abuaku thesis
TRANSCRIPT
KWAME NKRUMAH UNIVERSITY OF SCIENCE AND TECHNOLOGY
COLLEGE OF AGRICULTURE AND NATURAL RESOURCES
FACULTY OF RENEWABLE NATURAL RESOURCES
DEPARTMENT OF WILDLIFE AND RANGE MANAGEMENT
THE INFLUENCE OF PLANT SPECIES ON DISTRIBUTION OF KOB (KOBUS KOB) IN
THE HEADQUARTERS AREA OF MOLE NATIONAL PARK
HOWARD HENRY ABUAKU
MAY, 2012
KWAME NKRUMAH UNIVERSITY OF SCIENCE AND TECHNOLOGY
COLLEGE OF AGRICULTURE AND NATURAL RESOURCES
FACULTY OF RENEWABLE NATURAL RESOURCES
DEPARTMENT OF WILDLIFE AND RANGE MANAGEMENT
THE INFLUENCE OF PLANT SPECIES ON DISTRIBUTION OF KOB (KOBUS KOB) IN THE HEADQUARTERS AREA OF MOLE NATIONAL PARK
A THESIS SUBMITTED TO THE FACULTY OF RENEWABLE NATURAL RESOURCES KWAME NKRUMAH UNIVERSITY OF SCIENCE AND TECHNOLOGY IN PARTIAL
FULFILMENT OF THE REQUIREMENTS FOR THE AWARD OF BACHELOR OF SCIENCE DEGREE IN NATURAL RESOURCES MANAGEMENT.
HOWARD HENRY ABUAKU
MAY, 2012
i
ABSTRACT
The number of plant species in an area is expected to influence the number of animal species,
and at small spatial scales such positive associations have been widely found in both
experimental and observational studies. The study was conducted to estimate kob (Kobus kob)
sign density, plant species density and determine the relationship between plants species density
and kob density. The study was conducted at the Headquarters area of Mole National Park to
survey kob density. A combination of direct and indirect methodology was used to record kob
signs on line transects whiles quadrats were used to survey plants species. An overall density of
10 signs per km of kob was estimated and a total of 44 plant species were estimated out of which
9 were significant. Generally the regression models showed two patterns, for some plant species
highest kob abundance occurred at lowest plant densities indicating a negative relationship
whereas for other plant species highest kob abundance occurred at highest plant densities
indicating a positive relationship. Kob activity was not much at the headquarters area and could
be attributed to tourist disturbance and human activities. Various plant species were found in
MNP and it is recommended that further studies should be conducted to explain the negative
influence they have on kob density.
ii
ACKNOWLEDGEMENTS
I thank God for His mercies and love shown on me during all the years spent on campus and for
His inspiration and wisdom granted me during the writing of this work. I am also indebted to my
supervisor Mr. Emmanuel Danquah, Senior lecturer, Head of Department Wildlife and Range
Management, whose immense contributions, criticism and unwavering commitment has made this
research a success. To all the lecturers in Wildlife and Range Management Department I say
thank you for such a wonderful tuition and discipline you instilled in me during my education.
To Mr. Mac Elikem Nutsuakor a Senior Technician, Department of Wildlife and Range
Management I say thank you for your assistance and critique.
I also cannot forget all the sacrifices made by my parents Mr. and Mrs. Howard and my siblings
for contributing to who I am today, I hereby dedicate this work to. To my uncle Mr. Ben Adu-
wusu, for your contributions you have made towards my education since infancy I say thank you.
To my friends Franz Alex Gaisie-Essilfie, Alfred Barah, Josiah Aduko, Christiana Adofoa, Abena
Amoah-Kusi and Agyeiwaa Ampofo I say thank you.
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TABLE OF CONTENT
ABSTRACT .....................................................................................................................................................i
ACKNOWLEDGEMENTS ........................................................................................................................... ii
TABLE OF CONTENT ................................................................................................................................ iii
List of Figures ................................................................................................................................................. v
List of Tables .................................................................................................................................................vi
CHAPTER ONE ............................................................................................................................................. 1
1.0 INTRODUCTION .................................................................................................................................... 1
1.1 Background ..................................................................................................................................... 1
1.2 Justification ..................................................................................................................................... 2
1.3 Aim and Objectives ......................................................................................................................... 3
CHAPTER TWO ............................................................................................................................................ 4
2.0 LITERATURE REVIEW ................................................................................................................... 4
2.1 Kob Traits and Ecology .................................................................................................................. 4
2.2 Kob Social Behaviour ..................................................................................................................... 5
2.3 Reproduction in Kob ....................................................................................................................... 6
2.4 Predation ......................................................................................................................................... 7
2.5 Plants ............................................................................................................................................... 8
2.6 Plant Nutrition ................................................................................................................................. 8
2.7 Plant and Animal interactions ......................................................................................................... 9
2.8 Density .......................................................................................................................................... 10
CHAPTER THREE ...................................................................................................................................... 11
3.0 MATERIALS AND METHODS ...................................................................................................... 11
3.1 Materials ....................................................................................................................................... 11
3.1.1 Study area description ........................................................................................................... 11
3.1.2 Climate .................................................................................................................................. 12
3.1.3 Vegetation ............................................................................................................................. 12
3.2 Methods......................................................................................................................................... 15
3.2.1 Data collection ...................................................................................................................... 15
3.2.2 Data analysis ......................................................................................................................... 17
CHAPTER FOUR ......................................................................................................................................... 18
4.0 RESULTS ......................................................................................................................................... 18
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4.1 Estimate of kob sign density ......................................................................................................... 18
4.2 Estimate of Plant Density .............................................................................................................. 18
4.3 Relationship between Plant Species density and Kob Sign Density ............................................. 19
4.4 Regressional analysis .................................................................................................................... 20
CHAPTER FIVE .......................................................................................................................................... 24
5.0 DISCUSSION ................................................................................................................................... 24
5.1 Kob Densities ................................................................................................................................ 24
5.2 Plant density .................................................................................................................................. 25
5.2.1 Summary of Major Plant Species .......................................................................................... 25
5.3 Relationship between Plant Species density and Kob Sign Density ............................................. 28
CHAPTER SIX ............................................................................................................................................. 31
6.0 CONCLUSIONS AND RECOMMENDATIONS ........................................................................... 31
Conclusions ............................................................................................................................................... 31
Recommendation ...................................................................................................................................... 32
LITERATURE CITED ................................................................................................................................. 33
Appendices .................................................................................................................................................... 38
Appendix 1: Type and Density of Plant Species ....................................................................................... 38
v
List of Figures
Figure 3.1: Map of Study Area ....................................................................................................... 11 Figure 3.2: Map of Study Area showing transect origins ............................................................... 16 Figure 4.1: Spatial pattern of Kob signs distribution in Mole National Park……………………..19 Figure 4.2: Relationships between Kob signs per km and a suite of plant species.........................21 Figure 4.3: Relationships between Kob signs per km and a suite of plant species……………….22
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List of Tables
Table 4.1: Correlation coefficients (r) between kob signs per km and a suite of plants species recorded on transects. Sample size is 8 transects ............................................................................ 20
1
CHAPTER ONE
1.0 INTRODUCTION
1.1 Background
The number of plant species in an area is expected to influence the number of animal species,
and at small spatial scales such positive associations have been widely found in both experimental
and observational studies (Siemann et al., 1998; Knops et al., 1999; Haddad et al., 2001). Such
associations have also been used to argue that one of the ecosystem functions provided by diverse
plant communities is the maintenance of rich animal communities (Knops et al., 1999).
However, whether or not this ‘function’ operates at larger extents or for all animal groups is less
certain.
At some very gross level plant and animal richness patterns must be congruent, since both increases
from the poles to the tropics. But even if true, it begs the more interesting ecological question of
the extent that this covariation is causal or coincidental. If plant diversity strongly influences
animal diversity at broad scales , then it follows that to understand animal diversity gradients we
need only know what drives plant diversity and then explain total biotic diversity as a special
case of resource–consumer interactions, whereas if links between plant and animal diversity are
non-causal, then we need to understand what aspects of the environment can drive both patterns
simultaneously.
Given that there is widespread evidence that elements of climate influence both plant and animal
diversity gradients at broad spatial scales (Wright et al., 1993; Hawkins et al., 2003), the key to
2
answering this question is not simply to correlate plant and animal richness gradients, but to include
simultaneously both plant richness data and climatic variables in analyses of animal diversity
patterns to determine how they covary in concert.
Plant-animal interactions and their effects on ecosystem properties assume particular importance
in protected areas where management decisions have to be taken according to vegetation status
and animal distribution and density. Browsing impact on vegetation communities also assumes
particular importance in protected areas where management decisions have to be taken
according to vegetation status, and animal distribution and density.
The headquarters area of the Mole National Park (MNP) was selected for this study because the
high visitor influx in the area has resulted in substantial variation in the level of anthropogenic
disturbance, making it an ideal setting to test the joint effects of vegetation modifications on
species distributions. The study focused on kob (Kobus kob) that have been widely used as
indicators of forest fragmentation and habitat disturbance due to their close relationships with
forest cover and vegetative complexity (Chiarello, 2000) and can be sampled with relatively
simple methods like transects (Conroy,2006). Another reason for the study of kob was that they
serve as important sources of food for indigenous people and are the focus on many ongoing
conservation efforts in the region.
1.2 Justification
Effective conservation of kob in Mole National Park requires scientific knowledge underpinning
management decisions and on-ground actions. Yet, there is general lack of ecological research on
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kob in Ghana which limits our ability to make even generalizations about the habitat requirements
of the species living in such landscapes, and hence suggest management recommendations. A
further complication is the large variation in habitat requirements among species (Jellinek et al.,
2004; Monamy and Fox, 2005). Hence, conservation managers face significant uncertainty
regarding the most appropriate management strategies for achieving long-term conservation
outcomes for kob and the diversity of native fauna species in MNP. If kob are to be conserved in
MNP, it is vital that we understand the habitat requirements and sensitivities of the species. This
requires understanding how both species’ density is influenced by local-level habitat factors like
vegetation type and its implications for tourism.
1.3 Aim and Objectives
The study provides some of the first quantitative data on kob species density in the headquarters
area of the Mole National Park (MNP), and one of the first comparisons across vegetation types.
Specifically, the objectives of the study are to;
1. Estimate kob sign density (encounter rate) at the headquarters area of MNP.
2. Estimate the density of plant species in the study area.
3. Determine the relationship between plant species density and kob sign density.
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CHAPTER TWO
2.0 LITERATURE REVIEW
2.1 Kob Traits and Ecology
The Kob (Kobus kob) is a medium sized antelope; the males are heavier than females they stand
approximately 92cm high at the shoulder. Kobus kob has a short reddish brown coat with a white
throat-patch and white underparts. The male kob is robustly built and has a muscular neck and
thick, lyrate horns. Females are more slender and lack horns (Kingdon, 2007). Males are 90-100
cm long and have an average weight of 94 kg. Females are 82-92 cm long and weigh on average
63 kg (Kingdon, 2007) (Estes, 1991).The bushy tail is white underneath and terminates with a
black tip with a length of 20-40 cm.
The kob has a scattered and patchy distribution ranging from Senegal and Guinea-Bissau to
Uganda, southern Sudan, and south-east Ethiopia (IUCN SSC Antelope Specialist Group (2008).
It requires low-lying flats or gently rolling country close to permanent water with no severe
seasonal extremes (Kingdon, 2007). Having likely evolved from a reedbuck-like ancestor, the kob
is largely tied to floodplain grasslands. However, it is not cover-dependent and avoids flooded
ground and steep slopes (Estes, 1991). Kob are herbivores and its preference for perennial grasses
in early, palatable stages and its need to drink daily makes it tied to green pastures that are well
watered (Kingdon,2007). During the rainy season, kob concentrate in areas of short grass and
high dry ground and keep these pastures short while ungrazed grassland grow tall and rank (Estes,
1991). Due to its dependence on water, any extension of ecological range into drier habitats stops
short of the point where there is no more access to moist green growth, or adequate water
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(Kingdon, 2007). The kob are able to congregate and move from one resource to another. These
movements follow seasonal changes in pasture (Kingdon, 2007). In areas with extensive flooding,
traveling can involve many hundreds of kilometres. Daily treks to water in the dry season may
require a walk of 10 km or more (Kingdon, 2007).
2.2 Kob Social Behaviour
Kob have few strong social bonds; however females live in herds of which can reach thousands.
The females also tend to be more mobile and more social than territorial males which remain
attached to their static territories as long as possible (Kingdon, 2007). It is the females that lead
the daily movements to water regardless of the length of time, scale or proximity. Individual
young kob learn their routines from their mothers. However, the higher the density of individuals
the more females will take their cues from other females (Kingdon, 2007). Males follow the
females and may be an integral part of their herds. All-males herds that number up to several
hundred individuals may associate with females during the dry season marches.
The social and reproductive organization of kob can vary. At average or low population densities,
males establish conventional territories that are spaced at least 100-200 m apart (Estes, 1991).
Adult males try to establish their territories in the best habitat available which are inhabited by
herds of females and their young. These herds are loosely structured and have open, changing
composition and size as the animals move about their range searching for greener pastures. Non-
territorial males, particularly young males, live in bachelor herds and are segregated from the
females by the territorial males. On floodplains, where kob live in high population densities,
around two thirds of the territorial males defend conventional territories while the rest live in
clustered territories known as leks (Estes, 1991). These clusters may be no larger than a single
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conventional territory. Lek clusters are located on short grass and bare ground and are surrounded
by taller grassland. As such, these territories have litter to no value other than the males that
reside in them. 8-9 of every 10 females visit leks to mate which makes it worth it for males to
forego space and food for greater reproductive success (Estes, 1991). Females and bachelor males
live in large herds of up to 2000 and circulate around a lek. Where are in the middle of the best
pastureland and are near waterholes and well-travelled routes. Females visit these leks only to
breed, and males provide no parental care. This mating system may have evolved because males
cannot defend the widely-dispersed food resources or the dynamic and temporary female herds
(Deutsch, 1994a). Within a lek, 20 to 200 males defend territories 15 to 200 meters in diameter
(Nowak, 1991). Male territories are smallest and most highly-contested in the center of the lek,
where most mating occurs. These territories maintain their popularity among females despite
rapid male turnover (Deutsch, 1994a). In areas of lower population density, males are spaced
farther apart and hold their territories for longer periods of time (Nowak, 1991). Each lek is
associated with a female herd of about 100 individuals.
2.3 Reproduction in Kob
Females begin to mate at the age of one year, but males must normally wait for several more
years (Nowak, 1991). Larger numbers of females associate with larger leks, possibly because
females stay on the lek longer when more males and other females are present (Deutsch, 1994b).
Females begin to ovulate at 13-14 months and come into oestrous every 20-26 days until they are
inseminated. Courtship by males differs between males of conventional territories and lek
territories. Males of conventional territories will try to prevent females from leaving and will
7
chase and herd them (Estes, 1991). Lek males are unable to keep females from escaping, although
they try. Kob courtship may last as little as 2-3 minutes and copulation may only last 1-2 seconds
(Buechner and Schleoth, 1966). At leks, a female may copulative up to 20 times by one or more
of the central males. Gestation lasts 261–271 days after which a calf is usually dropped, with a
sex ratio of about 1:1 (Haltenorth and Diller, 1994). For their first month, calves lie concealed in
high grass. Mothers and their calves use their noses to identify one another. When they pass the
hiding stage, calves join crèches and rarely go into tall grass. They rest together in available
shades. When they are 3-4 months old, the young join the female herds and associate with their
mothers until they are weaned at 6-7 months. When they mature, males join bachelors groups
(Estes, 1991).
2.4 Predation
The sedentary nature of Kob and their tendency to occur in relatively large concentrations make
them highly susceptible to hunting. Buffon's Kob, (Kobus kob kob) in particular, has been
eliminated from large parts of its former range by poaching for meat and now survives mainly in
and around protected areas. Poaching has caused large-scale declines of key populations areas
(East, 1999). The kob is preyed upon by several species, including common jackal Canis aureus,
spotted hyena Crocuta crocuta, olive baboon Papio anubis and lion Panthera leo (Wanzie, 1986;
Kingdon,1982).
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2.5 Plants
Plants include family organisms such as trees, flowers, herbs, shrubs, grasses, vines, ferns, mosses
and green algae. The group is also called Green Plant or Viridiplantae in Latin (Lewis,
2004).They obtain most of their energy from sunlight via photosynthesis using chlorophyll
contained in chloroplasts, which gives them their green colour. The plant kingdoms comprises
about 260,000 known species of mosses, liverworts, fern, herbaceous and woody plants, shrub,
vines, trees and various other forms that mantle the earth and are also found in its waters (Raven,
2008).
2.6 Plant Nutrition
Just as animals need certain nutrients, such as carbohydrates, amino acids, and vitamins to
survive, plants also need various nutrients to remain alive and healthy. Lack of important nutrient
may slow a plants growth or make the plant more susceptible to disease or even death. Plants
acquire these nutrients primarily from soil through their roots; although some take a more direct
approach example, the carnivorous plants are able to obtain some nutrients directly from small
animals (Mengel et al., 1982). Plants require a number of inorganic nutrients. Some of these are
macro nutrients which the plants need in relatively large amount and others are micro nutrients,
which are required in trace amounts.
There are nine macronutrients, carbon, hydrogen and oxygen – the three elements found in all
organic compounds as well as nitrogen, potassium, calcium, phosphorus, magnesium, and sulphur
(Kirkby et al., 1982). Each of these nutrients approaches or, as in the case with carbon, may
greatly exceed 1% of the dry weight of a healthy plant. The seven micronutrients elements are
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iron, chlorine, copper, manganese, zinc, molybdenum, and boron which constitute from less than
one to several hundred parts per million in most plants.
2.7 Plant and Animal interactions
Large mammalian herbivores not only depend on plant communities for their existence but cause
major changes in plant community composition and structure (Augustine and McNaughton, 1998)
The effect ungulates exert on plant communities depends on the balance between feeding
selectivity of herbivores thus the degree to which different plant species or ecotypes experience
different levels of tissue loss, and differences among plant species in their ability to recover from
tissue loss (Augustine and McNaughton, 1998).
The selectivity of ungulate herbivory leads to the dominance of unpalatable chemically defended
plant species in communities. However, studies have also demonstrated that intensive long-term
herbivory does not lead to the invasion of unpalatable species into the community, and can even
increase the dominance of highly palatable species (Augustine and McNaughton, 1998). High
levels of nutrient inputs or recycling and an intermittent temporal pattern of herbivory (often due
to migration) are key factors increasing the regrowth capacity of palatable species and hence
maintaining their dominance in plant communities and supports abundant herbivores. Key factors
limiting ungulate foraging selectivity, again limiting herbivore-induced dominance of slow-
growing, unpalatable species, include herding behaviour, early growing season and post-fire
herbivory, asynchronous phenology of palatable versus unpalatable species, and low relative
abundance of unpalatable species (Augustine and McNaughton, 1998).
10
2.8 Density
Density is the number of individuals per unit area (Wayne and James 1986, Sanford, 1980).
According to Wayne and James (1986), density determination is useful when one is more
interested in the number individuals rather than the cover or biomass, such as in evaluation of
trees or shrub stand. It can also provide an indication of the structure of a habitat and the amount
of wildlife food and cover (Sanford, 1980)
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CHAPTER THREE
3.0 MATERIALS AND METHODS
3.1 Materials
3.1.1 Study area description
Mole National Park (MNP) is Ghana’s largest protected area and covers about 4,590 km². It is
almost entirely located in the Northern Region and includes parts of West Gonja, Sawla – Tuna -
Kalaba, Wa East and West Mamprusi Districts. It lies between 9° 11’ and 10° 10’ N, and between
1° 22’ and 2° 13’ W, between Wa and Tamale (Fig 3.1).
Figure 3.1: Map of Mole National Park insert in black is the study area.
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Most of the 742 plant species found in MNP are widespread throughout the savannah zone. These
species of conservation value (4 endemic, 12 disjunct and 24 species which are rare or have a very
limited distribution) is relatively high. However their abundance is generally low and they are
often confined to small areas (Wildlife Department, 1994).
3.1.2 Climate
The average annual rainfall is about 1100 mm, decreasing to 1000 mm in the north of the park.
More than 90% of the rain falls in the rainy season from April to October, with peaks in July and
September. The dry season lasts from November to March. The mean annual temperature of
28°C varies from 26°C in December to 31°C in March. The average range from day to night is
13°C. It can be unpleasantly hot in March and April, with temperatures sometimes in the 40°C.
The Harmattan - the dry wind from the Sahara – may blow during December to February bringing
dusty, hazy weather. The relative humidity reaches 90% at night in the rains and falls to about
70% in the afternoons. In the dry season the figures are 50% and 20% respectively.
3.1.3 Vegetation
The vegetation of Mole National Park can be grouped into eight broad vegetation types. Their
distribution is mainly determined by soil depth and drainage (Schmitt and Adu-Nsiah, 1993).
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3.1.3.1 Open savannah woodland
This is the dominant vegetation type. The tree cover varies from 5% to 65%, with an average of
30%. The average tree height is 11 m with individuals reaching 22m. The ground cover, which
can reach up to 100%, is dominated by grasses up to 3m tall. The main grasses are species of
Andropogon and scattered herbs are found between them.
The savannah woodland is divided into three main groups: The Burkea - Terminalia savannah
woodland with Vitellaria paradoxa (the shea-nut tree) comprises all savannah woodland on well-
drained and often deep soils. The Burkea - Terminalia savannah woodland with Detarium
microcarpum is confined to shallow and rocky soils. The Anogeissus with Vitellaria paradoxa is
found on the granite outcrops.
3.1.3.2 Boval (open grassland)
The boval vegetation (Loudetiopsis kerstingii - Polycarpaea tenuifolia community) comprises all
plant communities on flat iron pans with patches of shallow soil. Only annual species can
compete on such sites which are flooded and species-rich during the rains and subject to extreme
water-stress during the dry season.
3.1.3.3 Riverine forest
This is found along most of the rivers in the park. It often forms bands of generally dense and
species-rich forests of up to 38m in height. The width of these bands varies from a few metres to
more than 100 m on either side of the river and is mainly determined by topography and geology.
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3.1.3.4 Flood plain grassland and swamps
This vegetation type comprises four plant communities of seasonally water-logged valley bottoms
and badly-drained depressions and areas around water-holes which are mainly dominated by
grasses and sedges.
3.1.3.5 Communities covering small areas
These are sites with special vegetation such as old termite mounds or depressions in the
sandstone plateau on top of the Konkori escarpment, which are water-filled during the rainy
season. There is also a scarp forest along the foot of the Konkori escarpment.
15
3.2 Methods
3.2.1 Data collection
3.2.1.1 Reconnaissance survey
A two-day reconnaissance survey was conducted in the study area. This was done to get
familiarise with the study area, talk to park staff and predict logistical problems and was assisted
by the head ranger of Mole National Park.
3.2.1.2 Sampling techniques
Quadrats and transects were used to sample the plants and animals respectively in the area. The
map of the area was gridded and 8 transects of 1000m was systematically laid in each grid to
sample the area (Fig. 3.2). Three quadrats of 10m x 10m was systematically laid on each transect
to sample animals and plants (William, 2000).
16
Figure 3.2: Map of study area showing transect origins and observations
3.2.1.3 Field survey
The coordinates of sampling points on the map were entered into the Global Positioning System
(GPS) device to locate the sampling points on the ground. From the gridded map a reference
transect was established to the north and all other transects according to this direction. All
quadrats were established to the right of each transect. In each quadrat selected plants were
identified and their numbers recorded. A line transect methodology (straight line) was used to
sample kob signs (Barn and Jensen, 1994).
17
3.2.2 Data analysis
3.2.2.1 Estimate of plant density
The density of plants was calculated using the formula,
, (Wayne and James, 1986)
3.2.2.2 Estimate of Kob sign density
The kob sign density was calculated using the formula,
, (Wayne and James, 1986)
3.2.2.3 Influence of Plant Species on Kob Density
The influence of plants species on kob density was analysed in two stages. Firstly, a correlation
matrix based on the value correlation coefficient (r) was performed to access the strength of a
general relationship or influence of each plant species on kob density. Secondly, a regression
analysis was performed on the plants that had significant influences on kob density to further
investigate the trend of these relationships. In all cases, the statistics package StatView 5.0.1 was
used. The goal was to build mathematical models that described the distribution of kob species.
Descriptive analysis was used to present the results in tables and graphs.
18
CHAPTER FOUR
4.0 RESULTS
4.1 Estimate of kob sign density
Kob signs in each cell ranged from 3 to 27 signs per km. The spatial patterns showed a
north- east to south-west gradient with most species occurring in the north-east direction and
south-west direction with fewer species occurring at the mid-portions around the Headquarters
and Dam areas ( Figure 3.2). Kob sign density was approximately 10 signs per kilometre.
4.2 Estimate of Plant Density
In all 44 plant species were encountered and identified in the quadrats laid on the transects
(Appendix 1: Plant Species List). The major plant species recorded were Burkea africana (1.1667
per ha), Crossopteryx febrifuga (1.25 per ha), Piliostigma thonningii (1.25 per ha), Afrormorsia
laxiflora (2.083 per ha), Daniellia oliveri (2.917 per ha), Annona senegalensis (3.75 per ha),
Nauclea latifolia (5.833 per ha), Daniellia macrocarpa (7.917 per ha) and Vitellaria paradoxa
(7.75 per ha).
19
Figure 4.1: Spatial pattern of kob signs in Mole National Park
4.3 Relationship between Plant Species density and Kob Sign Density
In the study 44 plants species were identified but only 9 had significant correlation with kob
density (Table 4.1). When the plants species were considered individually, Nauclea latifolia (r=
0.0996, P<0.01) was the best predictor of kob distribution pattern followed by Piliostigma
thonningii (r= 0.982 P<0.01), Afrormorsia laxiflora (r=0.971, P<0.01), Vitellaria paradoxa
(r=0.975, P>0.05) and Daniellia oliveri (r = 0.943, P<0.01) and had a positive influence on kob
distribution pattern.
20
However Daniellia macrocarpa(r=-0.982 P<0.01), Annona senegalensis(r=-0.873, P<0.01)
Crossopteryx febrifuga(r=-0861, P<0.01) and Burkea africana(r=-0825, P<0.01) all had an
inverse influence on Kob distribution pattern.
Table 4.1: Correlation coefficients (r) between kob signs per km and a suite of plants species recorded on transects
4.4 Regressional analysis
Each of the significant plant species were regressed against kob sign densities. Once again Kob
density was positively influenced by the Nauclea latifolia (r2=0.996, P<0.01; fig.4.1a),
Piliostigma thonningii (r2=0.982, P<0.01; fig 4.1b), Vitellaria paradoxa (r2=0.975, P>0.05;fig
4.2c), Afrormosia latiflora (r2=0.971, P<0.01; fig 4.2d) and Daniellia oliveri (r2=0.943, P<0.01;
fig 4.2 e).
Description of Plant species r P Nauclea latifolia, 0.996 < 0.01 Piliostigma thonningii 0.982 < 0.01 Vitellaria paradoxa 0.975 > 0.05 Afrormosia laxiflora 0.971 < 0.01 Daniellia oliveri 0.943 < 0.01 Daniellia macrocarpa - 0.982 < 0.01 Annona senegalensis - 0.873 < 0.01 Crossopteryx febrifuga - 0.861 < 0.01 Burkea africana - 0.825 < 0.01
21
(a) (b)
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-2 0 2 4 6 8 10 12 14 16No. of Nauclea latifolia per ha
Y = 3.209 + 2.027 * X - .023 * X^2; R^2 = .994
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-1 0 1 2 3 4 5 6 7 8No. of Piliostigma thonningii per ha
Y = 4.63 + 1.373 * X + .261 * X^2; R^2 = .989
(c) (d)
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
0 10 20 30 40 50 60 70 80 90No. of Vitellaria paradoxa per ha
Y = 3.701 + .156 * X + .002 * X^2; R^2 = .962
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5N
o. o
f Ko
b si
gns
per k
m
-.5 0 .5 1 1.5 2 2.5 3 3.5No. of Afrormosia laxifolia per ha
Y = 4.89 + 2.648 * X + 1.623 * X^2; R^2 = .98
(e)
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-.5 0 .5 1 1.5 2 2.5 3 3.5 4 4.5No. of Daniellia oliveri per ha
Y = 4.63 - .022 * X + 1.413 * X^2; R^2 = .975
Figure 4.2: Relationships between kob signs per km and a number of suite of plants species per ha.
22
Generally the regression models showed increasing kob abundance with an increasing plant
density per hectare.
Similarly kob density was inversely influenced by Daniellia macrocarpa (r2= 0.982, P<0.01;
Figure 4.3a), Annona senegalensis (r2= 0.873, P<0.01; Figure 4.3b), Crossopteryx febrifuga (r2=
0.861, P<0.01; Figure 4.3c), and Burkea africana (r2= 0.825, P<0.01; Figure 4.3d).
(a) (b)
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-1 0 1 2 3 4 5 6 7 8No. of Daniellia macrocarpa per ha
Y = 27.502 - 4.277 * X + .137 * X^2; R^2 = .972
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-.5 0 .5 1 1.5 2 2.5 3 3.5No. of Annona senegalensis per ha
Y = 26.889 - 16.111 * X + 2.889 * X^2; R^2 = .893
(c) (d)
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-.5 0 .5 1 1.5 2 2.5 3 3.5No. of Crossopteryx febrifuga per ha
Y = 21.962 - 13.276 * X + 2.545 * X^2; R^2 = .852
2.5
5
7.5
10
12.5
15
17.5
20
22.5
25
27.5
No.
of
Kob
sign
s pe
r km
-1 0 1 2 3 4 5 6 7 8 9 10No. of Burkea africana per ha
Y = 25.37 - 6.501 * X + .452 * X^2; R^2 = .938
Figure 4.3: An inverse relationships between kob signs per km and a suite of plant species per ha.
23
The regression models showed that highest kob abundance occurred at lowest plant densities per
hectare. These models allow us to calculate the number of kob signs expected given the number
of available plant species.
24
CHAPTER FIVE
5.0 DISCUSSION
5.1 Kob Densities
Human population growth and land transformations also influence ungulate population
dynamics through the destruction and loss of their natural habitats and accelerated
exploitation. Hunting pressures was suspected to be much reduced in the headquarters area
compared to the other areas; however kob densities were generally high at the north- east to
south-west sections of the study area with fewer species occurring in the mid-portions around the
Headquarters and Dam areas. Particularly most kob activity was recorded some distance from the
tourist visitor centre towards the periphery of these study area indicating a possibility of
disturbance by tourists and possibly from other human activities.
Nevertheless, the generally high record of kob signs in the study area corresponds well to
established increased activity levels. Kob may be adapted to the habitat conditions in MNP,
thereby persisting or increasing and do not appear to have suffered to the same extent as other
species groups like primates or larger carnivores due to human activities. Most kob populations
have also been assessed as stable or increasing in Ghanaian savannahs (IUCN/SSC, 1998). In
addition, most antelopes, especially kob, can probably withstand hunting pressure to a greater
degree than the more susceptible primate species. However, hunting activities might have reduced
the large ungulate populations in comparison to past levels of abundance.
25
5.2 Plant density
5.2.1 Summary of Major Plant Species Forty – four plants species were recorded in the study area during the survey. The major species
include: Nauclea latifolia, Piliostigma thonningii, Afrormorsia laxiflora, Vitellaria paradoxa
Daniellia oliveri, Daniellia macrocarpa, Annona senegalensis, Crossopteryx febrifuga and
Burkea africana.
5.2.1.1 Nauclea latifolia
Nauclea latifolia is an evergreen multi-stemmed shrub or a tree from the family: Rubiaceae, it
grows up to an altitude of 200m. It is widespread in the humid tropical rainforest zone or in
savannah woodlands of West and Central Africa. It has an open canopy and terminal spherical
head lined cymes of white flowers. The flowers are joined with their calyces with a syncarp fruit.
The tree is flowering from April to June. The fruits are ripening from July to September. Baboons
and other livestock feed on them and they serve as medicinal to rural folks (Vogt, 1995). The
plant is widely distributed in the study area.
5.2.1.2 Piliostigma thonningii
Piliostigma thonningii (camel’s foot) is a tree 4-15 m in height and belongs to the family
caesalpinioideae with a rounded crown and a short but often crooked bole with rusty-hairy twigs.
The bark is rough and longitudinally fissured, being creamy-brown when fresh and grey-brown
later. Leathery green leaves up to 15 x 17 cm, bi-lobed one eighth to one third the way down with
a small bristle in the notch, glossy above and heavily veined and somewhat rusty-hairy below.
26
Flowers with 5 white to pink petals, pendulous, unisexual with male and female usually on
separate trees; ovary topped by a thick flattened-globose stigma. The leaves are edible and
chewed to relieve thirst. The fruit and seeds are edible. The pods are nutritious and relished by
cattle and antelopes. This is a preferred browse species of the African elephant (Loxodonta
africana), the fruits are also taken in considerable quantities (Bombardelli et al., 1994). In terms
of distribution it is sparsely distributed in the study area. It is mostly found at the MNP tourist
centre and at the main entrance of MNP.
5.2.1.3 Burkea africana
Burkea africana is a deciduous, medium-sized, spreading, flat-topped tree. Leaves are bipinnately
compound, silvery-pubescent or glabrescent. Flowers are creamy-white, fragrant and in pendulous
racemes of up to 300 mm in length. It is widely distributed in tropical Africa but sparsely
distributed in the study site. It is mostly found near water bodies in MNP. The leaves are the only
food resource of two kinds of edible caterpillars which are harvested in thousands during the rainy
season, mainly January and February. The bark is used as dye for Combretum zeyheri roots which
are woven into baskets. The roots are used to treat stomach pain and tooth ache (Palmer et al.,
1972).
5.2.1.4 Crossopteryx febrifuga
Crossopteryx febrifuga is a deciduous savannah tree 1.8-15 m tall, with a rounded crown and
pendulous branchlets. It has bark pale grey to dark brown, scaly, finely reticulate; young stems
glabrous to densely hairy pubescent (Palmer et al., 1972). It is sparsely distributed at the study
27
area. Bushbuck browses the leaves and shoots. The wood is hard, fine textured, with a pale pink
tinge and used for building domestic implements e.g. utensils, tool handles and also used as fuel.
5.2.1.5 Annona senegalensis
Annona senegalensis is a shrub or small tree 2-6 m tall but may reach 11 m under favourable
conditions; bark smooth to roughish, silvery grey or grey-brown, with leaf scars and roughly
circular flakes exposing paler patches of under bark. Wild fruit trees of this species are found in
semi-arid to sub-humid all over regions Africa. The species occurs along riverbanks, fallow land,
swamp forests and at the coast. Commonly grows as a single plant in the understorey of savannah
woodlands. The plant species are sparsely distributed in the study area around the headquarters.
The leaves are sometimes used as vegetables, while the edible white pulp of the ripe fruit has a
pleasant, pineapple-like taste. Flowers serve as a spice for various meals whiles livestock browse
the leaves. Fibre from young sucker shoots is used in binding. The wood is soft and white or light
brown in colour; it is used for poles and tool handles (Palmer et al., 1972).
5.2.1.6 Afrormosia latiflora
Afrormosia latifolia is small to medium-sized tree 2–12 m tall bole rarely straight reaching to 25
cm diameter, bearing crooked, drooping branches forming a dishevelled crown. It is among one of
the commonest trees found in savannah woodland and fringing forest, and also in dry dense forest
(Palmer et al., 1972). However it is sparsely distributed in the study area and located around the
dam areas.
28
5.2.1.7 Vitellaria paradoxa
Vitellaria paradoxa is a small to medium-sized tree about 10-15 high; much branched, dense,
spreading, round to hemispherical crown. In mature trees the bole is short, usually 3-4 m but
exceptionally 8m, with a diameter ranging from 0.3 to 1 m, but most frequently 0.6 m. Bark
conspicuously thick, corky, horizontally and longitudinally deeply fissured; protects older trees
against bush fires. Slash pale pink, secreting white latex, as do broken twigs or petioles. The
sugary pulp of the fruit makes it attractive to a wide range of animals. A large variety of birds,
ungulates and primates, including humans, eat them, dispersing the seed in the process (Palmer et
al., 1972). It is the most densely populated plant in the study area and almost found everywhere.
5.3 Relationship between Plant Species density and Kob Sign Density
When the plants species were considered individually, Nauclea latifolia, Piliostigma thonningii,
afrormorsia laxiflora, Vitellaria paradoxa and Daniellia oliveri and had a positive influence on
kob distribution pattern. However Daniellia macrocarpa, Annona senegalensis, Crossopteryx
febrifuga, and Burkea africana, all had an inverse influence on kob distribution pattern.
Generally the regression models showed two patterns, for some plant species highest kob
abundance occurred at lowest plant densities indicating a negative relationship whilst for other
plant species highest kob abundance occurred at highest plant densities indicating a positive
relationship. These results should however be viewed with caution because a lot more other
factors could be working together with these plants densities to influence kob distribution. These
factors include various ecological and climatic variables such as humidity, temperature, rainfall,
29
water availability, shade. and also human variables such as hunting activity and tourist
disturbance (Siemann et al., 1998; Knops et al., 1999; Haddad et al., 2001). Temperature, soil
type and climate conditions affect plant growth and this could be contributing to influence kob
density in the study area (Wright et al., 1993; Hawkins et al., 2003). Dry and wet soil types are
also pre-requisite for some plant species to grow well. The level of protection is also a major
factor in animal distribution patterns. The affinity for some plants by kob could be due to
closeness of such plants to water sources.
During the study for instance (Annona senegalensis, Afrormosia latifolia and Burkea africana)
were found mainly in flood plains hence the abundance of kob numbers may be due to kob
affinity for water (Knops et al., 1999). The affinity for water by large mammals in Bia
Conservation Area has also been shown by PADP (2009). Also such places around water sources
are cooler and are likely to shield kob from hot temperatures from the heat of the sun especially in
the afternoons where most species search for shade to rest under. These plant species may also
provide a positive effect through their canopies which could serve as a hideout from most
predators and poachers.
It is also likely that these flood plains are inaccessible to poachers during most times of the year
because of the nature of the terrain hence poaching activity may be lower compared to other
areas, providing a safe haven for most animals. The floodplain areas which contain mineral salts
(saltlicks) are of major importance to animals hence kob may be especially attracted to these
areas. Rainfall drives population dynamics of African savannah ungulates through its
controlling influence on vegetation growth, food sufficiency and availability of surface
water.
30
Consequently, fluctuations in rainfall underpin ungulate population dynamics (Mills,
Biggs & Whyte, 1995; Owen-Smith & Mills, 2006). The plants that had inverse influence on
kob density possibly possessed variables that deter kob. Hence visibility for poachers and
predator and scarcity of water will be higher to discourage the congregation of kob in these areas.
Many African ungulates live in groups which gives them potential advantage over predators
because of dilution effects and early detection of attackers. Antelopes, however, are not only
hunted by natural predators but increasingly by humans, resulting not only in significant reduction
of population densities but sometimes in obliteration of entire populations and even species
(Bertram, 1978). The species that suffered most were the duikers and other small antelopes up to
the size of the kob antelope (Kobus kob kob). The observed decreases can most likely be
attributed to intensive poaching that occurs in localised areas throughout the park.
31
CHAPTER SIX
6.0 CONCLUSIONS AND RECOMMENDATIONS
Conclusions
Most kob activity was recorded some distance from the tourist visitor centre towards the periphery
of these study area indicating a possibility of disturbance by tourists and possibly from other
human activities. An overall density of 10 signs per km of kob was estimated.
In all 44 plant species were encountered and identified in the quadrats laid on transects. The major
plant species recorded were Burkea africana (1.1667 per ha), Crossopteryx febrifuga (1.25 per
ha), Piliostigma thonningii (1.25 per ha), Afrormorsia laxiflora (2.083 per ha), Daniellia oliveri
(2.917 per ha), Annona senegalensis (3.75 per ha), Nauclea latifolia (5.833 per ha), Daniellia
macrocarpa (7.917 per ha) and Vitellaria paradoxa (7.75 per ha). The plants belong to the
families Leguminosae, Rubiaceae, Caesalpiniacea, Fabaceae, Annonaceae and Sapotaceae respectively.
Generally the regression models showed two patterns, for some plant species highest kob
abundance occurred at lowest plant densities indicating a negative relationship whereas for other
plant species highest kob abundance occurred at highest plant densities indicating a positive
relationship.
32
Recommendation
Kob activity was not much at the headquarters area and could be attributed to tourist disturbance
and human activities. Various plant species were found in MNP and it is recommended that
further studies should be conducted to explain the negative relationship with kob density and also
those with positive relationship kob should be planted in areas that had plant species with
negative influence to boost kob abundance.
It was beyond the scope of this study to understand why certain plant species show negative
influence on kob density. Such a study is critical to inform management plans of MNP to be
focused on the protection of plant resources for kob.
33
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.
Appendices
Appendix 1: Type and Density of Plant Species
Plant Species Trans1 Trans 2 Trans 3 Trans 4 Trans 5 Trans 6 Trans 7 Trans 8 Total Density/ha Gardenia tomatosa 10 9 3 1 1 0 0 1 25 1.417 Burkea africana 3 4 4 2 1 0 9 5 28 1.1667 Vitellaria paradoxa 28 19 11 83 2 0 25 18 186 7.75 Terminalia avicennoides 33 6 70 53 15 0 23 22 222 9.25 Hanila acida 1 0 2 2 0 0 0 1 6 2.5 Piliostigma thonningii 2 0 0 7 2 0 0 3 14 5.833 Gardenia aquala 1 0 0 0 1 0 0 2 4 1.667 Combrentum senegalensis 14 2 9 5 23 18 2 10 83 3.4583 Maytenus senegalensis 8 0 0 0 0 0 3 1 12 5.0 Piliostigma polyendra 4 17 7 2 0 0 0 0 30 1.25 Combrentum mole 2 0 0 0 0 0 0 12 14 5.833 Crossopteryx febrifuga 1 0 0 0 0 0 1 1 3 1.25 Bridelia ferogina 1 0 0 1 0 0 0 1 3 1.25 Parinari crotifolia 2 5 1 1 0 0 0 0 9 3.75 Tericarpus erinacius 1 0 0 0 0 0 0 0 1 4.17 Lania acida 1 0 0 0 0 0 0 0 1 4.17 Annona senegalensis 1 4 1 0 0 0 1 2 9 3.75 Sicuridata longicudata 0 4 0 0 0 0 0 0 4 1.667 C. spps 0 8 0 0 0 0 5 2 15 6.25 Aflagyl peninculata 0 4 1 0 0 0 0 1 6 2.5 Daniellia olivera 0 1 0 2 3 0 0 1 7 2.917 Azilia africana 0 12 0 0 0 0 0 0 12 5 Grunia mole 0 8 1 0 0 0 0 0 9 3.75 Daniellia macrocarpa 0 6 3 0 0 0 3 7 19 7.917 Hanila ungulata 0 2 0 0 0 0 0 0 2 8.33
39
Plant Species Trans1 Trans 2 Trans 3 Trans 4 Trans 5 Trans 6 Trans 7 Trans 8 Total Density/ha Tericarpus erinacius 0 3 0 0 0 0 0 0 3 1.25 Afrormosia laxiflora 0 1 1 2 0 0 0 1 5 2.083 Xymenia americana 0 0 2 0 1 0 0 0 3 1.25 Trigilia roca 0 2 6 2 0 0 0 0 10 4.167 Tiliopsis subanopsa 0 0 2 0 0 0 0 0 2 8.33 Cocosp. Continum 0 0 1 0 0 0 0 0 1 4.17 Sodioli kochai 0 0 4 0 0 0 0 0 4 1.667 Nauclea latifolia 0 0 0 14 0 0 0 0 14 5.833 Maligyina inermis 0 0 0 0 1 0 0 0 1 4.17 Terminalia microcarpa 0 0 0 0 1 0 0 0 1 4.17 Cidio ceduella 0 0 0 0 3 0 0 0 3 1.25 Anogeissius leocarpus 0 0 0 0 4 24 0 0 28 1.1667 Acasia spp. 0 0 0 0 0 2 0 0 2 8.33 Diasparos spp. 0 0 0 0 0 1 0 0 1 4.17 Metrogina inermis 0 0 0 0 0 18 0 0 18 7.5 Electrofolium acida 0 0 0 0 0 0 3 0 3 1.25 Asobelinilia doka 0 0 0 0 0 0 0 2 2 8.33 Garmenia amerio 0 0 0 0 0 0 0 1 1 4.17 Total 113 117 129 177 58 63 75 95 827