greg challis department of chemistry lecture 2: methods for experimental identification of cryptic...

Greg Challis

Department of Chemistry

Lecture 2: Methods for experimental identification of cryptic biosynthetic gene cluster products

Microbial Genomics and Secondary Metabolites Summer School, MedILS, Split, Croatia, 25-29 June 2007

Overview

• Overview of available approaches

• Identification of a S. coelicolor cryptic NRPS product

prediction of properties, gene KO / metabolic profiling

• Identification of S. coelicolor cryptic type III PKS products

gene KO / metabolic profiling

• Identification of a S. coelicolor cryptic terpene synthase product

in vitro reconstiution

Overview of approaches

Corre and Challis, Chem. Biol. (2007) 14, 7-9

Gene knockout / comparative metabolic profiling

X wild type

mutant

H2NNH

O

N

O

OH

NH

ONH2

NOH

O

NHO

O

O OH

H H

OH

O

O

HO

Lautru, Deeth, Bailey and Challis, Nat. Chem. Biol. (2005) 1, 265-269

Song et al., J. Am. Chem. Soc. (2006), 128, 14754

Expression of pathway specific activator / comparative metabolic profiling

host + activator

host - activator

O

NH

OH

O

OH

R

aspyridones

Bergman et al., Nat. Chem. Biol. (2007) 3, 213-217

Heterologous gene expression / comparative metabolic profiling

host

host + genes

host - genes

NH

OO

O Cl

OMe

OOHOH

O

MeO

Hornung et al., ChemBioChem (2007) 8, 757-766

Prediction of physicochemical properties

predicted precursors h

NH

OO

OH

O OH

HO OH

OH

CO2HMeNH2N

NH

Banskota et al., J. Antibiot., (2006) 59, 533-542

“Genomisotopic” approach

labelled predicted precursor

** * *

NH

HNNH

O

NH

NH

HN

NH

NH

O

O

OO

OO

O

O

OH

HO

O OH

orfamides

Gross et al. Chem. Biol. (2007) 14, 53-63

In vitro pathway reconstitution

predicted precursors

purifiedenzymes

epi-isozizaene

Lin, Hopson and Cane, J. Am. Chem. Soc. (2006) 128, 6022-6023

H. Vlamakis, P. Straight, M. Fischbach

Addition of a soil metabolite to Streptomyces avermitilis induces it to produce a cryptic metabolite

Ueda et al., J. Antibiotics, 2000

Diffusible compound from a soil organism induces another organism to generate a new antibiotic activity

Supernatant of soil organism A

(stimulating compound)

Soil organism B(antibiotic producer)

• Paper discs containing extracts from the culture broth of organism A were placed adjacent to inoculated spots of organism B

•

• Organism B grew for 1 – 3 days

• Soft agar containing spores of Bacillus subtilis was overlain to indicate antibiotic production

Example 1: isolation of a novel cryptic NRPS product

A new S. coelicolor NRPS gene cluster

cchAcchBcchH

Flavin-dependent monooxygenase (cchB)

Non-ribosomal peptide synthetase (cchH)

Formyl-tetrahydrofolate-dependent formyl transferase (cchA)

MbtH-like protein (cchK)

Esterase (cchJ)

Challis and Ravel FEMS Microbiol. Lett. (2000) 187, 111-114

Export functions

Ferric-siderophore import

cchJcchI

Prediction of substrates and possible products for the S. coelicolor cryptic NRPS

O

NHNH2

OH

HN

OH

O

H

O

NOH

O

NH2

OH O

NHNH2

OH

HN

OH

O

H

O

HN

N

O

OHH

Challis and Ravel FEMS Microbiol. Lett. (2000) 187, 111-114

A E C A E C A

SO

HN

H2NO

N

H2N

OHO

H

S

Module 1 Module 2 Module 3

O

NH2HOH

S

OH

Gene KO / comparative metabolic profiling targeting predicted properties

cchH

X

-20

180

380

580

0 5 10 15 20 25 30 35 40

Retention time / min

Mutant

Wild type

-20

180

380

580

A4

35

/ n

m

408

+2 H

408+2H

307+2H

H2NNH

OOH

N

O

OH

NH

ONH2

NOH

O

NHO

O

O OH

H H

m/z

Mass spectrometric analysis of coelichelin

ESI-FTICR-MS

ESI-MS-MS

C21H39N7O11

NMR analysis of Ga-coelichelin complexAssignment H C

hfOrn1-C1 - 168.5 hfOrn1-C2 3.97, dd, 3.0 Hz, 3.0 Hz hfOrn1-C3 1.91, m; 1.50, m hfOrn1-C4 1.42, m; 1.50, m hfOrn1-C5 3.41, m; 3.51, m hfOrn1-NH2 - - hfOrn1-C(O)H 8.17, s 153.5 Thr2-C1 - 162.5 Thr2-C2 4.59, dd, 9.0 Hz, 9.0 Hz 58.0 Thr2-C3 3.82, m 66.0 Thr2-C4 1.14, d, 5.5 Hz 21.0 Thr2-NH 8.75, d, 9.0 Hz - Thr2-OH 5.08, d, 6.2 Hz - hOrn3-C1 - 173 hOrn3-C2 4.24, dd, 8.5 Hz, 11.0 Hz hOrn3-C3 1.76, m; ? hOrn3-C4 1.83, m; 1.83, m hOrn3-C5 3.45, m; 3.93, m hOrn3-NH 7.57, d, 8.5 Hz - hfOrn4-C1 - 170 hfOrn4-C2 4.15, dd, 11.0 Hz, 1.9 Hz hfOrn4-C3 1.64, m; 2.29, m hfOrn4-C4 1.96, m, 1.76, m hfOrn4-C5 3.76, m; ? hfOrn4-C(O)H 8.22, s 153.5 hfOrn4-NH2 - -

H2NNH

OOH

N

O

O

N

ONH2

NO

O

NO

O

Ga

O OH

H

H H

12

3

4

5

12

34

1

2345

12

3

4

5

hfOrn1Thr2

hOrn3

hfOrn4

2D-NMR analysis of Ga-coelichelin complex

H2NN

OOH

N

O

O

N

ONH2

NO

O

NO

O

Ga

O OH

H

H

HH

HH

H H

1

2

34

5

6

7

1

2

3

4

5

6 7

1

2 3

5

6

4

H2NN

O

N

O

O

N

ONH2

NO

O

NO

O

Ga

O OH

H

H

HH

HH

H H

H

HOH

H1

2

3

H

4

5

6

HMBC

ROESY

Molecular modelling of Ga-coelichelin

2.45

2.52

2.06d

H2NN

O

N

O

O

N

ONH2

NO

O

NO

O

Ga

O OH

H

H

HH

H

H H

HO H

2.58

1.83

2.46

Structure of coelichelin

H2NNH

O

N

O

OH

NH

ONH2

NOH

O

NHO

O

O OH

H H

OH

H2NNH

OOH

N

O

OH

NH2

NOH

O

O OH

H

proposedstructure

Assembly of a tetrapeptide by a trimodular NRPS

cchH

CchJH2N

NH

OOH

N

O

OH

NH

ONH2

NOH

O

NHO

O

O OH

H

H H

A E C A E C A

SH SO

N

HN

HOO

NHHOO

N

NH2

HO O

H

H

ON

H2N

HO

HO

SH

Module 1 Module 2 Module 3

cchJ

Heterologous expression of the cch cluster in Streptomyces fungicidicus

-50

350

750

1150

1550

-50

350

750

1150

1550

S. fungicidicus

S. fungicidicus + cch cluster

-50

350

750

1150

1550

S .coelicolor M145

Lautru, Deeth, Bailey and Challis, Nat. Chem. Biol. (2005) 1, 265-269

Example 2: isolation of novelproducts of a cryptic iterative PKS

Archetypal type III PKS products from bacteria

HO OH

O

SCoA

OH

OAmycolatopsis

orientalis

DpgA4 x Me

O O

O

NH

O HN

O

NH

O

NHMe

Cl

O

HN

H

OH

NH

OCl

OH

NHO

OHHO

H

HO2C

HOH

O

HOHO

O

OH

OH2N

HO Me

NH2

O

HO OH

O

OHH2N

Mechanism of 3,5-DHPA-CoA assembly by DpgA

-O

O

SCoA

O

DpgA

-S

-O

O

SCoA

O

DpgA

S

O

-O

O

O

SCoA

O

DpgA

-S

-O

O

O

SCoA

OOOO

-O

O

SCoAHO

O O

O

SCoA

HO OH

3,5-DHPA-CoA

Tseng, McLoughlin, Kelleher and Walsh Biochemistry (2004) 43, 970-980

Type III polyketide synthases

In vitro investigation of the products formed by Sco7221 from acyl thioesters + malonyl CoA

R SCoA

O

SCoA

O

HO

O+

purifiedrecombinant

Sco7221O

O

HO R'

Moore, Noel and coworkers, unpublished

Identification of a new S. coelicolor type III PKS products by genome mining

sco7221

0 5 10 15 20 25 Time [min]0.0

0.5

1.0

1.5

2.0

6x10Intens.

7221_EtOAc_72_01_511.d: EIC 197 +All MS, Smoothed (0.3,1, GA)7221_EtOAc_72_01_511.d: EIC 183 +All MS, Smoothed (0.3,1, GA)WTM145_7_01_1360.d: EIC 183 ±All MS, Smoothed (1.1,1, GA)WTM145_7_01_1360.d: EIC 197 ±All MS, Smoothed (1.1,1, GA)

EIC 197 sco7221

EIC 183 sco7221

EIC 197 M145

EIC 183 M145

X

Structures of the products

O

O

HO

O

O

HO

Germicidin A(MW = 196)

Germicidin B(MW = 182)

O

O

HO

Isogermicidin B*(MW = 182)

O

O

HO

Isogermicidin A*(MW = 196)

O

O

HO

Germicidin C(MW = 182)

Song, Barona-Gomez, Corre, Xiang, Udwary, Austin, Noel, Moore and Challis, J. Am. Chem. Soc. (2006), 128, 14754Petersen, Zahner, Metzger, Freund and Hummel, J. Antibiot. (1993) 46, 1126-1138

O

O

HO

Isogermicidin C*(MW = 182)

Biosynthetic origins of germicidin A in S. coelicolor

OO

OH

NH2 O

OH

O

OH D

DD

DD/H

D

D D

D D

D D

[U-13C]Isoleucine [2H7]butyrate

0 5 10 15 Time [min]0.0

0.5

1.0

1.5

2.0

2.58x10

Intens.

D7GerBcollection_2_01_2303.d: EIC 197 +All MS, Smoothed (0.4,1, GA)D7GerBcollection_2_01_2303.d: EIC 202 +All MS, Smoothed (0.4,1, GA), Smoothed (0.4,1, GA), Smoothed (0.4,1, GA)

0 5 10 15 Time [min]0

2

4

6

87x10

Intens.

C13Gercollection_10_01_2311.d: EIC 197 +All MS, Smoothed (0.4,2, GA)C13Gercollection_10_01_2311.d: EIC 202 +All MS, Smoothed (0.4,2, GA)

196.93

201.95

213.91 223.92

+MS, 21.00-21.07min #(3004-3014)

0

2

4

6

8

7x10Intens.

180 190 200 210 220 m/z

196.93

201.94

218.91

223.93

+MS, 20.13-20.24min #(2884-2899)

0

1

2

3

7x10Intens.

180 190 200 210 220 m/z

EIC 202EIC 197

Proposed mechanism 1 for germicidin assembly

SCoA

O

GcsA

HS

-O

O

SCoA

O

GcsA

S

O

R2

SCoA

O

GcsA

HS

R2

R1R2

R1

R1

O

-O

O

SCoA

O

GcsA

S

OO

R2

R1

R4

R2

R1

O O O

R4

SCoA

O

O

R4

R1R2 OH

R3 R3

R3

R3 R3 R3

-CO2-CoASH -CoASH

-CO2 -CoASH

Proposed mechanism 2 for germicidin assembly

SCoA

O

FabH

HS

-O

O

S

O

FabH

S

O

R2

S

O

GcsA

HS

R2

R1R2

R1

R1

O

-O

O

SCoA

O

GcsA

S

OO

R2

R1

R4

R2

R1

O O O

R4

SCoA

O

O

R4

R1R2 OH

R3 R3

R3

R3 R3 R3

FabC FabC

-CO2

-CO2

-CoASH

-CoASH

-FabC-SH

Heterologous expression of sco7221 in Streptomyces venezualae ISP5230

0 2 4 6 8 10 12 14 16 Time [min]0

1

2

3

4

7x10Intens.

newSV5d_2_01_3370.d: EIC 183 +All MS, Smoothed (0.4,1, GA)newSV5d_2_01_3370.d: EIC 197 +All MS, Smoothed (0.4,1, GA)Svenezualaenew_2_01_2361.d: EIC 183 +All MS, Smoothed (0.4,1, GA), Smoothed (0.4,1, GA), Smoothed (0.4,1, GA)Svenezualaenew_2_01_2361.d: EIC 197 +All MS, Smoothed (0.4,1, GA), Smoothed (0.4,1, GA), Smoothed (0.4,1, GA)

EIC 197 ISP5230 + sco7221

EIC 183 ISP5230 + sco7221

EIC 197 ISP5230

EIC 183 ISP5230

gcs (sco7221)

PermE*

Fatty acid biosynthesis in Streptomyces coelicolor and E. coli compared

SCoA

O

-O

O

S

O

S

O

R2

R1R2

R1

OR3 R3

ACP ACP+

R1R2

R3

OH

O

Sc-FabH

R1 = R2 = Me, R3 = H

R1 = H, R2= R3 =H

R1 = Me, R2 = R3 = H

R1 = R3 = H, R2 = Me

SCoA

O

-O

O

S

O

S

OO

ACP ACP+Ec-FabH

O

OH

Analysis of germicidin production in S. coelicolor YL/ecFabH

EIC 197 YL/ecFabH

EIC 183 YL/ecFabH

EIC 197 M511

EIC 183 M511

0.0 2.5 5.0 7.5 10.0 12.5 15.0 17.5 20.0 Time [min]0

2

4

6

7x10Intens.

PSE2SMMmedium_3_01_3234.d: EIC 183 +All MS, Smoothed (0.4,1, GA)PSE2SMMmedium_3_01_3234.d: EIC 197 +All MS, Smoothed (0.4,1, GA)M145SMMmedium_4_01_3235.d: EIC 183 +All MS, Smoothed (0.4,1, GA)M145SMMmedium_4_01_3235.d: EIC 197 +All MS, Smoothed (0.4,1, GA)

O

O

HO

O

O

HO

fabD aac(3)IV fabC fabBoriT ecfabH+

OH

O

OH

O

OH

O

PermE*

Proposed mechanism for germicidin assembly

SCoA

O

FabH

HS

-O

O

S

O

FabH

S

O

R2

S

O

GcsA

HS

R2

R1R2

R1

R1

O

-O

O

SCoA

O

GcsA

S

OO

R2

R1

R4

R2

R1

O O O

R4

SCoA

O

O

R4

R1R2 OH

R3 R3

R3

R3 R3 R3

FabC FabC

-CO2

-CO2

-CoASH

-CoASH

-FabC-SH

X-ray structure of germicidin synthase

Ser

Cys

Gcs

AcpP

Example 3: a novel product of a cryptic sesquiterpene synthase

Cryptic sesquiterpene synthases of S. coelicolor

In vitro investigation of the product formed by Sco5222 from farensyl pyrophosphate

Lin, Hopson and Cane, J. Am. Chem. Soc. (2006) 128, 6022-6023

O

P

O

O O-

P

O-O O-

Sco5222

-PPi

epi-isozizaene

sco5222 overexpressed in E. coli with N-terminal His6 and purified from CFE

sco5222 sco5223

Sesquiterpene synthase Cytochrome P-450

Sco5223?

O

albaflavenone

Streptomyces albidoflavus

O2-H2O

Conclusions

• Several different approaches for the identification of the products of cryptic biosynthetic gene clusters have been developed in recent years

• Several novel bioactive metabolites have been discovered from well-studied microbes by these approaches

• Activation of silent cryptic gene clusters is a challenge that awaits generic solutions

• Genome mining is a promising approach for new bioactive metabolite discovery