Crystal Structure of Mycobacterium tuberculosis Polyketide Synthase 11 (PKS11) Reveals Intermediates in the Synthesis of Methyl-branched Alkylpyrones

Gokulan, Kuppan; O’Leary, Seán E.; Russell, William K.; Russell, David H.; Lalgondar, Mallikarjun; Begley, Tadhg P.; Ioerger, Thomas R.; Sacchettini, James C.

doi:10.1074/jbc.m113.468892

Cited by 25 publications

(29 citation statements)

References 40 publications

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“…This is analogous to PKSA and PpASCL, whereby a replacement of bulky Thr197 in alfalfa CHS with a smaller Gly205 in PKSA and Gly225 in PpASCL is believed to widen the entrance of the acyl-binding tunnel, enabling them to utilize larger acyl-CoAs as starters [63]. The crystal structure of PKS11 was recently solved (PDB ID: 4JAP), and a buried hydrophobic tunnel was also revealed, together with a CoA-binding tunnel [73]. Co-crystallizations and in vitro enzyme assays revealed that PKS11 can catalyze the decarboxylative condensation of methylmalonyl-CoA with palmitoyl-CoA (C16) or stearoyl-CoA (C18), followed by another decarboxylative condensation of malonyl-CoA and lactonization to generate methylated alkylpyrones.…”

Section: Biosynthesis Of Alkylpyrones By Pks11 and Pks18mentioning

confidence: 95%

“…The ability of PKS11 to select different extenders at different stages of polyketide elongation is intriguing, and more structural studies in this aspect will be useful for the generation of clinically important unnatural polyketides. The crystal structure of PKS11 was recently solved (PDB ID: 4JAP), and a buried hydrophobic tunnel was also revealed, together with a CoA-binding tunnel [73]. Co-crystallizations and in vitro enzyme assays revealed that PKS11 can catalyze the decarboxylative condensation of methylmalonyl-CoA with palmitoyl-CoA (C16) or stearoyl-CoA (C18), followed by another decarboxylative condensation of malonyl-CoA and lactonization to generate methylated alkylpyrones.…”

Section: Biosynthesis Of Alkylpyrones By Pks11 and Pks18mentioning

confidence: 99%

“…Crystallographic analyses of the plant type III PKSs (alfalfa CHS [23], Scots pine STS [26], daisy 2-PS [35], rhubarb BAS [45], O. sativa CUS [49], C. microcarpa ACS and QNS [59], and brown alga phloroglucinol synthase [60]), the bacterial PKSs (S. coelicolor THNS [66], M. tuberculosis PKS11 [73] and PKS18 [72], A. vinelandii ArsC [80]), and of the fungal ORAS from N. crassa [83] have enabled the understanding of the basis of starter molecule selectivity, chain elongation, and cyclization of the linear polyketide intermediate. These structural studies have provided insights into the mechanistic details of type III PKSs, illustrating how subtle modifications in the active site cavity can expand the biosynthetic repertoire and result in the generation of diverse products.…”

Section: Insights Into Mutagenesis Studiesmentioning

confidence: 99%

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Exploiting the Biosynthetic Potential of Type III Polyketide Synthases

Lim

Yew

2016

Molecules

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Abstract:Polyketides are structurally and functionally diverse secondary metabolites that are biosynthesized by polyketide synthases (PKSs) using acyl-CoA precursors. Recent studies in the engineering and structural characterization of PKSs have facilitated the use of target enzymes as biocatalysts to produce novel functionally optimized polyketides. These compounds may serve as potential drug leads. This review summarizes the insights gained from research on type III PKSs, from the discovery of chalcone synthase in plants to novel PKSs in bacteria and fungi. To date, at least 15 families of type III PKSs have been characterized, highlighting the utility of PKSs in the development of natural product libraries for therapeutic development.

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Section: Biosynthesis Of Alkylpyrones By Pks11 and Pks18mentioning

confidence: 95%

Section: Biosynthesis Of Alkylpyrones By Pks11 and Pks18mentioning

confidence: 99%

Section: Insights Into Mutagenesis Studiesmentioning

confidence: 99%

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Exploiting the Biosynthetic Potential of Type III Polyketide Synthases

Lim

Yew

2016

Molecules

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“…Two recent KS crystal structures provide the first views of bona fide substrates as covalent intermediates in the KS active site. One structure is for a PKS that acts on acyl-CoA substrates [54], and the other is excised from a trans -AT pathway [51]. The spacious KS active sites appear to provide binding pockets adapted to their substrates, and based on these high-resolution substrate complexes, it is challenging to predict the position of a new building block delivered through the entrance for the module ACP.…”

Section: Overall Architecturementioning

confidence: 99%

Architecture of the polyketide synthase module: surprises from electron cryo-microscopy

Smith

Skiniotis

Sherman

2015

Current Opinion in Structural Biology

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Modular polyketide synthases produce a vast array of bioactive molecules that are the basis of many highly valued pharmaceuticals. The biosynthesis of these compounds is based on ordered assembly lines of multi-domain modules, each extending and modifying a specific chain-elongation intermediate before transfer to the next module for further processing. The first 3D structures of a full polyketide synthase module in different functional states were obtained recently by electron cryo-microscopy. The unexpected module architecture revealed a striking evolutionary divergence of the polyketide synthase compared to its metazoan fatty acid synthase homolog, as well as remarkable conformational rearrangements dependent on its biochemical state during the full catalytic cycle. The design and dynamics of the module are highly optimized for both catalysis and fidelity in the construction of complex, biologically active natural products.

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“…M. smegmatis, a fast-growing saprophytic relative of Mtb, is a potential expression host for Mtb genes overcoming many of the restrictions of E. coli (36)(37)(38)(39). Unexpectedly, however, only nine proteins of H37Rv represented by 27 structures were produced in M. smegmatis (37,(40)(41)(42)(43)(44)(45)(46). Clearly the faster growth and production rates of E. coli ensure that it remains the most popular expression host.…”

Section: Technical Aspects Of Mtb Structural Analysismentioning

confidence: 99%

Assessing the progress of Mycobacterium tuberculosis H37Rv structural genomics

et al. 2015

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Tuberculosis threatens human health nowhere more than in developing countries with large malnourished and/or immune-compromised (e.g. HIV infected) populations. The etiological agent, Mycobacterium tuberculosis (Mtb), is highly infectious and current interventions demonstrate limited ability to control the epidemic in particular of drug resistant Mtb strains. New drugs and vaccines are thus urgently required. Structural biologists are critical to the TB research community. By identifying potential drug targets and solving their three dimensional structures they open new avenues of identifying potential inhibitors complementing the screening of novel compounds and the investigation of Mtb's molecular physiology by pharmaceutical companies and academic researchers. Much effort has gone into structurally elucidating the Mtb proteome though much remains to be done with progress primarily limited by technological constraints. We review the currently available data for Mtb H37Rv to extract the lessons they have taught us. KeywordsMycobacterium tuberculosis, structural genomics, drug target AbbreviationsAll abbreviations in the manuscript are standard in the field.

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Crystal Structure of Mycobacterium tuberculosis Polyketide Synthase 11 (PKS11) Reveals Intermediates in the Synthesis of Methyl-branched Alkylpyrones

Cited by 25 publications

References 40 publications

Exploiting the Biosynthetic Potential of Type III Polyketide Synthases

Exploiting the Biosynthetic Potential of Type III Polyketide Synthases

Architecture of the polyketide synthase module: surprises from electron cryo-microscopy

Assessing the progress of Mycobacterium tuberculosis H37Rv structural genomics

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