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Polyketide synthase

December 15, 2023

Polyketide synthases (PKSs) are a family of multi-domain enzymes or enzyme complexes that produce polyketides, a large class of secondary metabolites, in bacteria, fungi, plants, and a few animal lineages. The biosyntheses of polyketides share striking similarities with fatty acid biosynthesis.[1][2]

The PKS genes for a certain polyketide are usually organized in one operon or in gene clusters. Type I and type II PKSs form either large modular protein complexes or dissociable molecular assemblies; type III PKSs exist as smaller homodimeric proteins.[3][4]

Classification edit

 
Reaction mechanisms of type I, II and III PKSs. Decarboxylation of malonyl unit followed by thio-Claisen condensation. a) (cis-AT) type I PKS with acyl carrier protein (ACP), keto synthase (KS) and acyl transferase (AT) domains covalently bound to another . b) Type II PKS with KSα-KSβ heterodimer and ACP as separate proteins. c) ACP-independent Type III PKS.

PKSs can be classified into three types:

  • Type I PKSs are large, complex protein structures with multiple modules which in turn consist of several domains that are usually covalently connected to each other and fulfill different catalytic steps. The minimal composition of a type I PKS module consists of an acyltransferase (AT) domain, which is responsible for choosing the building block to be used, a keto synthase (KS) domain, which catalyzes the C-C bond formation and an acyl carrier protein (ACP) domain, also known as thiolation domain. The latter contains a conserved Ser residue, post-translationally modified with a phosphopantetheine at the end of which the polyketide chain is covalently bound during biosynthesis as a thioester. Moreover, multiple other optional domains can also exist within a module like ketoreductase or dehydratase domains which alter the default 1,3-dicarbonyl functionality of the installed ketide by sequential reduction to an alcohol and double bond, respectively.[5][6] These domains work together like an assembly line. This type of type I PKSs is also referred to as cis-acyltransferase polyketide synthases (cis-AT PKSs). In contrast to that, so called trans-AT PKSs evolved independently and lack AT domains in their modules. This activity is provided by free-standing AT domains instead. Moreover, they often contain uncommon domains with unique catalytic activities.[7]
  • Type II PKSs behave very similarly to type I PKS but with one key difference: Instead of one large megaenzyme, type II PKSs are separate, monofunctional enzymes. The smallest possible type II PKS consists of an ACP, as well as two heterodimeric KS units (KSα, which catalyzes the C-C bond formation and KSβ, also known as 'chain length factor' — CLF, since it can determine the carbon chain length[8]), which fulfill a similar function as the AT, KS and ACP domains in type I PKSs, even though type II PKSs are lacking a separate AT domain. Additionally, type II PKSs often work iteratively where multiple chain elongation steps are carried out by the same enzyme, similar to type III PKSs.[9][10]
  • Type III PKSs are small homodimers of 40 kDa proteins that combine all the activities from the essential type I and II PKS domains. However, in contrast to type I and II PKSs they do not require an ACP-bound substrate. Instead, they can use a free acyl-CoA substrate for chain elongation.[11][12][13] Moreover, type III PKSs contain a Cys-His-Asn catalytic triad in their active center, with the cysteine residue acting as the attacking nucleophile, whereas type I and II PKSs are characterized by a Cys-His-His catalytic triad.[14] Typical products of type III PKSs include phenolic lipids like alkylresorcinols
  • In addition to these three types of PKSs, they can be further classified as iterative or noniterative. Iterative Type I PKSs reuse domains in a cyclic fashion. Other classifications include the degree of reduction performed during the synthesis of the growing polyketide chain.
    • NR-PKSs — non-reducing PKSs, the products of which are true polyketides
    • PR-PKSs — partially reducing PKSs
    • FR-PKSs — fully reducing PKSs, the products of which are fatty acid derivatives

Modules and domains edit

 
Biosynthesis of the doxorubicin precursor, є-rhodomycinone. The polyketide synthase reactions are shown on top.

Each type I polyketide-synthase module consists of several domains with defined functions, separated by short spacer regions. The order of modules and domains of a complete polyketide-synthase is as follows (in the order N-terminus to C-terminus):

  • Starting or loading module: AT-ACP-
  • Elongation or extending modules: -KS-AT-[DH-ER-KR]-ACP-
  • Termination or releasing domain: -TE

Domains:

The polyketide chain and the starter groups are bound with their carboxy functional group to the SH groups of the ACP and the KS domain through a thioester linkage: R-C(=O)OH + HS-protein <=> R-C(=O)S-protein + H2O.

The ACP carrier domains are similar to the PCP carrier domains of nonribosomal peptide synthetases, and some proteins combine both types of modules.

Stages edit

The growing chain is handed over from one thiol group to the next by trans-acylations and is released at the end by hydrolysis or by cyclization (alcoholysis or aminolysis).

Starting stage:

  • The starter group, usually acetyl-CoA or its analogues, is loaded onto the ACP domain of the starter module catalyzed by the starter module's AT domain.

Elongation stages:

  • The polyketide chain is handed over from the ACP domain of the previous module to the KS domain of the current module, catalyzed by the KS domain.
  • The elongation group, usually malonyl-CoA or methylmalonyl-CoA, is loaded onto the current ACP domain catalyzed by the current AT domain.
  • The ACP-bound elongation group reacts in a Claisen condensation with the KS-bound polyketide chain under CO2 evolution, leaving a free KS domain and an ACP-bound elongated polyketide chain. The reaction takes place at the KSn-bound end of the chain, so that the chain moves out one position and the elongation group becomes the new bound group.
  • Optionally, the fragment of the polyketide chain can be altered stepwise by additional domains. The KR (keto-reductase) domain reduces the β-keto group to a β-hydroxy group, the DH (dehydratase) domain splits off H2O, resulting in the α-β-unsaturated alkene, and the ER (enoyl-reductase) domain reduces the α-β-double-bond to a single-bond. It is important to note that these modification domains actually affect the previous addition to the chain (i.e. the group added in the previous module), not the component recruited to the ACP domain of the module containing the modification domain.
  • This cycle is repeated for each elongation module.

Termination stage:

  • The TE domain hydrolyzes the completed polyketide chain from the ACP-domain of the previous module.

Pharmacological relevance edit

Polyketide synthases are an important source of naturally occurring small molecules used for chemotherapy.[15] For example, many of the commonly used antibiotics, such as tetracycline and macrolides, are produced by polyketide synthases. Other industrially important polyketides are sirolimus (immunosuppressant), erythromycin (antibiotic), lovastatin (anticholesterol drug), and epothilone B (anticancer drug).[16]

Polyketides are a large family of natural products widely used as drugs, pesticides, herbicides, and biological probes.[17]

There are antifungal and antibacterial polyketide compounds, namely ophiocordin and ophiosetin.[citation needed]

And are researched for the synthesis of biofuels and industrial chemicals.[18]

Ecological significance edit

Only about 1% of all known molecules are natural products, yet it has been recognized that almost two thirds of all drugs currently in use are at least in part derived from a natural source.[19] This bias is commonly explained with the argument that natural products have co-evolved in the environment for long time periods and have therefore been pre-selected for active structures. Polyketide synthase products include lipids with antibiotic, antifungal, antitumor, and predator-defense properties; however, many of the polyketide synthase pathways that bacteria, fungi and plants commonly use have not yet been characterized.[20][21] Methods for the detection of novel polyketide synthase pathways in the environment have therefore been developed. Molecular evidence supports the notion that many novel polyketides remain to be discovered from bacterial sources.[22][23]

See also edit

References edit

  1. ^ Khosla, C.; Gokhale, R. S.; Jacobsen, J. R.; Cane, D. E. (1999). "Tolerance and Specificity of Polyketide Synthases". Annual Review of Biochemistry. 68: 219–253. doi:10.1146/annurev.biochem.68.1.219. PMID 10872449.
  2. ^ Jenke-Kodama, H.; Sandmann, A.; Müller, R.; Dittmann, E. (2005). "Evolutionary Implications of Bacterial Polyketide Synthases". Molecular Biology and Evolution. 22 (10): 2027–2039. doi:10.1093/molbev/msi193. PMID 15958783.
  3. ^ Weng, Jing-Ke; Noel, Joseph P. (2012). "Structure–Function Analyses of Plant Type III Polyketide Synthases". Natural Product Biosynthesis by Microorganisms and Plants, Part A. Methods in Enzymology. Vol. 515. pp. 317–335. doi:10.1016/B978-0-12-394290-6.00014-8. ISBN 978-0-12-394290-6. PMID 22999180.
  4. ^ Pfeifer, Blaine A.; Khosla, Chaitan (March 2001). "Biosynthesis of Polyketides in Heterologous Hosts". Microbiology and Molecular Biology Reviews. 65 (1): 106–118. doi:10.1128/MMBR.65.1.106-118.2001. PMC 99020. PMID 11238987.
  5. ^ Sattely, Elizabeth S.; Fischbach, Michael A.; Walsh, Christopher T. (2008). "Total biosynthesis: in vitro reconstitution of polyketide and nonribosomal peptide pathways". Natural Product Reports. 25 (4): 757–793. doi:10.1039/b801747f. PMID 18663394.
  6. ^ Weissman, Kira J. (2020). "Bacterial Type I Polyketide Synthases". Comprehensive Natural Products III: 4–46. doi:10.1016/b978-0-12-409547-2.14644-x. ISBN 9780081026915. S2CID 201202295.
  7. ^ Helfrich, Eric J. N.; Piel, Jörn (2016). "Biosynthesis of polyketides by trans-AT polyketide synthases". Natural Product Reports. 33 (2): 231–316. doi:10.1039/c5np00125k. PMID 26689670.
  8. ^ "The polyketide metabolites". General Pharmacology: The Vascular System. 23 (6): 1228. November 1992. doi:10.1016/0306-3623(92)90327-g.
  9. ^ Hertweck, Christian; Luzhetskyy, Andriy; Rebets, Yuri; Bechthold, Andreas (2007). "Type II polyketide synthases: gaining a deeper insight into enzymatic teamwork". Nat. Prod. Rep. 24 (1): 162–190. doi:10.1039/B507395M. PMID 17268612.
  10. ^ Sattely, Elizabeth S.; Fischbach, Michael A.; Walsh, Christopher T. (2008). "Total biosynthesis: in vitro reconstitution of polyketide and nonribosomal peptide pathways". Natural Product Reports. 25 (4): 757–793. doi:10.1039/b801747f. PMID 18663394.
  11. ^ Abe, Ikuro; Morita, Hiroyuki (2010). "Structure and function of the chalcone synthase superfamily of plant type III polyketide synthases". Natural Product Reports. 27 (6): 809–838. doi:10.1039/b909988n. PMID 20358127.
  12. ^ Shen, B (April 2003). "Polyketide biosynthesis beyond the type I, II and III polyketide synthase paradigms". Current Opinion in Chemical Biology. 7 (2): 285–295. doi:10.1016/S1367-5931(03)00020-6. PMID 12714063.
  13. ^ Wong, Chin Piow; Morita, Hiroyuki (2020). "Bacterial Type III Polyketide Synthases". Comprehensive Natural Products III: 250–265. doi:10.1016/b978-0-12-409547-2.14640-2. ISBN 9780081026915. S2CID 195410516.
  14. ^ Shimizu, Yugo; Ogata, Hiroyuki; Goto, Susumu (3 January 2017). "Type III Polyketide Synthases: Functional Classification and Phylogenomics". ChemBioChem. 18 (1): 50–65. doi:10.1002/cbic.201600522. PMID 27862822. S2CID 45980356.
  15. ^ Koehn, F. E.; Carter, G. T. (2005). "The evolving role of natural products in drug discovery". Nature Reviews Drug Discovery. 4 (3): 206–220. doi:10.1038/nrd1657. PMID 15729362. S2CID 32749678.
  16. ^ Wawrik, B.; Kerkhof, L.; Zylstra, G. J.; Kukor, J. J. (2005). "Identification of Unique Type II Polyketide Synthase Genes in Soil". Applied and Environmental Microbiology. 71 (5): 2232–2238. Bibcode:2005ApEnM..71.2232W. doi:10.1128/AEM.71.5.2232-2238.2005. PMC 1087561. PMID 15870305.
  17. ^ Pankewitz, Florian; Hilker, Monika (May 2008). "Polyketides in insects: ecological role of these widespread chemicals and evolutionary aspects of their biogenesis". Biological Reviews. 83 (2): 209–226. doi:10.1111/j.1469-185X.2008.00040.x. PMID 18410406. S2CID 27702684.
  18. ^ Cai, Wenlong; Zhang, Wenjun (1 April 2018). "Engineering modular polyketide synthases for production of biofuels and industrial chemicals". Current Opinion in Biotechnology. 50: 32–38. doi:10.1016/j.copbio.2017.08.017. PMC 5862724. PMID 28946011.
  19. ^ Von Nussbaum, F.; Brands, M.; Hinzen, B.; Weigand, S.; Häbich, D. (2006). "Antibacterial Natural Products in Medicinal Chemistry—Exodus or Revival?". Angewandte Chemie International Edition. 45 (31): 5072–5129. doi:10.1002/anie.200600350. PMID 16881035.
  20. ^ Castoe, T. A.; Stephens, T.; Noonan, B. P.; Calestani, C. (2007). "A novel group of type I polyketide synthases (PKS) in animals and the complex phylogenomics of PKSs". Gene. 392 (1–2): 47–58. doi:10.1016/j.gene.2006.11.005. PMID 17207587.
  21. ^ Ridley, C. P.; Lee, H. Y.; Khosla, C. (2008). "Chemical Ecology Special Feature: Evolution of polyketide synthases in bacteria". Proceedings of the National Academy of Sciences. 105 (12): 4595–4600. Bibcode:2008PNAS..105.4595R. doi:10.1073/pnas.0710107105. PMC 2290765. PMID 18250311.
  22. ^ Metsä-Ketelä, M.; Salo, V.; Halo, L.; Hautala, A.; Hakala, J.; Mäntsälä, P.; Ylihonko, K. (1999). "An efficient approach for screening minimal PKS genes from Streptomyces". FEMS Microbiology Letters. 180 (1): 1–6. doi:10.1016/S0378-1097(99)00453-X. PMID 10547437.
  23. ^ Wawrik, B.; Kutliev, D.; Abdivasievna, U. A.; Kukor, J. J.; Zylstra, G. J.; Kerkhof, L. (2007). "Biogeography of Actinomycete Communities and Type II Polyketide Synthase Genes in Soils Collected in New Jersey and Central Asia". Applied and Environmental Microbiology. 73 (9): 2982–2989. Bibcode:2007ApEnM..73.2982W. doi:10.1128/AEM.02611-06. PMC 1892886. PMID 17337547.

External links edit

December 15, 2023
polyketide, synthase, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news, newspapers, books, scholar, jstor, novem. This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Polyketide synthase news newspapers books scholar JSTOR November 2008 Learn how and when to remove this template message Polyketide synthases PKSs are a family of multi domain enzymes or enzyme complexes that produce polyketides a large class of secondary metabolites in bacteria fungi plants and a few animal lineages The biosyntheses of polyketides share striking similarities with fatty acid biosynthesis 1 2 The PKS genes for a certain polyketide are usually organized in one operon or in gene clusters Type I and type II PKSs form either large modular protein complexes or dissociable molecular assemblies type III PKSs exist as smaller homodimeric proteins 3 4 Contents 1 Classification 2 Modules and domains 3 Stages 4 Pharmacological relevance 5 Ecological significance 6 See also 7 References 8 External linksClassification edit nbsp Reaction mechanisms of type I II and III PKSs Decarboxylation of malonyl unit followed by thio Claisen condensation a cis AT type I PKS with acyl carrier protein ACP keto synthase KS and acyl transferase AT domains covalently bound to another b Type II PKS with KSa KSb heterodimer and ACP as separate proteins c ACP independent Type III PKS PKSs can be classified into three types Type I PKSs are large complex protein structures with multiple modules which in turn consist of several domains that are usually covalently connected to each other and fulfill different catalytic steps The minimal composition of a type I PKS module consists of an acyltransferase AT domain which is responsible for choosing the building block to be used a keto synthase KS domain which catalyzes the C C bond formation and an acyl carrier protein ACP domain also known as thiolation domain The latter contains a conserved Ser residue post translationally modified with a phosphopantetheine at the end of which the polyketide chain is covalently bound during biosynthesis as a thioester Moreover multiple other optional domains can also exist within a module like ketoreductase or dehydratase domains which alter the default 1 3 dicarbonyl functionality of the installed ketide by sequential reduction to an alcohol and double bond respectively 5 6 These domains work together like an assembly line This type of type I PKSs is also referred to as cis acyltransferase polyketide synthases cis AT PKSs In contrast to that so called trans AT PKSs evolved independently and lack AT domains in their modules This activity is provided by free standing AT domains instead Moreover they often contain uncommon domains with unique catalytic activities 7 Type II PKSs behave very similarly to type I PKS but with one key difference Instead of one large megaenzyme type II PKSs are separate monofunctional enzymes The smallest possible type II PKS consists of an ACP as well as two heterodimeric KS units KSa which catalyzes the C C bond formation and KSb also known as chain length factor CLF since it can determine the carbon chain length 8 which fulfill a similar function as the AT KS and ACP domains in type I PKSs even though type II PKSs are lacking a separate AT domain Additionally type II PKSs often work iteratively where multiple chain elongation steps are carried out by the same enzyme similar to type III PKSs 9 10 Type III PKSs are small homodimers of 40 kDa proteins that combine all the activities from the essential type I and II PKS domains However in contrast to type I and II PKSs they do not require an ACP bound substrate Instead they can use a free acyl CoA substrate for chain elongation 11 12 13 Moreover type III PKSs contain a Cys His Asn catalytic triad in their active center with the cysteine residue acting as the attacking nucleophile whereas type I and II PKSs are characterized by a Cys His His catalytic triad 14 Typical products of type III PKSs include phenolic lipids like alkylresorcinolsIn addition to these three types of PKSs they can be further classified as iterative or noniterative Iterative Type I PKSs reuse domains in a cyclic fashion Other classifications include the degree of reduction performed during the synthesis of the growing polyketide chain NR PKSs non reducing PKSs the products of which are true polyketides PR PKSs partially reducing PKSs FR PKSs fully reducing PKSs the products of which are fatty acid derivativesModules and domains edit nbsp Biosynthesis of the doxorubicin precursor ye rhodomycinone The polyketide synthase reactions are shown on top Each type I polyketide synthase module consists of several domains with defined functions separated by short spacer regions The order of modules and domains of a complete polyketide synthase is as follows in the order N terminus to C terminus Starting or loading module AT ACP Elongation or extending modules KS AT DH ER KR ACP Termination or releasing domain TEDomains AT Acyltransferase ACP Acyl carrier protein with an SH group on the cofactor a serine attached 4 phosphopantetheine KS Keto synthase with an SH group on a cysteine side chain KR Ketoreductase DH Dehydratase ER Enoylreductase MT Methyltransferase O or C a or b SH PLP dependent cysteine lyase TE ThioesteraseThe polyketide chain and the starter groups are bound with their carboxy functional group to the SH groups of the ACP and the KS domain through a thioester linkage R C O OH HS protein lt gt R C O S protein H2O The ACP carrier domains are similar to the PCP carrier domains of nonribosomal peptide synthetases and some proteins combine both types of modules Stages editThe growing chain is handed over from one thiol group to the next by trans acylations and is released at the end by hydrolysis or by cyclization alcoholysis or aminolysis Starting stage The starter group usually acetyl CoA or its analogues is loaded onto the ACP domain of the starter module catalyzed by the starter module s AT domain Elongation stages The polyketide chain is handed over from the ACP domain of the previous module to the KS domain of the current module catalyzed by the KS domain The elongation group usually malonyl CoA or methylmalonyl CoA is loaded onto the current ACP domain catalyzed by the current AT domain The ACP bound elongation group reacts in a Claisen condensation with the KS bound polyketide chain under CO2 evolution leaving a free KS domain and an ACP bound elongated polyketide chain The reaction takes place at the KSn bound end of the chain so that the chain moves out one position and the elongation group becomes the new bound group Optionally the fragment of the polyketide chain can be altered stepwise by additional domains The KR keto reductase domain reduces the b keto group to a b hydroxy group the DH dehydratase domain splits off H2O resulting in the a b unsaturated alkene and the ER enoyl reductase domain reduces the a b double bond to a single bond It is important to note that these modification domains actually affect the previous addition to the chain i e the group added in the previous module not the component recruited to the ACP domain of the module containing the modification domain This cycle is repeated for each elongation module Termination stage The TE domain hydrolyzes the completed polyketide chain from the ACP domain of the previous module Pharmacological relevance editPolyketide synthases are an important source of naturally occurring small molecules used for chemotherapy 15 For example many of the commonly used antibiotics such as tetracycline and macrolides are produced by polyketide synthases Other industrially important polyketides are sirolimus immunosuppressant erythromycin antibiotic lovastatin anticholesterol drug and epothilone B anticancer drug 16 Polyketides are a large family of natural products widely used as drugs pesticides herbicides and biological probes 17 There are antifungal and antibacterial polyketide compounds namely ophiocordin and ophiosetin citation needed And are researched for the synthesis of biofuels and industrial chemicals 18 Ecological significance editOnly about 1 of all known molecules are natural products yet it has been recognized that almost two thirds of all drugs currently in use are at least in part derived from a natural source 19 This bias is commonly explained with the argument that natural products have co evolved in the environment for long time periods and have therefore been pre selected for active structures Polyketide synthase products include lipids with antibiotic antifungal antitumor and predator defense properties however many of the polyketide synthase pathways that bacteria fungi and plants commonly use have not yet been characterized 20 21 Methods for the detection of novel polyketide synthase pathways in the environment have therefore been developed Molecular evidence supports the notion that many novel polyketides remain to be discovered from bacterial sources 22 23 See also editDoxorubicinReferences edit Khosla C Gokhale R S Jacobsen J R Cane D E 1999 Tolerance and Specificity of Polyketide Synthases Annual Review of Biochemistry 68 219 253 doi 10 1146 annurev biochem 68 1 219 PMID 10872449 Jenke Kodama H Sandmann A Muller R Dittmann E 2005 Evolutionary Implications of Bacterial Polyketide Synthases Molecular Biology and Evolution 22 10 2027 2039 doi 10 1093 molbev msi193 PMID 15958783 Weng Jing Ke Noel Joseph P 2012 Structure Function Analyses of Plant Type III Polyketide Synthases Natural Product Biosynthesis by Microorganisms and Plants Part A Methods in Enzymology Vol 515 pp 317 335 doi 10 1016 B978 0 12 394290 6 00014 8 ISBN 978 0 12 394290 6 PMID 22999180 Pfeifer Blaine A Khosla Chaitan March 2001 Biosynthesis of Polyketides in Heterologous Hosts Microbiology and Molecular Biology Reviews 65 1 106 118 doi 10 1128 MMBR 65 1 106 118 2001 PMC 99020 PMID 11238987 Sattely Elizabeth S Fischbach Michael A Walsh Christopher T 2008 Total biosynthesis in vitro reconstitution of polyketide and nonribosomal peptide pathways Natural Product Reports 25 4 757 793 doi 10 1039 b801747f PMID 18663394 Weissman Kira J 2020 Bacterial Type I Polyketide Synthases Comprehensive Natural Products III 4 46 doi 10 1016 b978 0 12 409547 2 14644 x ISBN 9780081026915 S2CID 201202295 Helfrich Eric J N Piel Jorn 2016 Biosynthesis of polyketides by trans AT polyketide synthases Natural Product Reports 33 2 231 316 doi 10 1039 c5np00125k PMID 26689670 The polyketide metabolites General Pharmacology The Vascular System 23 6 1228 November 1992 doi 10 1016 0306 3623 92 90327 g Hertweck Christian Luzhetskyy Andriy Rebets Yuri Bechthold Andreas 2007 Type II polyketide synthases gaining a deeper insight into enzymatic teamwork Nat Prod Rep 24 1 162 190 doi 10 1039 B507395M PMID 17268612 Sattely Elizabeth S Fischbach Michael A Walsh Christopher T 2008 Total biosynthesis in vitro reconstitution of polyketide and nonribosomal peptide pathways Natural Product Reports 25 4 757 793 doi 10 1039 b801747f PMID 18663394 Abe Ikuro Morita Hiroyuki 2010 Structure and function of the chalcone synthase superfamily of plant type III polyketide synthases Natural Product Reports 27 6 809 838 doi 10 1039 b909988n PMID 20358127 Shen B April 2003 Polyketide biosynthesis beyond the type I II and III polyketide synthase paradigms Current Opinion in Chemical Biology 7 2 285 295 doi 10 1016 S1367 5931 03 00020 6 PMID 12714063 Wong Chin Piow Morita Hiroyuki 2020 Bacterial Type III Polyketide Synthases Comprehensive Natural Products III 250 265 doi 10 1016 b978 0 12 409547 2 14640 2 ISBN 9780081026915 S2CID 195410516 Shimizu Yugo Ogata Hiroyuki Goto Susumu 3 January 2017 Type III Polyketide Synthases Functional Classification and Phylogenomics ChemBioChem 18 1 50 65 doi 10 1002 cbic 201600522 PMID 27862822 S2CID 45980356 Koehn F E Carter G T 2005 The evolving role of natural products in drug discovery Nature Reviews Drug Discovery 4 3 206 220 doi 10 1038 nrd1657 PMID 15729362 S2CID 32749678 Wawrik B Kerkhof L Zylstra G J Kukor J J 2005 Identification of Unique Type II Polyketide Synthase Genes in Soil Applied and Environmental Microbiology 71 5 2232 2238 Bibcode 2005ApEnM 71 2232W doi 10 1128 AEM 71 5 2232 2238 2005 PMC 1087561 PMID 15870305 Pankewitz Florian Hilker Monika May 2008 Polyketides in insects ecological role of these widespread chemicals and evolutionary aspects of their biogenesis Biological Reviews 83 2 209 226 doi 10 1111 j 1469 185X 2008 00040 x PMID 18410406 S2CID 27702684 Cai Wenlong Zhang Wenjun 1 April 2018 Engineering modular polyketide synthases for production of biofuels and industrial chemicals Current Opinion in Biotechnology 50 32 38 doi 10 1016 j copbio 2017 08 017 PMC 5862724 PMID 28946011 Von Nussbaum F Brands M Hinzen B Weigand S Habich D 2006 Antibacterial Natural Products in Medicinal Chemistry Exodus or Revival Angewandte Chemie International Edition 45 31 5072 5129 doi 10 1002 anie 200600350 PMID 16881035 Castoe T A Stephens T Noonan B P Calestani C 2007 A novel group of type I polyketide synthases PKS in animals and the complex phylogenomics of PKSs Gene 392 1 2 47 58 doi 10 1016 j gene 2006 11 005 PMID 17207587 Ridley C P Lee H Y Khosla C 2008 Chemical Ecology Special Feature Evolution of polyketide synthases in bacteria Proceedings of the National Academy of Sciences 105 12 4595 4600 Bibcode 2008PNAS 105 4595R doi 10 1073 pnas 0710107105 PMC 2290765 PMID 18250311 Metsa Ketela M Salo V Halo L Hautala A Hakala J Mantsala P Ylihonko K 1999 An efficient approach for screening minimal PKS genes from Streptomyces FEMS Microbiology Letters 180 1 1 6 doi 10 1016 S0378 1097 99 00453 X PMID 10547437 Wawrik B Kutliev D Abdivasievna U A Kukor J J Zylstra G J Kerkhof L 2007 Biogeography of Actinomycete Communities and Type II Polyketide Synthase Genes in Soils Collected in New Jersey and Central Asia Applied and Environmental Microbiology 73 9 2982 2989 Bibcode 2007ApEnM 73 2982W doi 10 1128 AEM 02611 06 PMC 1892886 PMID 17337547 External links editPolyketide synthases at the U S National Library of Medicine Medical Subject Headings MeSH Portal nbsp Biology Retrieved from https en wikipedia org w index php title Polyketide synthase amp oldid 1171081394, wikipedia, wiki, book, books, library,

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