foreign countries. Higgins and Bailey (1955) by exercising selections in the different lots of farmers' groundnuts of USA identified six groundnut v a r i e t i e s ; GFA Spanish, Dixie Spanish, Southeastern runner 56-15, Virginia bunch 67, Virginia bunch G 2 , and Virginia runner G 2 6 .
Spanish varieties released through pure line selections in USA were A r g e n t i n a ( 1 9 5 1 ) , Comet (1977), and Spantex (1950). Virginia varieties released were Virginia 56R (1957) and Virginia 61R (1962).
SDS no. 4 17 HRDP
Hybridization
The objective of hybridization is to recombine characters from different lines into a desirable genotype for commercial utilization. The results of crossing will be known after several years, therefore, it is necessary to consider the following points before starting a hybridization program:
Germplasm Collection and Evaluation
Breeding for resistance to foliar diseases (leafspots and r u s t ) .
Breeding for resistance to soilborne diseases (pod rot, A s p e r g i l l u s flavus, and collar rot, A. n i g e r ) .
Breeding for resistance to p e s t s . This includes t h r i p s , jassids, leafminer, spodoptera etc.
Breeding for drought resistance or tolerance.
B r e e d i n g for adaptation to specific environments and requirements. This includes cultivars for oil production with varying duration (early, medium, and late type) and for direct consumption.
Efforts have bee n made to accomplish these requirements at ICRISAT under five p r o j e c t s .
-
-
-
-
-
Wall defined objectives. The breeding objectives should be well defined before taking up hybridization, such as resistance to diseases, insect p e s t s or improvement in oil content.
Choice of p a r e n t s . Select the parents based on the breeding objective. One parent can be a desirable variety of the area and the other parent or p a r e n t s m a y have a desirable trait(s) not present in the first p a r e n t . It is safe to select the parents for a particular trait from various sources (Tables 8a, 8b, and 8 c ) .
H a t i n g d e s i g n . Depending on the breeding objectives and the traits available in different sources single, double or three way crosses are attempted. The other way is to attempt crosses using mating designs suitable for biometrical studies. This will help in understanding the genetics of characters as well as to identify the material for a breeding program.
When the number of parents involved in a cross exceeds two, it creates a problem in crossing. As the number of parents increases the number of b u d s to be crossed must be increased to realize the m a x i m u m recombinations. Groundnut, being a highly self-pollinated crop (cleistogamous) makes it difficult to use population improvement p r o c e d u r e s . However, diallel selective matings (Jensen 1970) and modified recurrent selection schemes (Compton 1968) were applied in groundnut improvement (Wynne 1 9 7 6 ) . At ICRISAT Center, single crosses, three-way crosses, and double crosses are m a d e .
1 8 SDS no. 4 HRDP
T a b l e 8 a . G r o u n d n u t g e n o t y p e s r e p o r t e d r e s i s t a n t t o t o l e r a n t o f d i s e a s e s .
character Genotypes with desirable traits
1. Early leaf spots (cercospera arachidicola) Late leaf spots Phaeoisariopsis personata
FESR-5-l-B-b4, FESR-5-2-B-64, NC3033, and PI 109839, ICG 7878, ICG 6284 UP 81206-1, UF 81206-2, 72 x 32B 3-2-2-2-l-b3-B NC3033, AC3139, PI Nos. 203395, 203397, 261893-2-1-1-13, 261893-1-3-B, 261893-2-1-4-1-2B, 261906-1-1-1-2-3B and NC 3033, Southern Runner', ICG 7756, ICG 1710, ICGV 86699
2. PI Nos. 259747, 341879, 350680, 380622, 315608, 314817, 405132, Tarapota, DHT 200, Israel line 136, PI 314817, NC Ac 17133, PI 25947, NC Ac 17090, and EC 76446
Lines resistant to late leaf spot and rusts (Interspecific hybrid crosses)
CS9, CS30, CS22, CS62, CS31, CS26, CS36, CS2403, CS820/1, CS13-1-B1-B3-B1, CS16-B2-B2-B1, CS29/1-B2-B1-B1, and NC Ac 17090
3. Web blotch (Phoma arachidicola) Florunner, Florigiant, and GK3
4. Florispan, and F334A-B-14
5. Sclerotinia blight (Sclerotinia sclerotiorum)
NC 11165, Chico, PI 535817
6. CBR-Black rot NC 3033, Argentine, NC2, VAGP1, NC Ac 18016
7. Pythium pod rot (Pythium myriotylum)
PI Nos. 341885, 365553, 535816 and Toalson
8. Southern stem rot (Sclerotium rolfsii)
NC2
9. Aflatoxin (Aspergillus flavus and A. parasiticus)
Tolerant: Florunner, Daron IV, Shulamit, PI 337394F, PI 337409, J 11, U4-7-5, VRR 245, GFA-1, GFA-2, Ah 7223, UF 71513, 55-437
10. Rosette virus (Vector Aphis craccivora)
RG 1, RMP 40, RMP 12, RMP 91, KH 14-9A, and M-25-68
11. Bud necrosis ICGV No. 86029, 86030, 86031, 86032, 86033, and 86038
12. Necrotic etch leaf disease Jenkins Jumbo
HRDP SDS no. 4 19
(Puccinia arachidis) Rust
SDS no. 4 HRDP 20
T a b l e 8 b . G r o u n d n u t g e n o t y p e s r e p o r t e d r e s i s t a n t t o o r t o l e r a n t o f i n s e c t p e s t s .
Character Genotypes with desirable traits
1. Lesser cornstalk borer (Elasmopalpus liqnosellus)
Florunner and Comet
2. Southern corn root. worm (Diabrotica undecimpunctate
NC 6
3. Thrips (Frankliniella fusca)
PI 280688, NC Ac 343, low damaged lines, NC Ac 2242, NC Ac 2214, NC Ac 2240, NC Ac 2232, and NC Ac 2230
ICRISAT pest resistant lines (low incidence)
ICG(PRS) 13, ICG(PRS) 4, ICG(PRS) 68, ICG(PRS) 77, and ICGPRS 36
4. Termites NC Ac 224 0, and NC 343
5. Jassid (Empoasca kerri) NC Ac 2214, NC Ac 2240, and NC Ac 2230, ICGV 87157, and ICG(FDRS) 10
T a b l e 8 c . G r o u n d n u t g e n o t y p e s d e s i r a b l e f o r d r o u g h t r e s i s t a n c e , e a r l i n e s s , q u a l i t y , a n d c o n f e c t i o n e r y t y p e .
Character Genotypes with desirable traits
Drought resistant/ tolerant lines
GNP 35, ICG 1660, ICG 3386, ICG 3736, ICG 296, ICG 405, ICG 1697, ICG 4790, ICG 4747, ICG 6997, ICG 2960, ICG 3301, ICG 4 5 4 4 , I C G 4728, ICG 3657, UP 67, Arbrook (PI 262817)
Earliness Chico, 91176, 91776, ICGS (E) 71, ICGS (E) 61, and ICGS (E) 11
Quality Oil: Tainan 10 (57.1%)
Protein: NC-F1a 14 (32%)
Confectionary type ICRISAT genotypes HYQ (CG) 514, HYQ (CG) 53, HYQ (CG) S5, ICGV 86564, ICGV 86577
Nitrogen fixation NC 7, NC Ac 2821
Sources for Tables 8 a , 8 b , and 8c: Norden et al. 1982, Subrahmanyam et al. 1980, ICRISAT 1985, 1986, 1987, 1990, and Reddy et al. 1991.
Both additive and nonadditive gene effects are evidently important for economic traits in groundnut. However, the former appears more important than the latter. Therefore, the breeding method that exploits b o t h additive and nonadditive gene effects may be suitable for the improvement of groundnut. Due to limitations in attempting large scale crossing, use of recurrent selection procedures are restricted. Therefore, a basic goal in most groundnut breeding programs is to develop pureline cultivars or multilines by using siblings to obtain wide adaptability and resistances to biotic and abiotic factors. Thus it is desirable to make single, three-way, or double crosses to pool the characters from different genotypes in the local cultivar that has wide adaptation. These crosses are grown with large F2 p rogenies so that further selection can be made using pedigree, m o d i f i e d p e d i g r e e , bulk, single seed (SSD), or single p o d descent m e t h o d s . An accelerated pedigree selection method (Valentine 1984) or stratified m a s s selection (Holly and Wynne 1986) and a sequential selection method (Branch et a l . 1991) were found useful in groundnut.
The accelerated pedigree selection (APS) involves an initial selection b a s e d on the assessment of the lines rather than the p l a n t s . These lines are derived by the accelerarted generations procedure. Unlike the SSD m e t h o d the line selection can begin in an early generation, that will minimize the risk of differential mortality. The length of the A P S b r e e d i n g cycle is shorter than that of either the pedigree or SSD selection m e t h o d s . In addition to enhancing the efficiency of selection, the A P S is expected to result in more genotypes b e i n g retained and a closer selection for the desirable combination of characters (Valentine 1 9 8 4 ) .
Stratified mass selection for higher seed yield was effective in interspecific crosses, but was only effective in one of the three intrasubspecific crosses (Holly and W y n n e , 1 9 8 6 ) . The confounding effect of shelling percentage with seed yield and the small number of F2 p lants evaluated may be partially responsible for the lack of effective selection in two of the intrasubspecific crosses for high seed yield having higher shelling p e r c e n t a g e . However, the high and low selections when evaluated in the F 4 generation did not differ for shelling percentage except for one intrasubspecific cross.
A sequential selection m e t h o d was p r o p o s e d (Branch et a l . 1991) to minimize genotype by environment interactions. In this procedure early generation selections at m o r e than one location identified p u r e -line genotypes with wider adaptability. This method involves cyclic early generation selections through different environments. Plants were selected in each generation at each location and were grown at different locations for evaluation. This method was found significantly better than the pedigree method and at par with the single seed descent m e t h o d of selection for pod yield in groundnut (Branch et a l . 1 9 9 1 ) .
An alternate approach to overcome breeding limitations of the p e d i g r e e m e t h o d is the use of recurrent selection. Modifications of the recurrent selection techniques to include closely related species should further broaden the b a s e . Guok et a l . (1986) carried out phenotypic recurrent selections for yield in a tetraploid population derived from a cross of A r a c h i s hypogaea x Arachis cardenasii Krap. Resistance to late leaf spot was recorded for selected families. Ten families selected for high p o d yield and large p o d size from the
21 SDS no. 4 ARDP
Choice of Selection Procedures for Groundnut
Diseases and pests cause serious yield losses to groundnut production. The range of genetic variation, particularly resistance to p e s t s , and diseases is limited in cultivated groundnut (Arachis h y p o g a e a ) . The collections of wild species from South America have contributed a wide range of genes that confer resistance to important pests and diseases. This germplasm provides opportunity for genetic improvement of cultivated groundnut.
Several A r a c h i s species are identified (Table 9) with resistance to pests and p a t h o g e n s . Particularly important are those which either have resistance to many (multiple) pests and diseases or are resistant to diseases for which variability is not available in the cultivated species.
The tetraploid A. hypogaea is classified into section Arachis along with the compatible diploid species that are resistant to several diseases and p e s t s . A p p r o p r i a t e genome and ploidy manipulations m a k e it possible to incorporate desirable genes from the wild diploid into Arachis hypogaea as discussed in MP 4.
22 HRDP SDS no.4
Utilization of Wild Species
segregates of the original cross were randomly intermated to the initial population. After two cycles of recurrent selection using S 1
t esting, the response to selection was compared with individual parents of the three cycles (C1, C2, and C3) in four environments. Two cycles of selection resulted in an increase in pod yield of 210 ± 70 kg ha - 1 cycle - 1, however, seed m a s s , shelling percentage and extra large seeds decreased significantly. Little variability was observed among lines after the second c y c l e . Genetic variability for resistance to late leaf spot existed among the parents over the 3 y e a r s .
It is evident from the foregoing discussions that the pure line selection, m a s s selection, recurrent selection, and bulk selection with its modifications are useful for handling segregating materials of groundnut. The details of these procedures are available in standard plant b r e e d i n g b o o k s .
Procedures for establishing groundnut breeding nurseries in the greenhouse, and a nursery in the field (MP 1 ) , emasculation and crossing (MP 2 ) , and a simple p r o c e d u r e for handling of segregating generations (MP 3) are separately discussed.
T a b l e 9 . W i l d A r a c h i s s p e c i e s w i t h m u l t i p l e r e s i s t a n c e t o d i s e a s e s a n d p e s t s .
S e c t i o n / S p e c i e s D i s e a s e / P e s t 1
RUS LLS ELS PS PM TSW THR APH JAS
Arachis A. duranensis A. villosa A. correntina A. cardenasii A. chacoense A. stenosperma Arachis spp.
I R R R(2) 3
R
R/I R
R(l)
R R R
R(3)
R
R R R
R R R R
R R
R
R R R R
Erectoides A. appressipila Arachis spp
I R(3)
R R(2) R(l) I(3) R(3)
Rhizomatosae A. qlabrata R I R R R R R R
1 . R U S = Rust, LLS = Late leaf spot, ELS = Early leaf spot, PS = Peanut stunt virus, PM = Peanut mottle virus, TSW = Tomato spotted wilt virus
THR = Thrips, APH = Aphids, JAS = Jassids. 2. I = Immune, R = Resistant. 3. Figures in parentheses are number of species. (Source: ICRISAT 1987)
Mutation Breeding Induced mutation has produced desirable results in several self-pollinated crops like wheat and rice as well as groundnut. There are examples where mutants were identified directly for cultivation. Useful mutants have b e e n identified for yield and quality traits in groundnut (Patil 1 9 7 5 ) .
Success of mutation breeding depends on:
o The identification of clear objectives. o Incorporation of the desired characters.
Efforts to produce mutations in groundnut have been successful for b o t h qualitative and quantitative characters using chemical as well as physical m u t a g e n s . Ashri and Levy (1976) used ethylmethane sulphonate (EMS) and diethyl sulphate in groundnut for producing m u t a t i o n s . Levy and Ashri (1978) found ethidium bromide to be a very effective mutagen in groundnut.
A variety TG 1 w a s developed by using X-rays (75 kr) and repeated selection for improved seed m a s s . TG 1 had 0.7 to 0.9 g seed - 1
c ompared to 0.4 to 0.5 g seed - 1 of its parent in the A l l India Coordinated Research Project on Oilseeds (AICORPO) during 1969-72 (Patil 1 9 7 5 ) .
F u rther high yielding lines such as TG 16, TG 1 7 , and TG 19 were derived by hybridization of different mutants with cultivars (Patil 1 9 7 7 ) . Hybridization of m u t a n t s and improved cultivars
SDS no. 4 23 HRDP
R
I2
I I I I
followed by radiation treatment have p r o d u c e d alterations of
characters in subspecies fastigiata and subspecies hypogaea. and also
modifications in plant type (Mouli et a l . 1 9 8 2 ) . Genotypes developed
by m u t a t i o n b r e e d i n g are given in Table 10 and mutagenesis in MP 5 and
MP 6.
T a b l e 1 0 . G r o u n d n u t v a r i e t i e s d e v e l o p e d t h r o u g h m u t a t i o n b r e e d i n g .
Name of mutant (variety selected)
Genotype irradiated/ pedigree
Inducing mutagen
Improved characters over parent
A. Direct mutants
TG 1 (Trombay Groundnut 1) released as Vikram
Bold 1 X-rays 75 kr
High seed mass 0.7-0.9 g seed as compared to 0.4-0.5 g seed"1 of parent, and yield
LV 3A LV 3 20 kr-Gamma Improved shelling % rays
TG 18A TG 18 -do- Large pod, dormancy, early maturity, and 76% seed out turn
Co 2 PoL 1 EMS Early maturity, 77% seed out turn
B. Mutants utilised in crossing program
TG 7, TG 13, TG 8, TG 9, TG 10, TG 11, TG 12
TG 1 x Virescent F5
Mutant crossed with other genotype
Medium to large pods, and dormancy
TG 16 Virescent/ TG 1
Selected in F6
Large pod
TG 17 Darker green/ TG 1
Selected in F4
Medium pods and dormancy
TG 19A TG 17 x TG 1 Dark green foliage, large pods dormancy
Source: Patil 1975; Mouli et al. 1982; and Sivaram et al. 1989.
24 HRDP SDS no. 4
A. A crossing nursery in the greenhouse
Hybridization of groundnut is commonly done in a greenhouse to ensure m a x i m u m seed setting under controlled conditions. The plants are grown in 15 L p o t s (30 cm diameter) on greenhouse benches in sterilized fertile soil. In each pot, 2-4 groundnut plants are maintained for hybridization.
Material and facilities required.
o Pots and gravel. o Sterilized soil, sterilized sand, and composted farm m a n u r e . o Chemicals - Bavistin and carbofuran. o Fertilizer - Diammonium phosphate o Seed o Greenhouse
Preparing pot for sowing. Prepare a soil mixture containing sterilized soil, sterilized sand, and compost in the ratio of 4:2:1. Put 2-3 cm of gravel in the base of each p o t . Then fill the pot with the soil m i x t u r e leaving 2-3 cm at the top. Now make holes for sowing seed 5 cm deep and put 50 g diammonium phosphate pot - 1 in the holes and some granules of carbofuran. Sow two Bavistin treated seeds hole - 1.
A f ter sowing, p l a c e the pots on stones or bricks and irrigate w e l l . Leave only 2-4 seedlings pot - 1 and place the pots on iron benches fitted with thick wire net.
Intensive care is required to keep plants healthy and free of diseases and p e s t s .
The temperature of the greenhouse should be maintained between 22-30oC at flowering with the humidity ranging from 6 0 - 7 0 % . The soil moisture is m a i n t a i n e d at 8 0 - 8 5 % of field capacity.
Label each pot with plastic pegs to identify the genotype and cross to be m a d e .
The crossing nurseries (blocks) are established in a well prepared field. A b a l a n c e d supply of plant nutrients is essential in the nursery with adequate N, P, K and calcium in the fruiting zone.
It is convenient to sow a crossing nursery on a 75 cm ridge-and-furrow system. Groundnuts are planted in 5-9 m rows of female or m a l e parents alternate to each other. This facilitates collection of flowers for pollination. The number of rows for each parent (female and male) should be decided as per the objective of the crossing, and amount of seed required. When a broadbed-and-furrow system is followed the emasculation can be attempted on p l a n t s from the furrow side or from top of the bed.
SDS no. 4 25 HRDP
MP 1. Establishing Groundnut Crossing Nurseries
B. A crossing nursery in the field
The female and male parents are labeled w i t h tags of different color. For example, the m a l e parent with a red and the female parent with a b l u e t a g . The name of t h e parent and number of rows sowed should be m e n t i o n e d on each tag.
Optimum soil moisture should be 4 0 % of the total soil volume in the podding zone regardless of soil moisture content in the rooting zone (Ono et a l . 1 9 7 4 ) . Therefore, PURFO or sprinkler irrigation is necessary after emasculation to create the required humidity and to supplement the water loss during bright sunny d a y s . Half an hour irrigation every evening is recommended when the rains fail and the temperature is high.
Temperatures from 22 to 33°C are ideal for flowering and fruiting of groundnut. The optimum soil temperature is b e t w e e n 28-30°C.
26 SDS no. 4 HRDP
A n t h e s i s . Flowering starts about 25-30 days after seedling emergence. The dehiscence of the anthers takes place (at ICRISAT Center, Hyderabad) from 0400 to 0500 and flowers open from 0530 to 0730.
Anthesis is affected by the temperature and humidity (Norden 1 9 8 0 ) . T h e r e f o r e , it is necessary to control these two factors in the greenhouse. During flowering time, the humidity should be above 7 0 % and the temperature between 28 and 30°C.
Emasculation. Emasculation of groundnut can be accomplished on w a r m bright days from 1330 to 1 6 3 0 . On cloudy or rainy d a y s , emasculation could be delayed until 2100-2200 (Norden 1 9 8 0 ) . N i g a m et al.(1.990) discussed the detailed technique of artificial hybridization in groundnut.
Steps for emasculation.
1. Select the well developed b u d for emasculation, and remove all other buds at the node to ensure that only one flower develops at that n o d e . Pull the leaf down gently to expose the bud.
2. With one hand hold the b u d between your thumb and index finger.
3. Remove the sepal on the side of the keel and push down the sepal on the side of the standard.
4. Open the standard petal with the forceps and pull down the w i n g p e t a l s .
5. Hold back the standard petal with the thumb and index finger. Break open the keel with the point of the forceps. M o v e the keel up and pull it free of the stigma and a n t h e r s . The keel is p u l l e d down and held out of the way with the thumb and index finger, while all anthers along w i t h their filaments are removed.
6. N o w return the standard p e t a l to its original position over the stigma. Usually no attempt is m a d e to cover the emasculated flowers for protection from outside p o l l e n .
7. A small thread is put on the hypanthium of the emasculated flowers for identification (Norden 1980) or on the stem above the b u d a x i s . Use different colored threads on different days to identify emasculated b u d s for p o l l i n a t i o n . A record of the number of b u d s emasculated should be maintained for each p a r e n t .
Pollination. On the morning after emasculation, the standard petal is usually expanded and the stigma is exposed between 0600 and 0 7 3 0 . A healthy flower from the male parent (pollen source) is selected. Its corolla is removed exposing the anthers and pollen. N o w directly squeeze the p o l l e n on to the emasculated flower stigma or on to the forceps, and transfer the pollen from the forceps to the stigma of an emasculated flower. A f t e r pollination, remove all other flowers that were not hand p o l l i n a t e d by breaking their hypanthium near the b a s e .
The m a x i m u m physiological development of pollen is from 0500 to 0700. It was found that p o l l e n remained viable up to 8 days when stored in a sealed desiccator over calcium chloride in a refrigerator at 6 C . W h e n flowers were stored at 28 C and at a relative humidity of
SDS no. 4 27 HRDP
MP 2. Emasculation and Crossing in Groundnut
5 6 % the pollen remained viable for only 8.5 h (Hassan and Srivastava 1 9 6 6 b ) .
P ollination success. Hybridizing groundnuts in the greenhouse may result in over 7 0 % s u c c e s s . A success rate of 4 4 % was reported in India from field hybridization, starting at 0630 during the monsoon season (Jul to A u g ) , compared to 2 7 % w h e n pollination w a s started at 0830 (Norden 1 9 8 0 ) .
Number of pegs or pods developed x 100 = Successful crosses % N u m b e r of flowers p o l l i n a t e d
P o d davelopment and h a r v a a t . When fertilization is successful, the tissue below the ovary, called the gynophore, elongates into a peg carrying the ovary at its tip geotropically into the soil. In the soil the ovary takes a horizontal position and a p o d develops. Mature pods can be harvested usually 55-65 days after the p e g s developed.
28 SDS no. 4 HRDP
MP 3. Handling Crosses of Groundnut
T h e crossed seeds are grown along w i t h their parents to identify h y b r i d s . Plants in the F1 generation resembling the female parent (selfed) should be removed. Undesirable F 1S that are highly susceptible to d i s e a s e s , or insects, or that are poor in quality can be rejected at harvest.
The harvested seeds on F1 plants are grown in bulk in unreplicated p l o t s w i t h a large p o p u l a t i o n (1000-2000 p l a n t s ) . The selection p r o c e d u r e s such as b u l k selection, pedigree selection, bulk-pedigree selection, or single seed (pod) descent selection can be followed for handling the segregating g e n e r a t i o n s . The detail of these selection p r o c e d u r e s can be found in plant breeding text b o o k s . A simple modified bulk selection method as p r a c t i c e d at ICRISAT is outlined in Figure 1. Some criteria for selections are listed (Table 1 1 ) . The end product or groundnut variety can be developed as a pure line, m u l t i l i n e , or m i x t u r e of p u r e l i n e s .
Some of the ICRISAT varieties that are released are listed in Table 12.
T a b l e 1 1 . C h a r a c t e r i s t i c s f o r s e l e c t i o n o f p l a n t s f r o m g r o u n d n u t
p o p u l a t i o n s .
C h a r a c t e r C r i t e r i a f o r s e l e c t i o n
E a r l i n e s s M a x i m u m e a r l y f l o w e r i n g i n a f e w d a y s
D r o u g h t r e s i s t a n c e T o t a l b i o m a s s p r o d u c t i o n ( u n d e r s t r e s s
c o n d i t i o n s )
L e a s t d i f f e r e n c e i n y i e l d u n d e r d r o u g h t a n d
i r r i g a t e d c o n d i t i o n s
H i g h p o d y i e l d u n d e r s t r e s s c o n d i t i o n s
I n s e c t r e s i s t a n c e L e a f h a i r s ( t r i c h o m e s ) r e p e l s o m e i n s e c t s
H i g h a d a p t a t i o n P e r f o r m w e l l u n d e r a p o o r e n v i r o n m e n t a n d
a r e r e s p o n s i v e t o r i c h e n v i r o n m e n t s
C o n f e c t i o n e r y t y p e L a r g e s e e d e d , s m o o t h , a n d u n i f o r m s i z e d s e e d s
N u t r i t i o n a l a n d f o o d q u a l i t y
H i g h o l e i c a c i d / l i n o l e i c a c i d r a t i o
29 SDS no. 4 HRDP
Operations
Attempt 100-150 buds to obtain 50 pods or 70-75 seeds
Identify hybrid plants and harvest as a bulk
Grow F2s in disease screening nursery, reject undesirable t y p e s , select and bulk plant types into three groups
Grow separate bulks and select plants from each group
Grow selected bulks and select plants from each group
Preliminary yield t r i a l : (4 m x 4 rows with 3 replications) Reject for poor yield
A d v a n c e yield t r i a l : (4 rows of 9 m, 3 replications, 2-3 l o c a t i o n s ) . R e j e c t for poor yield and select best entries for elite t r i a l .
Multilocation t r i a l s : (4 m length, 4 rows, and 3 replications) 1 or 2 years to select the entries that could go to national programs for testing
Multilocation International T r i a l : (for 2 y e a r s ) . The best material may go to national programs for release
Figure 1. M o d i f i e d bulk selection as practiced at ICRISAT. (Source: S.L. Dwivedi, ICRISAT, personal communication 1987)
30 SDS no. 4 HRDP
Seed multiplication and release
International trial
F4 and F5
F3 Spanish Valencia Virginia
F2
Generation
A x B Cross
F1
v
V V V
F1
T a b l e 1 2 . I C R I S A T g r o u n d n u t v a r i e t i e s r e l e a s e d f o r c u l t i v a t i o n
Variety Season and area of cultivation
Year of release
Remarks
ICGS 11 (ICGV 87123)
Post-rainy season Andhra Pradesh, Karnataka, Madhya Pradesh, and Maharashtra States of India
1986 Spanish selection, dark green foliage, small-to medium-sized, two-seeded pods with tan-colored seeds. Yield potential 4.5 t ha-1. Tolerant to bud necrosis disease
ICGS 44 (ICGV 87128)
Post-rainy season/ and rainy season Gujarat State of India In Pakistan as component line of BARD-699
1988 Spanish type, two-seeded small-to medium-sized pods, tan-colored seeds. Tolerant to bud necrosis
ICGS 5 (ICGV 87121)
Rainy season. India - Uttar Pradesh
1989 Virginia bunch, small-to medium-sized, two seeded pods with tan colored seeds. Pod yield 2.7 t ha-1
ICGS 76 (ICGV 87141)
Rainy season. India - Andhra Pradesh, Karnataka, Kerala, southern Maharashtra and Tamil Nadu. Under consideration for release in Sudan
1989 Virginia selection, medium-to-small elliptic, dark green leaves. Two-seeded medium-sized pods. Seeds tan-colored. Field tolerance to bud necrosis. Good recovery for pod yield from midseason drought
ICGS 1 (ICGV 87119)
Rainy season. Bihar, Haryana, Punjab, Rajasthan and Uttar Pradesh States of India
1990 Spanish type, medium-to-small dark green, elliptic leaves; two-seeded, medium-sized pods
ICG(FDRS) 10 (ICGV 87160)
Rainy season. India -Andhra Pradesh, Karnataka, and Maharashtra
1990 Sequential flowering, bunched, two-seeded, tan-colored, medium-sized seeds. Highly resistant to rust, moderate resistance to late leaf spot. Less susceptible to bud necrosis, peanut mottle virus, stem rot, and leaf miner
ICGS 37 (ICGV 87187)
Post-rainy season. India - Madhya Pradesh and Maharashtra. In Pakistan as component line of BARD-699
1990 Spanish selection with small-medium dark green, elliptic leaves. Two seeded medium sized pods. Moderately resistant to rust and late leaf spot, tolerant to bud necrosis, and peanut mottle, photoperiod insensitive
Source: Anonymous 1990. Crop improvement in India: ICRISAT cultivars. ICRISAT Public Awareness Series. ICRISAT Plant Description Material no. 21, 24, and 27. Patancheru, A.P. 502324, India: International Crops Research Institute for the Semi-Arid Tropics.
31 SDS no. 4 HRDP
Genome analysis at ICRISAT, in section A r a c h i s , revealed that a majority of d i p l o i d w i l d species has a common 'A' genome, but that A. batizocoi has a different 'B' genome. Both genomes have the base number 10, they are homeologous and together constitute the cultivated species A. hypogaea (Singh and Moss 1982, 1 9 8 4 ) . This has helped in identification of suitable methods (Fig. 2) for gene transfer from diploid A r a c h i s species w i t h 'A' and 'B' genomes (Singh 1 9 8 6 ) .
M e t h o d 1. Compatibility between cultivated tetraploid A. hypogaea and the diploid species p e r m i t s direct hybridization (Fig. 2 a ) . This crossing results in triploid hybrids that are sterile. In the triploid h y b r i d s , c h romosome numbers are doubled by colchicine treatment to p r o d u c e a fertile hexaploid amphidiploid. Hexaploids are screened against various diseases and p e s t s , and resistant segregants are b a c k crossed w i t h A. hypogaea till cytogenetically stable tetraploid A. hypogaea - like derivatives are obtained.
M e t h o d 2. Triploid hybrids occasionally can produce pods w i t h v i a b l e seeds. About 8 2 % of these seeds p r o d u c e h e x a p l o i d s . These progenies or p r o g e n i e s w i t h less than 60 chromosomes are back crossed w i t h A. hypogaea until stable tetraploids are p r o d u c e d (Fig. 2 b ) .
M e t h o d 3. Production of amphidiploids by doubling the chromosome number in F1 hybrids of diploid w i l d species (AxA or AxB) followed by crossing them w i t h A r a c h i s hypogaea (4x) is another option for genetic introgression Fig. 2 c ) . In this hybrid coherence to genomes of A. hypogaea b e c a u s e of homology between 'A' and 'B' genomes overcomes fertility p r o b l e m s when crossing to Arachis hypogaea to combine desirable traits.
M e t h o d 4. Production of an autotetraploid by doubling the chromosome number in a w i l d Arachis species followed by crossing them to A. hypogaea (4x) at the tetraploid level is another option (Fig. 2d) w h i c h may overcome the barriers d e v e l o p e d as a result of ploidy d i f f e r e n c e s . The p a r t i a l l y fertile hybrids w i t h greater allelic recombinations are p r o d u c e d for b a c k c r o s s i n g to A. hypogaea.
A n o t h e r m e t h o d is to reduce the chromosome number in A. hypogaea to a diploid level and then perform hybridization w i t h diploid wild species at the diploid level. However, the feasibility of this option can not be assessed till production of haploids from A. hypogaea is achieved (A.K. Singh, ICRISAT, personal communication 1 9 8 9 ) .
32 SDS no. 4 HRDP
MP 4. Incorporation of Genes from Wild Diploids into Cultivated Groundnut
T h i s involves t h r e e s t e p s .
A. Gene transfer from compatible species.
c. Production of hybrid tetraploids from two wild diploids.
d. Production of tetraploids from diploids.
(Source: ICRISAT 1980, and A.K.Singh, ICRISAT, personal communication 1 9 8 9 ) .
SDS no.4 33 HRDP
Wild diploid
Colchicine Ireatmenl
Wild diploid
Wild diploid
a. Production and testing
of hexaploids.
Hybrid
Colchicine treatment
cultivated tetraploid Allotelraploid
Hybrid lelraploid
Hybrid lelraploid
Cullivaled Letraploid
AutoLelraploid
b. Production of hybrid
tetraploids from diploids.
4x A. hypogaea like derivatives
Back crossed to A. hypogaea
Progenies 2 x , 3 x , 4x, 6x
Restitution nuclei x unequal
segregation produce gametes
x-3x
Cultivated lelraploid
Wild
diploid
Wild diploid
Cultivated Letraploid
Sterile triploid
Colchicine treatment
Hexaploid
Back crossed to Arachis hypogaea
4 x A. hypogaea like derivatives
Figure 2. Methods of producing hexaploids and hybrid tetraploids for backcrossing to Arachis hypogaea to transfer genes from wild species into cultivated groundnut.
X
X
X
X
X
The hybrids p r o d u c e d by crossing cultivated groundnut with the diploid wild species are triploid and sterile. Their fertility could be restored by induction of polyploidy using the colchicine technique developed by Spielman and M o s s (1976). In this technique, actively growing branches of sterile triploid hybrids are cut 20-30 mm above the node of young laterals. Leaves, buds and petioles are removed from the next 2 or 3 n o d e s ; a glass tube that fits tightly with the stem is filled with the colchicine solution and the second cut is made below the first cut (Singh et a l . 1 9 8 3 ) . Place the glass tube immediately over the cut end to maintain the flow of colchicine (Fig. 3 ) . Leave t h e t u b e on the plant for 24-48 h. It is important to prevent air b u b b l e s in the t u b e . After removing the tube, a hexaploid branch may develop which can flower and produce a peg. Another way of ploidy m a n i p u l a t i o n is successive back crossing of a triploid hybrid with A. hypogaea that results in fertile hexaploid hybrids (Singh 1986).
C. Use of incompatible species
Incompatible species from sections Rhizomatosae and Erectoides have been crossed w i t h A. hypogaea or diploid species of section Arachis' with the help of hormone treatments (GA3, IAA, and Kinetin) and/or in vitro embryo rescue t e c h n i q u e s . Hybrid plants have been established in two combinations (Sastri and Moss 1 9 8 2 ) .
Figure 3. Method of colchicine treatment of young laterals. (Source: Singh et a l . 1983)
34 SDS no. 4 HRDF
Developing hexapioid branch. First
cut Second cut
First cut
Colchicine
Glass tube
B. Ploidy manipulations
MP 5. Induced Mutagenesis
Mutagenesis
Treating a biological material with a mutagenic agent to induce mutants is m u t a g e n e s i s .
Physical m u t a g e n s . The most frequently used physical mutagens are x-rays, gamma rays, and neutrons. All these forms of radiations ionize atoms in a tissue by detaching electrons from the a t o m s .
X-rays are produced in special machines by bombarding tungsten or m o l y b d e n u m with electrons. For gamma-irradiations seeds are normally exposed using the radioactive isotopes cobalt-60 or cesium-137. in a gamma chamber. Neutrons are obtained from a nuclear reactor where uranium-235 fuel undergoes nuclear fission.
Physical m u t a g e n e s i s . The seed is dried to a low moisture content and put in sealed packets for irradiation. The seed is placed in the chamber for a fixed time depending on the dose of irradiation. In groundnut 5 kr, 10 kr, 15 kr, 20 kr, 30 kr, and 45 kr gamma irradiations are reported (Pathirana and Wijewickrama 1 9 8 2 ) . However, the most desirable groundnut mutants were recovered between 5-20 kr X-ray irradiation when .irradiated up to 75 kr (Patil 1 9 7 5 ) .
Chemical m u t a g e n s . These are agents that react with DNA by alkylating the phosphate groups as well as purine and pyrimidine b a s e s . Among the 30-40 chemical mutagens, some of the most powerful and useful are ethyl methane sulphonate (EMS), diethylsulfate (DES), ethylene-imine (EI), N - n i t r o s o - N-methyl Urethane (NMUT), N-nitro-N-methyl urea (NMU), and ethyl bromide (EB).
Chemical m u t a g e n e s i s . The effect of a chemical mutagen depends on its concentration, duration of treatment, temperature and pH of the mutagenic solution, and water content in seeds.
For chemical mutagenesis, soak the seed in water for 2-4 h, thereafter put the seed into the chemical at the desired concentration for 5-6 h. Then put the seed in a cloth bag under running tap water for 8-10 h to wash the excess chemical off the seed s u r f a c e . R e m o v e the excess water on the seed surface by drying for a few hours in the shade.
Selecting dose level
The highest number of induced mutations result when the number of fertile M1 plants is maximized to produce a large M2 generation. When using sparsely ionizing radiations (x-rays and gamma rays) in greenhouse t e s t s , an optimum dose should cause 3 0 - 5 0 % reduction in seedling h e i g h t . When densely ionizing radiations (neutrons) are used, the height reduction should be 1 5 - 3 0 % . With chemical mutagens, the reduction should be 1 0 - 3 0 % . In p r a c t i c e , an optimum dose is often achieved by using three separate doses (with an untreated c o n t r o l ) . One dose should be chosen based on reduction in seedling height in laboratory and field t e s t s . The other two doses should be about 1 0 % higher and 1 0 % lower (Sigurbjornsson 1 9 8 3 ) . A dose close to LD 50 (Lethal D o s e 50) should be optimum, since it provides a maximum percentage of useful m u t a n t s . LD 50 is that dose of mutagen that would kill 5 0 % of the treated individuals (Singh 1 9 8 3 ) .
35 SDS no, 4 HRDP
Amount of seed to be treated
A number of seeds should be treated with a mutagen to ensure identification of sufficient mutants in the M2 and later generations. The size of the M1 p o p u lation i.e., the number of seeds to be treated is partly governed by the effectiveness and the efficiency of the mutagen.
Brock (1976) calculated M2 progeny size and M1 population requirements according to the various mutant segregation ratios and the probability of the occurrence of homozygous m u t a n t s . Assuming a 5 0 % lethality in the M1 generation of 5000 p l a n t s , 2500 fertile survivors w o u l d be t e s t e d in the M2 generation. The M2 generation with 20 individuals per progeny would then be 20 x 2 500 = 50 000 p l a n t s . Thus a m i n i m u m of 5 000-10 000 seeds should be treated with a mutagen.
36 SDS no. 4 HRDP
The M1 generation starts with the germination of mutagen-treated seeds. The M 1 is heterozygous due to newly induced mutant genes and will segregate into mutants and nonmutants in the M2 generation. Only dominant mutations will be expressed in the M1 generation while recessives will be expressed in the M 2. Homozygous mutants are expressed in the M3 generation. The M1 generation should receive the best possible care to control weeds, insects, and diseases. This will help to transfer as many mutations as possible to the M 2 generation where selection for the desired genotypes will be done (Table 1 3 ) .
The M 2 could be generated from all the surviving plants (seeds of the M1 g e n e r a t i o n ) , or one can sample the better plants in the. M1. Redei (1974) recommended a large M1 population and small M2 families. The single seed descent or plant to row method, should be used in the mutation breeding program to identify low frequency of mutant p h e n o t y p e s .
T a b l e 1 3 . H a n d l i n g g e n e r a t i o n s o f m u t a n t s .
Year or crop season
Generation Operations
First M1 Sow the treated seed at wide spacing. Harvest seeds of individual plants separately.
Second M2 Grow individual plant progenies. Harvest vigorous, normal looking plants separately.
Third M3 Grow individual M2-plant progenies (M2) . Select superior plants among the progenies showing segregation and harvest separately.
Fourth M4 Grow individual M3-plant progenies (M3). Harvest superior and homogeneous lines in bulk. Reject segregating arid undesirable lines.
Fifth M5 Conduct a preliminary yield trial with suitable checks. Identify superior lines.
Sixth to eighth
M6-M9 Conduct replicated multilocation yield trials to identify outstanding lines for release as varieties.
Tenth Ml0-M11 Seed multiplication and on-farm testing.
(Source: Sigurbjornsson 1983; and Singh 1983).
Success of identifying mutants in the M 2 and M 3 p opulation may depend on ease of detection. By the M 5 or M 6 generation most of the mutants become homozygous and their seed can be multiplied for preliminary evaluation. Patil (1980) reported that over 6 0 % of the groundnut mutants appeared in the M2 and M3 generations. However, economically important mutants v i z . , the tertiary-branching and the large p o d size were isolated only after M3. Further, consistent selection for increased seed m a s s resulted in the isolation of the large p o d mutant in M5. Therefore, individual plant selection plays an important role in mutation breeding.
SDS no. 4 37 HRDF
MP 6. Handling the Mutation Breeding Population.
References
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Bailey, W . K . 1 9 6 8 . P e a n u t v a r i e t y i m p r o v e m e n t in t h e U S A . P a g e s 1-5 in P r o c e e d i n g s o f t h e F i f t h N a t i o n a l P e a n u t R e s e a r c h C o n f e r e n c e , 15-17 Jul 1 9 6 8 , N o r f o l k , V i r g i n i a , U S A . B l a c k s b u r g , V i r g i n i a , U S A : V i r g i n i a P o l y t e c h n i c I n s t i t u t e .
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B a l k i s h a n , P. 1 9 7 9 . S t u d i e s on the g e n e t i c p a r a m e t e r s in the F 2 g e n e r a t i o n o f eight c r o s s e s o f g r o u n d n u t (Arachis h y p o g a e a L . ) . M . S c . t h e s i s , A n d h r a P r a d e s h A g r i c u l t u r a l U n i v e r s i t y , H y d e r a b a d , A n d h r a P r a d e s h , I n d i a . 9 1 p p .
Basu, A . K . , and A s h o k r a j , P.C.A. 1969. G e n o t y p i c v a r i a b i l i t y i n some q u a n t i t a t i v e c h a r a c t e r s o f g r o u n d n u t . S c i e n c e and C u l t u r e 3 5 : 4 0 8 - 4 0 9 .
Basu, M . S . , N a g r a j , G., and Reddy, P . S . 1 9 8 8 . G e n e t i c s o f o i l and o t h e r m a j o r c o m p o n e n t s i n g r o u n d n u t (Arachis h y p o g a e a L . ) . I n t e r n a t i o n a l J o u r n a l o f T r o p i c a l A g r i c u l t u r e 6 ( 1 - 2 ) : 1 0 6 - 1 1 0 .
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B a s u , M . S . , Singh, N . P . , V a d d o r i a , M.A., and Raddy, P.S. 1986a. G e n e t i c a r c h i t e c t u r e o f y i e l d and its c o m p o n e n t s i n g r o u n d n u t (Arachis. h y p o g a e a L . ) . A n n a l s o f A g r i c u l t u r a l R e s e a r c h 7 : 1 4 4 - 1 4 8 .
B a s u . , M . S . , V a d d o r i a , M . A . , Singh, N . P . , and Raddy, P.S. 1986b. S t u d i e s o n h e t e r o s i s in inter and i n t r a - s u b s p e c i f i c c r o s s e s of g r o u n d n u t . J o u r n a l of O i l s e e d s R e s e a r c h 3 ( 2 ) : 2 2 3 - 2 3 0 .
Basu, M . S . , V a d d o r i a , M.A., Singh, N . P . , and Reddy, P . S . 1 9 8 7 . C o m b i n i n g a b i l i t y for y i e l d a n d its c o m p o n e n t s in d i a l l e l c r o s s of g r o u n d n u t . Indian J o u r n a l o f A g r i c u l t u r a l S c i e n c e s 5 7 : 8 2 - 8 4 .
B a r n a r d , R . L . 1 9 6 0 . The b r e e d i n g b e h a v i o r and i n t e r r e l a t i o n s h i p s o f some p o d a n d seed t r a i t s o f p e a n u t . P h . D . t h e s i s , N o r t h C a r o l i n a S t a t e U n i v e r s i t y , R a l e i g h , N C , U S A .
B h a r g a v a , P.D., D i x i t , P.K., Saxena, D.K., and B h a t i a , L.K. 1 9 7 0 . C o r r e l a t i o n s t u d i e s on y i e l d and its c o m p o n e n t s in erect v a r i e t i e s of g r o u n d n u t (Arachis h y p o q a e a L . ) . R a j a s t h a n Journal o f A g r i c u l t u r a l S c i e n c e s 1 : 6 4 - 7 1 .
B h u i y a n , S.A. 1 9 8 4 . I n h e r i t a n c e of p l a n t t y p e in g r o u n d n u t . Indian J o u r n a l o f G e n e t i c s a n d P l a n t B r e e d i n g 4 4 : 2 1 5 - 2 1 7 .
B i l q u e z , A . F . , and L e c o m t e , J. 1969. H e r e d i t e de la c o l o r a t i o n des fleurs c h e z l ' a r a c h i d e . (In F r . ) . O l e a g i n e u x 2 4 : 4 1 1 - 4 1 2 .
B o v i , M . L . A . , N o r d e n , A . J . , and Gorbat, D.W. 1983. Seed coat s p l i t t i n g in p e a n u t - its i n h e r i t a n c e a n d r e l a t i o n s h i p w i t h seed w e i g h t . P e a n u t S c i e n c e 1 0 : 3 6 - 4 0 .
B r a n c h , W . D . 1 9 7 9 . Q u a l i t i e s g e n e t i c i s t s look for. Peanut F a r m e r 1 5 : 9 .
B r a n c h , W . D . 1 9 8 9 . I n h e r i t a n c e o f d o m i n a n t w h i t e p e a n u t t e s t a c o l o r . J o u r n a l of H e r e d i t y 80 ( 2 ) : 1 5 5 - 1 5 6 .
B r a n c h , W . D . , K e r b y , J.S., W y n n e , J.C., H o l b r o o k , C.C., and A n d a r s o n , W . F . 1 9 9 1 . S e q u e n t i a l v s . p e d i g r e e s e l e c t i o n m e t h o d for y i e l d and leaf spot r e s i s t a n c e i n p e a n u t . C r o p S c i e n c e 3 1 : 2 7 4 - 2 7 6 .
B r o c k , R . D . 1 9 7 6 . P r o s p e c t s a n d p e r s p e c t i v e s i n m u t a t i o n b r e e d i n g . P a g e s 1 1 7 - 1 3 2 in G e n e t i c d i v e r s i t y in p l a n t s (Muhammed, A., A k s e l , R., and v o n B o r s t e l , R . C . , e d s . ) . N e w Y o r k , U S A : P l e n u m P r e s s .
B r o m f i e l d , K.R., and B a i l a y , W . K . 1 9 7 2 . I n h e r i t a n c e o f r e s i s t a n c e t o P u c c i n i a a r a c h i d i s i n p e a n u t . P h y t o p a t h o l o g y 6 2 : 7 4 8 . (Abstract.)
C a h a n a r , A . 1 9 7 8 . The i n h e r i t a n c e o f y i e l d c o m p o n e n t s and p l a n t c o n f o r m a t i o n i n p e a n u t s , A r a c h i s h y p o q a e a L . P h . D . t h e s i s , H e b r e w U n i v e r s i t y , J e r u s a l e m , I s r a e l .
C a h a n a r , A., H i l l e l , J., and A s h r i , A. 1 9 7 9 . D e t e c t i o n of g e n e t i c i n t e r a c t i o n s by a n a l y z i n g the F 2 g e n e r a t i o n of d i a l l e l c r o s s . T h e o r e t i c a l and A p p l i e d G e n e t i c s 5 5 : 1 6 1 - 1 6 7 .
C h a n d o l a , R . P . , D i x i t , P.K., and S a x a n a , D . K . 1 9 7 3 . N o t e o n p a t h c o e f f i c i e n t a n a l y s i s o f y i e l d c o m p o n e n t s i n g r o u n d n u t . Indian J o u r n a l o f A g r i c u l t u r a l S c i e n c e s 4 3 : 8 9 7 - 8 9 8 .
Chan, C.Y., a n d W a n , H. 1 9 6 8 . V a r i e t y x e n v i r o n m e n t i n t e r a c t i o n s in r e g i o n a l t r i a l s of s o y b e a n s and g r o u n d n u t and t h e i r i m p o r t a n c e in b r e e d i n g . J o u r n a l o f t h e A g r i c u l t u r a l A s s o c i a t i o n o f C h i n a , N e w S e r i e s 6 4 : 1 - 1 2 .
C o f f a l t , T.A., and H a m m o n s , R . O . 1 9 7 3 . E a r l y - g e n e r a t i o n t r i a l s o f p e a n u t s . P e a n u t S c i e n c e 1:3-6.
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C o f f e l t , T.A., and H a m m o n s , R . O . 1 9 7 4 a . I n h e r i t a n c e of p o d c o n s t r i c t i o n s in p e a n u t s . J o u r n a l o f H e r e d i t y 6 5 : 9 4 - 9 6 .
Coffelt, T.A., and H a m m o n s , R . O . 1 9 7 4 b . C o r r e l a t i o n and h e r i t a b i l i t y s t u d i e s of n i n e c h a r a c t e r s in p a r e n t a l and i n t r a s p e c i f i c c r o s s p o p u l a t i o n s of Arachis h y p o g a e a L . O l e a g i n e u x 2 9 : 2 3 - 2 7 .
Coffelt, T.A., and P o r t e r , D.M. 1 9 8 2 . S c r e e n i n g p e a n u t s for r e s i s t a n c e to S c l e r o t i n i a b l i g h t . P l a n t D i s e a s e R e p o r t e r 6 6 : 3 8 5 - 3 8 7 .
C o f f e l t , T.A., and P o r t e r , D.M. 1 9 8 6 . F i e l d s c r e e n i n g of r e c i p r o c a l c h i c o x f l o r i g i a n t p e a n u t p o p u l a t i o n s for r e s i s t a n c e to leafspot in V i r g i n i a . Peanut S c i e n c e 1 3 ( 2 ) : 5 7 - 6 0 .
C o m p t o n , W . A . 1 9 6 8 . R e c u r r e n t s e l e c t i o n i n s e l f - p o l l i n a t e d c r o p s w i t h o u t e x t e n s i v e c r o s s i n g . C r o p S c i e n c e 8 : 7 7 3 - 7 7 4 .
D a l a l . , J.L. 1 9 6 2 . I n h e r i t a n c e s t u d i e s i n g r o u n d n u t c r o p . I n d i a n O i l s e e d s J o u r n a l 6 : 2 8 8 - 2 9 2 .
D a s h i e l l , K . E . 1 9 8 3 . I n h e r i t a n c e o f n o d u l a t i o n and its a s s o c i a t i o n w i t h g e n e s c o n t r o l l i n g t e s t a c o l o r i n A r a c h i s h y p o g a e a L . D i s s e r t a t i o n A b s t r a c t s B 4 4 : 2 0 6 3 B .
da B e r c h o u x , C. 1 9 6 0 . L a r o s e t t e d e l'arachide en H a u t e v o l t a . C o m p a r t m e n t d e s l i g n e e s r e s i s t a n t e s . O l e a g i n e u x 1 5 : 2 2 9 - 2 3 3 .
D e s h m u k h , S.N., B a s u , M . S . , and R e d d y , P . S . 1 9 8 6 . G e n e t i c v a r i a b i l i t y , c h a r a c t e r a s s o c i a t i o n and p a t h c o e f f i c i e n t s o f q u a n t i t a t i v e t r a i t s i n V i r g i n i a b u n c h v a r i e t i e s o f g r o u n d n u t . Indian J o u r n a l o f A g r i c u l t u r a l S c i e n c e s 5 6 : 8 1 6 - 8 2 1 .
D h o l a r i a , S.J., and J o s h i , S.N. 1 9 7 2 . E f f e c t of high and low f e r t i l i z a t i o n o n v a r i a b i l i t y i n g r o u n d n u t (Arachis h y p o q a e a L . ) . Indian J o u r n a l o f A g r i c u l t u r a l S c i e n c e s 4 2 : 4 6 7 - 4 7 0 .
D h o l a r i a , S.J., J o s h i , S.N., and K a b a r i a , M . M . 1 9 7 3 . S e l e c t i o n i n d i c e s under high and low f e r t i l i t y i n g r o u n d n u t . M a d r a s A g r i c u l t u r a l J o u r n a l 6 0 : 1 3 8 3 - 1 3 9 3 .
D i x i t , P.K., B h a r g a v a , P.D., S a x e n a , D.K., and B h a t i a , L.K. 1 9 7 0 . E s t i m a t e s of g e n o t y p i c v a r i a b i l i t y of some q u a n t i t a t i v e c h a r a c t e r s in g r o u n d n u t (Arachis h y p o q a e a L . ) . I n d i a n J o u r n a l o f A g r i c u l t u r a l S c i e n c e s 4 0 : 1 9 7 - 2 0 2 .
D o r a i r a j , S.M. 1 9 6 2 . P r e l i m i n a r y steps for the f o r m u l a t i o n of s e l e c t i o n index for y i e l d i n g r o u n d n u t (Arachis h y p o q a e a L . ) . M a d r a s A g r i c u l t u r a l J o u r n a l 4 9 : 1 2 - 2 7 .
D u t t a , M., and R e d d y , L.J. 1 9 8 8 . F u r t h e r s t u d i e s on g e n e t i c s of n o n n o d u l a t i o n i n p e a n u t . C r o p S c i e n c e 2 8 ( 1 ) : 6 0 - 6 2 .
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E s s o m b a , N . B . , C o f f e l t , T.A., B r a n c h , W . D . , and S c o y o c , S.W.Van. 1 9 8 7 . I n h e r i t a n c e o f m o r p h o l o g i c a l t r a i t s i n p e a n u t (Arachis h y p o q a e a L . ) . P r o c e e d i n g s o f A m e r i c a n Peanut R e s e a r c h and E d u c a t i o n S o c i e t y 1 9 : 1 6 .
F i s h e r , R.A. 1 9 1 8 . O n the c o r r e l a t i o n b e t w e e n r e l a t i v e s o f the s u p p o s i t i o n o f M e n d e l i a n i n h e r i t a n c e . T r a n s a c t i o n s o f the R o y a l S o c i e t y o f E d i n b u r g h 5 2 : 3 9 9 - 4 3 3 .
Garet, B. 1 9 7 6 . H e t e r o s i s et a p t i t u d e s a la c o m b i n a i s o n c h e z l'arachid (Arachis h y p o q a e a L . ) . (In Fr.) O l e a g i n e u x 3 1 : 4 3 5 - 4 4 2 .
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G i b b o n s , R.W. 1 9 8 5 . B r e e d i n g for g r o u n d n u t r o s e t t e v i r u s d i s e a s e r e s i s t a n c e . P a g e 17 in C o l l a b o r a t i v e research on g r o u n d n u t r o s s e t t e v i r u s : s u m m a r y p r o c e e d i n g s o f the C o n s u l t a t i v e G r o u p M e e t i n g t o D i s c u s s C o l l a b o r a t i v e R e s e a r c h o n G r o u n d n u t R o s e t t e V i r u s D i s e a s e , 13-14 A p r 1985, C a m b r i d g e , UK. P a t a n c h e r u , A . P . 502 3 2 4 , India: I n t e r n a t i o n a l C r o p s R e s e a r c h I n s t i t u t e for t h e S e m i - A r i d T r o p i c s .
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G r e e n , C . C . 1 9 8 5 . E v a l u a t i o n and i n h e r i t a n c e of c o m p o n e n t s of p a r t i a l r e s i s t a n c e t o e a r l y l e a f s p o t (Cercospora a r a c h i d i c o l a Hori) i n p e a n u t . P h . D . t h e s i s , N o r t h C a r o l i n a S t a t e U n i v e r s i t y , R a l e i g h , N C , U S A .
Guok, H.P., W y n n e , J.C., and Stalker, H.T. 1986. R e c u r r e n t s e l e c t i o n w i t h i n a p o p u l a t i o n from an i n t e r s p e c i f i c peanut c r o s s . C r o p S c i e n c e 2 6 : 2 4 9 - 2 5 3 .
H a b i b , A . F . , J o a h i , M . S . , K u l l a i s w a m y , B . I . , and Bhat, B.N. 1 9 8 5 . C o m b i n i n g a b i l i t y e s t i m a t e s i n p e a n u t s (Arachis h y p o g a e a L . ) . Indian J o u r n a l o f G e n e t i c s and P l a n t B r e e d i n g 45 (2):235-239.
H a b i b , A . F . , J o a h i , M . S . , V i s h w a n a t h a , K.P., and J a y a r a m a i a h , H . 1 9 8 0 . G e n e t i c s of w h i t e f l o w e r in A r a c h i s h y p o g a e a L. N a t i o n a l S e m i n a r on the A p p l i c a t i o n of G e n e t i c s to Improvement of G r o u n d n u t , 16-17 Jul 1 9 8 0 , C o i m b a t o r e , I n d i a : T a m i l N a d u A g r i c u l t u r a l U n i v e r s i t y .
H a m m o n s , R . O . 1 9 5 7 . P e a n u t i n v e s t i g a t i o n s . A n n u a l r e p o r t , T i f t o n , GA, U S A : U n i t e d S t a t e s D e p a r t m e n t o f A g r i c u l t u r e , A g r i c u l t u r a l R e s e a r c h S e r v i c e .
H a m m o n s , R . O . 1 9 6 3 . W h i t e t e s t a i n h e r i t a n c e in the p e a n u t . J o u r n a l of H e r e d i t y 5 4 : 1 3 9 - 1 4 2 .
H a m m o n s , R . O . 1 9 7 1 . I n h e r i t a n c e of i n f l o r e s c e n c e in m a i n stem leaf a x i l s in A r a c h i s h y p o g a e a L . C r o p S c i e n c e 1 1 : 5 7 0 - 5 7 1 .
H a m m o n a , R . O . 1 9 7 2 . P e a n u t s . P a g e s 2 1 7 - 2 2 3 , 252 i n G e n e t i c v u l n e r a b i l i t y o f m a j o r c r o p s . W a s h i n g t o n , D C , U S A : N a t i o n a l A c a d e m y o f S c i e n c e s .
Hammona, R . O . 1 9 7 3 . G e n e t i c s o f A r a c h i s h y p o g a e a . P a g e s 135-173 in P e a n u t s - c u l t u r e a n d u s e s . S t i l l w a t e r , O K , U S A : A m e r i c a n P e a n u t R e s e a r c h and E d u c a t i o n A s s o c i a t i o n .
H a m m o n a , R . O . 1 9 7 4 . G e n e t i c v a r i a b i l i t y in p e a n u t s : a second look. P r o c e e d i n g s o f A m e r i c a n P e a n u t R e s e a r c h and E d u c a t i o n A s s o c i a t i o n 6 : 1 7 - 2 0 .
Hammona, R . O . 1 9 8 0 . I n h e r i t a n c e of a n e c r o t i c - e t c h leaf d i s e a s e in p e a n u t s . Peanut S c i e n c e 7 : 1 3 - 1 4 .
H a s s a n , M . A . 1 9 6 4 . G e n e t i c , f l o r a l , b i o l o g i c a l and m a t u r i t y s t u d i e s i n g r o u n d n u t . M . S c . t h e s i s , R a n c h i U n i v e r s i t y , R a n c h i , B i h a r , I n d i a .
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H a y e s , T.R. 1 9 3 3 . T h e c l a s s i f i c a t i o n o f g r o u n d n u t v a r i e t i e s w i t h p r e l i m i n a r y n o t e o n t h e i n h e r i t a n c e o f some c h a r a c t e r s . T r o p i c a l A g r i c u l t u r e (Trinidad) 1 0 : 3 1 8 - 3 2 7 .
B i g g i n s , B . B . 1 9 4 0 . I n h e r i t a n c e of seed coat color in p e a n u t s . J o u r n a l of A g r i c u l t u r a l R e s e a r c h (USA) 6 1 : 7 4 5 - 7 5 2 .
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H i g g i n s , B . B . , and B a i l e y , W.K. 1 9 5 5 . N e w v a r i e t i e s and s e l e c t e d s t r a i n s o f p e a n u t s . G e o r g i a A g r i c u l t u r a l E x p e r i m e n t S t a t i o n B u l l e t i n N e w S e r i e s 1 1 . 3 5 p p .
H o l l y , R.N., and W y n n a , J.C. 1 9 8 6 . E f f e c t i v e n e s s o f s t r a t i f i e d m a s s s e l e c t i o n for y i e l d in i n t r a - s u b s p e c i f i c a n d i n t e r - s u b s p e c i f i c c r o s s e s of p e a n u t . P e a n u t S c i e n c e 1 3 : 3 3 - 3 5 .
H u l l , F.H. 1 9 3 7 . I n h e r i t a n c e of rest p e r i o d of s e e d s a n d c e r t a i n o t h e r c h a r a c t e r i s t i c s i n t h e p e a n u t . T e c h n i c a l B u l l e t i n n o . 3 1 4 . G a i n e s v i l l e , F L , U S A : F l o r i d a A g r i c u l t u r a l E x p e r i m e n t S t a t i o n . p p 3 1 7 .
Husted, L. 1 9 3 4 . G e n e t i c a n d c y t o l o g i c a l s t u d i e s o n the p e a n u t , A r a c h i s . I . C y t o l o g i c a l s t u d i e s o n t h e p e a n u t , A r a c h i s . I I . C h r o m o s o m e n u m b e r , m o r p h o l o g y , a n d b e h a v i o r , a n d t h e i r a p p l i c a t i o n t o the p r o b l e m o f the o r i g i n o f t h e c u l t i v a t e d f o r m s . I I I . G e n e t i c s t u d i e s o n the p e a n u t , A r a c h i s . IV. A report on t h e i n h e r i t a n c e of some c h a r a c t e r s . P h . D . t h e s i s , U n i v e r s i t y of V i r g i n i a , V i r g i n i a , U S A . 9 6 p p .
I C R I S A T ( I n t e r n a t i o n a l C r o p s R e s e a r c h I n s t i t u t e for t h e S e m i - A r i d T r o p i c s ) . 1 9 8 0 . A n n u a l report 1 9 7 8 - 7 9 . P a t a n c h e r u , A . P . 502 3 2 4 , I n d i a : I C R I S A T . 288 p p .
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P r a s a d , M . M . K . D . 1 9 8 1 . G e n e t i c c h a r a c t e r i z a t i o n and h e t e r o t i c p o t e n t i a l o f v a r i e t a l g r o u p s i n g r o u n d n u t (Arachis h y p o q a e a L . ) . P h . D . t h e s i s , A n d h r a P r a d e s h A g r i c u l t u r a l U n i v e r s i t y , H y d e r a b a d , A n d h r a P r a d e s h , I n d i a . 303 p p .
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W y n n e , J . C , and R a w l i n g , J . O . 1 9 7 8 . G e n e t i c v a r i a b i l i t y a n d h e r i t a b i l i t y for a n inter c u l t i v a r c r o s s o f p e a n u t . P e a n u t S c i e n c e 5 : 2 3 - 2 6 .
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X i a n g , R . Y . , L i , X . Y . , Ling, S.X., and Zheng, G.Y. 1984. P r e l i m i n a r y a n a l y s i s of t h e F 1 s o f h i g h y i e l d i n g S p a n i s h - t y p e g r o u n d n u t c u l t i v a r s c r o s s e d w i t h rust r e s i s t a n t V a l e n c i a - t y p e s . G u a n g d o n g N o n g y e K e x u e 2 : 1 8 - 2 2 .
Y a d a v a , T.P., and K u m a r , P. 1978a. P h e n o t y p i c s t a b i l i t y of yield and its c o m p o n e n t s i n s e m i - s p r e a d i n g g r o u p o f g r o u n d n u t (Arachis h y p o q a e a L . ) . C r o p I m p r o v e m e n t 5 : 4 5 - 4 9 .
Y a d a v a , T.P., and K u m a r , P. 1978b. Stability a n a l y s i s for p o d yield and m a t u r i t y in b u n c h g r o u p of g r o u n d n u t , A r a c h i s h y p o q a e a L. Indian J o u r n a l of A g r i c u l t u r a l R e s e a r c h 1 2 : 1 - 4 .
Y a d a v a , T.P., and K u m a r , P. 1979. Studies on g e n o t y p e - e n v i r o n m e n t i n t e r a c t i o n for p o d y i e l d and m a t u r i t y i n g r o u n d n u t (Arachis h y p o q a e a L . ) . J o u r n a l o f R e s e a r c h , H a r y a n a A g r i c u l t u r a l U n i v e r s i t y 9:226-230.
Y a d a v a , T.P., K u m a r , P., and T h a k r a l , S.K. 1 9 8 4 . A s s o c i a t i o n of p o d y i e l d w i t h some q u a n t i t a t i v e t r a i t s in b u n c h g r o u p of g r o u n d n u t (Arachis h y p o q a e a L . ) . J o u r n a l o f R e s e a r c h , H a r y a n a A g r i c u l t u r a l U n i v e r s i t y 1 4 : 8 5 - 8 8 .
Y a d a v a , T.P., K u m a r , P., and Yadav, A . K . 1 9 8 1 . C o r r e l a t i o n and p a t h a n a l y s i s i n g r o u n d n u t . J o u r n a l o f R e s e a r c h , H a r y a n a A g r i c u l t u r a l U n i v e r s i t y 1 1 : 1 6 9 - 1 7 1 .
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Evaluation
Select the most appropriate answer and check the correct answer at the end of the booklet.
1. In groundnut the spreading growth habit is dominant over a) bunch. b) open habit. c) semispreading. d) all the above.
2. Dwarfism is a character. a) dominant b) complementary c) additive d) recessive
3. The erect growth habit in groundnut is a character. a) dominant b) epistatic c) recessive d) complementary
4. Dark or purple pigmentation of groundnut stems is a) dominant. b) recessive. c) additive. d) polygenic.
5. Albinism in groundnut ranges from yellow to white. Albinism is inherited due to
a) a single recessive gene. b) triplicate recessive genes. c) triplicate dominant genes. d) duplicate genes.
6. The character light green foliage on groundnut is a) dominant. b) recessive. c) epistatic. d) polygenic.
7. The dark green foliage character of groundnut is a) monogenic. b) digenic. c) trigenic dominant. d) trigenic recessive.
8. The elliptical-oblong and narrow leaf shape is governed by a) recessive genes. b) dominant genes. c) complementary genes. d) duplicate genes.
9. Inflorescence on the main axis of groundnut is governed by a) a single gene. b) two duplicate genes with epistatic action. c) complementary genes. d) three genes.
10. The dark corolla color character is due to a gene. a) recessive b) dominant c) epistatic d) complementary
11. The boat shaped wing petal is a character. a) digenic b) monogenic dominant c) trigenic d) polygenic
12. The large pod is a character. a) recessive b) dominant c) epistatic d) complementary
13. Yellow and white corolla colors in groundnut are inherited due to a) dominance. b) duplicate epistasis. c) incomplete dominance. d) cytoplasmic factors.
14. The number of flowers plant-1 is inherited due to a) epistatic genes. b) complementary genes. c) additive dominant genes. d) duplicate genes.
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15. The chlorophyll deficiency in groundnut is governed by a) a single gene. b) two genes. c) three genes. d) cytoplasmic factors.
16. The presence of pod constrictions in groundnut is a character. a) dominant b) recessive c) epistatic d) complementary
17. The large seed size in groundnut is a character. a) recessive b) dominant c) additive d) polymorphic
18. Long seed shape and flat ends of seed are a) recessive characters. b) dominant characters. c) quantitative characters. d) complementary characters.
19. The red testa color in groundnut is governed by a a) dominant gene. b) recessive gene. c) epistatic gene. d) complementary gene.
20. The characters of flesh, white, pink, and purple testa colors are a) monogenic. b) digenic. c) trigenic. d) tetra genic.
21. The presence of seed dormancy is a) recessive to nondormancy. b) dominant to nondormancy. c) partially dorminant to nondormancy. d) none of the above.
22. The high protein content in groundnut is a character. a) recessive b) dominant c) epistatic d) duplicate
23. High oil percentage in groundnut is a a) recessive character. b) dominant character. c) digenic character. d) epistatic character.
24. Violet color and stem hardiness in groundnut are linked with a a) thick pericarp and bold seed size. b) thick seed coat and pod constriction. c) white seed color. d) thin pericarp and small seed size.
25. The characters late maturity, small seed size, separate pod cells and low yield in groundnut showed linkages with resistance to
a) rust. b) bud necrosis. c) collar rot. d) late leaf spot.
26. The Spanish plant type in groundnut is controlled by duplicate genes a) Va1 Va1, va2 va2. b) va1 va1, Va2 Va2. c) va1 va1, va2 va2. d) Va1 Va1, Va3 Va3.
27. The Virginia (runners)-plant type of groundnut is controlled by duplicate genes
a) Va1 Va1, Va2 Va2. b) Va1 Va1, va2 va2. c) va1 va1, Va2 Va2. d) Va1 Va1, Va3 Va3.
28. The heritability of pod yield plant-1 in groundnut is a) low. b) high. c) moderate to high. d) varies from high to low.
29. The heritability estimated in groundnut for mature pods plant-1 is a) high. b) low. c) moderate. d) varies from high to low.
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30. Characters that have high heritability in groundnut are a) pod yield, pod mass, pod length, and seeds pod-1. b) 100 seed mass, pod breadth, days to flowering,
plant height, and primary branches. c) days to maturity and seeds pod-1. d) none of the above.
31. Pod characters in groundnut include size and constriction The one that is dominant is
a) small pod size. b) large pod size. c) absence of pod constriction. d) none of the above.
32. Seeds pod-1 in groundnut may be one or more than three and they are small to large in size. Which one is dominant?
a) A few seeds pod-1. b) Small seed size. c) Three or more seeds pod-1. d) None of the above.
33. The characters dwarfism, yellow corolla, and spanish-plant type of groundnut are controlled by
a) dominant genes. b) recessive genes. c) epistasis. d) complementary genes.
34. Resistance to groundnut rosette virus is controlled by a) complementary genes. b) dominant genes. c) recessive genes. d) duplicate genes.
35. Resistance to cercospora leafspot in groundnut is reported to be controlled by
a) recessive genes. b) two or more nuclear genes. c) additive genes. d) all the above.
36. Rust resistance in groundnut is a) dominant to susceptibility. b) recessive and controlled by duplicate genes. c) controlled by cytoplasmic genes. d) none of the above.
37. Resistance to Necrotic-etch in groundnut is a) recessive to normal. b) dominant to normal with digenic ratio; 15 nondisease:l disease. c) complementary. d) cytoplasmic in nature.
38. Sclerotinia blight resistance in groundnut is controlled by a) dominant genes. b) recessive genes. c) epistatic genes. d) cytoplasmic factors.
39. The primary branches, pods plant-1, 100 seed mass, and oil contents are important components of groundnut yield. The character negatively correlated with yield is
a) number of pods plant-1. b) 100 seed mass. c) primary branches plant-1. d) oil content.
40. In groundnut, the correlation of protein to oil content is a) negative. b) positive. c) positive low. d) not known.
41. High heterosis for vegetative characters and pod yield have been reported in groundnut involving crosses.
a) Virginia x Spanish b) Spanish x Virginia c) Spanish x Valencia d) none of the above
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42. High heterosis for pod yield and fruit characters in groundnut have been reported involving crosses.
a) Spanish x Virginia b) Virginia x Spanish c) Spanish x Valencia d) Valencia x Spanish and Virginia x Spanish
43. High general combining ability (GCA) is indicative of additive genes where as specific combining ability (SCA) indicates nonadditive genes. Studies on groundnut indicate most quantitative characters are governed
a) by additive genes. b) by nonadditive genes. c) by additive and nonadditive genes. d) monogenically.
44. When additive genetic variance is high and breeders want to develop homozygous lines, the appropriate breeding method is
a) multiline breeding. b) backcross breeding. c) mass selection. d) pedigree and modified pedigree selection.
45. The important characters directly influencing groundnut yield are a) oil content and shelling percentage. b) plant height and days to flowering. c) 100 seed mass and mature pods plant-1. d) secondary branches and early maturity.
46. Two characters having a negative effect on pod yield in groundnut are a) 100 seed mass and mature pods plant-1. b) plant height and days to 50% flowering. c) oil content and protein content. d) primary and secondary branches.
47. Protein and oil contents are inherited a) quantitatively. b) cytoplasmically. c) qualitatively. d) due to interaction of nuclear and cytoplasmic genes.
48. The main objectives of groundnut breeding at ICRISAT are for high a) yield and oil content. b) resistance to insect pests and diseases. c) resistance to drought and adaptation to specific
environment with early, medium, and late maturity. d) all the three above.
49. ICRISAT maintains a world collection of groundnut germplasm of over accessions.
a) 5 000 b) 10 000 c) 12 000 d) 15 000
50. In groundnut, negative correlations were reported between a) pod numbers and mass of pods plant-1. b) number of pods and 100 seed mass. c) size of pod and size of seed. d) number of seeds and seed mass plant-1.
51. The correlation of large pod size with yield was reported to be a) negative. b) positive and low. c) positive and high. d) no correlation,
52. Multiline varieties of groundnut are useful in obtaining a) homozygosity. b) heterosis. c) stability and adaptation. d) none of the above.
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53. Early generation testing in groundnut is useful to a) incorporate one or two genes. b) obtain homozygous lines. c) develop multilines. d) eliminate undesirable crosses.
54. Days to maturity and fruit size in groundnut are controlled by a) duplicate genes. b) additive genes. c) complementary genes. d) none of the above.
55. Two most important wild species of Arachis with pest resistant characters used at ICRISAT in interspecific hybridization are
a) Arachis qlabrata and A. appressipila. b) Arachis duranensis and A. villosa. C) Arachis correntina and A. stenosperma. d) Arachis chacoense and A. cardenasii.
56. Groundnut varieties developed by mutation breeding are a) ICGS 11 and ICGS 44. b) TMV 2 and J 11. c) TG 1 and TG 18A. d) CS9 and CS 30.
57. After germination, flowering in groundnut starts in a) 10-15 days. b) 15-25 days. c) 25-35 days. d) 35-45 days.
58. In groundnut after emasculation, pollination is carried out a) immediately. b) the next morning at 0600-0800. c) the next morning at 1000-1200. d) after 2 days.
59. The maximum physiological development of pollen in groundnut takes place between
a) 0300-0500. b) 0500-0700. c) 0700-0900. d) 0900-1100.
60. A criteria for selecting groundnut for earliness is a) minimum flowering in short span of time. b) maximum flowering in short span of time. c) continuous flowering till maturity. d) none of the above.
61. Selection for drought resistance under stress conditions should be based on
a) total biomass production unit-1 area. b) least difference in yield under stress and irrigated conditions. c) high pod yield under stress condition. d) all the three above.
62. For higher adaptation it is better to select a genotype that performs well under a
a) rich environment. b) poor environment. c) poor environment and well responsive to rich environment. d) poor environment and nonresponsive to rich environment.
63. Large seeded, well shaped, uniform seed size groundnut are selected for a) oil purpose. b) confectionery purpose. c) oil and confectionery purpose. d) none of the above.
64. For nutritional and food quality purposes selection of groundnut should be based on
a) high protein content. b) high oil content. c) high oleic by linoleic acid ratio. d) none of the above.
65. The most common selection procedure used at ICRISAT for handling segregating generations is
a) pedigree selection. b) bulk selection. c) modified-bulk selection. d) single pod descent.
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66. Preliminary yield trials start in the a) F4 generation. b) F5 generation. c) F6 generation.
67. Before giving material for national programs and release, it is necessary to test in multi-location international trials for
a) 1 year. b) 2 years. c) 3 years. d) 4 years.
68. The chemical useful to induce fertility in triploids of interspecific hybrids is
a) indole acetic acid. b) EMS. c) colchicine. d) alcohol.
69. To restore fertility in triploid hybrids of interspecific crosses, besides colchicine treatment another way is to cross with
a) a wild diploid. b) a haploid. c) a back cross with tetraploid cultivated. d) none of the above.
70. Treating a biological material (seed, bud, or vegetative part) with a mutagenic agent to induce mutation is
a) breeding. b) hybridization. c) mutagenesis. d) polyploidization.
71. The most common physical mutagens are a) EMS, DES and EI. b) gamma rays, x-rays and UV rays. c) acetocarmin, indole acetic acid. d) sun rays, hot water.
72. The highest numbers of induced mutation results when the number of a) sterile M,s are maximum. b) fertile M,s are maximum. c) sterile M2s are maximum. d) fertile M2s are maximum.
73. An optimum dose of mutagenic agent reduces seedling height by a) 5-10%. b) 10-20%. c) 15-30%. d) more than 50%.
74. To ensure maximum mutations, the minimum number of seeds of groundnut should be about
a) 100-200. b) 1000-2000. c) 3000-4000. d) 5000-6000.
75. To identify low frequency mutations in advanced generations it is better to use
a) the pedigree method. b) the bulk method.
c) single seed descent. d) recurrent selection.
76. In mutation breeding material, the preliminary trial is conducted in the
a) M2 generation. b) M5 generation. c) M7 generation. d) M8 generation.
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d) F8 generation.
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Correct responses to the questions.
1. d ) ; 2. d ) ; 3 . c ) , 4 . a ) ; 5 . b ) ; 6. b ) ; 7. c ) ; 8. b ) ; 9 . b ) ;
10. b ) ; 11. b ) ; 12. b ) ; 13. b ) ; 14. b ) ; 15. d ) ; 16. b ) ; 17. b ) ;
18. b ) ; 19. a ) ; 20. b ) ; 21. c ) ; 22. b ) ; 23. a ) ; 24. d ) ; 25. d) ;
26. a ) ; 27. c ) ; 28. d ) ; 29. d ) ; 30. b ) ; 31. b ) ; 32. c ) ; 33. c ) ;
34. d ) ; 35. a ) ; 36. b ) ; 37. b ) ; 38. d ) ; 39. d ) ; 40. a ) ; 41. b) ;
42. d ) ; 43. c ) ; 44. d ) ; 45. c ) ; 46. c ) ; 47. c ) ; 48. d ) ; 49. c ) ;
50. b ) ; 51. b ) ; 52. c ) ; 53. d ) ; 54. b ) ; 55. d ) ; 56. c ) ; 57. c ) ;
58. b ) ; 59. b ) ; 60. d ) ; 61. c ) ; 62. c ) ; 63. c ) ; 64. c ) ; 65. c ) ;
66. b ) ; 67. c ) ; 68. c ) ; 69. c ) ; 70. b ) ; 71. b ) ; 72. c ) ; 73. d ) ;
74. c ) ; 75. b ) ; 76. b) .