Structure of the peptidoglycan polymerase RodA resolved by evolutionary coupling analysis

Sjodt, Megan; Brock, Kelly; Dobihal, Genevieve S; Rohs, Patricia D. A.; Green, Anna G.; Hopf, Thomas A.; Meeske, Alexander J.; Srisuknimit, Veerasak; Kahne, Daniel; Walker, Suzanne; Marks, Debora S.; Bernhardt, Thomas G.; Rudner, David Z.; Kruse, Andrew C.

doi:10.1038/nature25985

Cited by 121 publications

(150 citation statements)

References 48 publications

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“…ECs have been used successfully to predict the tertiary contacts (Marks, et al, 2011;Morcos, et al, 2011) and full 3D structure of proteins (Marks, et al, 2011) and RNA (Weinreb, et al, 2016), as well as protein-protein and protein-RNA interactions, disorder and conformational changes (Weigt, et al, 2009;Hopf, et al, 2012;Hopf, et al, 2014;Ovchinnikov, et al, 2014;Rodriguez-Rivas, et al, 2016;Toth-Petroczy, et al, 2016) and the effects of mutations (Figliuzzi, et al, 2015;Hopf, et al, 2017). More recently, hybrid approaches have integrated ECs with experimental data for improved structure determination using NMR, cryo-EM and X-ray crystallography data (Tang, et al, 2015;Sjodt, et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

The EVcouplings Python framework for coevolutionary sequence analysis

Hopf

Green

Schubert

et al. 2018

Preprint

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111

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Summary: Coevolutionary sequence analysis has become a commonly used technique for de novo prediction of the structure and function of proteins, RNA, and protein complexes. This approach requires extensive computational pipelines that integrate multiple tools, databases, and data processing steps. We present the EVcouplings framework, a fully integrated open-source application and Python package for coevolutionary analysis. The framework enables generation of sequence alignments, calculation and evaluation of evolutionary couplings (ECs), and de novo prediction of structure and mutation effects. The application has an easy to use command line interface to run workflows with user control over all analysis parameters, while the underlying modular Python package allows interactive data analysis and rapid development of new workflows. Through this multi-layered approach, the EVcouplings framework makes the full power of coevolutionary analyses available to entry-level and advanced users.

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Section: Introductionmentioning

confidence: 99%

The EVcouplings Python framework for coevolutionary sequence analysis

Hopf

Green

Schubert

et al. 2018

Preprint

Self Cite

111

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“…The ligands of many membrane-integral enzymes and transporters are hydrophobic (or at least amphipathic), implying these ligands are most likely recognized (and released) laterally, from (and to) the membrane instead of through the aqueous phase. In particular membraneintegral enzymes with lipid-like ligands include many transferases (20)(21)(22)(23)(24), as well as some translocases (25), synthases (26), polymerases (27) and proteases (28). Little is known about how most of these proteins interact with the membrane, but the increasing availability of structural data will surely help advance our understanding.…”

Section: Resultsmentioning

confidence: 99%

DHHC20 palmitoyl-transferase reshapes the membrane to foster catalysis

Stix

Song

Banerjee

et al. 2019

Preprint

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Cysteine palmitoylation, a form of S-acylation, is a key post-translational modification in cellular signaling. This type of reversible lipidation is catalyzed by a family of integral membrane proteins known as DHHC acyltransferases. The first step in the S-acylation process is the recognition of free acyl-CoA from the lipid bilayer. The DHHC enzyme then becomes autoacylated, at a site defined by a conserved Asp-His-His-Cys motif. This reaction entails ionization of the catalytic Cys. Intriguingly, in known DHHC structures this catalytic Cys appears to be exposed to the hydrophobic interior of the lipid membrane, which would be highly unfavorable for a negatively charged nucleophile, thus hindering auto-acylation. Here, we use biochemical and computational methods to reconcile these seemingly contradicting facts. First, we experimentally demonstrate that human DHHC20 is active when reconstituted in POPC nanodiscs. Microsecond-long all-atom molecular dynamics simulations are then calculated for hDHHC20 and for different acyl-CoA forms, also in POPC. Strikingly, we observe that hDHHC20 induces a drastic deformation in the membrane, particularly on the cytoplasmic side where autoacylation occurs. As a result, the catalytic Cys becomes hydrated and optimally positioned to encounter the cleavage site in acyl-CoA. In summary, we hypothesize that DHHC enzymes locally reshape the membrane to foster a morphology that is specifically adapted for acyl-CoA recognition and auto-acylation.3 Significance StatementPalmitoylation, the most common form of S-acylation and the only reversible type of protein lipidation, is ubiquitous in eukaryotic cells. In humans, for example, it has been estimated that as much as ~10% of the proteome becomes palmitoylated, i.e. thousands of proteins. Accordingly, protein palmitoylation touches every important aspect of human physiology, both in health and disease. Despite its biological and biomedical importance, little is known about the molecular mechanism of the enzymes that catalyze this post-translational modification, known as DHHC acyltransferases. Here, we leverage the recently-determined atomic-resolution structure of human DHHC20 to gain novel insights into the mechanism of this class of enzymes, using both experimental and computational approaches.

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“…Therefore, following the discovery of PG polymerase activity for RodA, it was proposed that RodA-PBP2 and other SEDS-bPBP complexes form a functional PG synthase with both polymerase and crosslinking activity (Cho et al, 2016;Meeske et al, 2016). This possibility is supported by recent evolutionary coupling analyses and mutational studies indicating that a RodA-PBP2 complex formed through interactions between RodA and the pedestal domain of PBP2 is likely to be critical for Rod system function (Sjodt et al, 2018).…”

Section: Coupling Of Pg Polymerization and Crosslinking Within The Romentioning

confidence: 99%

“…In both Escherichia coli and Bacillus subtilis, the aPBPs have been shown to display distinct subcellular localization dynamics from Rod system components and to be dispensable for the activity of the machinery (Cho et al, 2016;Meeske et al, 2016). It has therefore been proposed that a RodA-PBP2 complex forms the core PG synthase of the Rod system, an idea supported by recent evolutionary covariation analysis (Sjodt et al, 2018), and the finding that the aPBPs largely operate outside of the cytoskeletal system during cell elongation (Cho et al, 2016). A similar division of labor between aPBPs and FtsW-PBP3 may also be taking place during cytokinesis, but the relative contributions of the two types of synthases to the division process requires further definition.…”

Section: Introductionmentioning

confidence: 99%

An activation pathway governs cell wall polymerization by a bacterial morphogenic machine

Pda

Buss

et al. 2018

Preprint

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Cell elongation in rod-shaped bacteria is mediated by the Rod system, a conserved morphogenic complex that spatially controls cell wall (CW) assembly. In Escherichia coli, alterations in a CW synthase component of the system called PBP2 were identified that overcome other inactivating defects. Rod system activity was stimulated in the suppressors in vivo, and purified synthase complexes with these changes showed more robust CW synthesis in vitro. Polymerization of the actinlike MreB component of the Rod system was also found to be enhanced in cells with the activated synthase. The results suggest an activation pathway governing Rod system function in which PBP2 conformation plays a central role in stimulating both CW glycan polymerization by its partner RodA and the formation of cytoskeletal filaments of MreB to orient CW assembly. An analogous activation pathway involving similar enzymatic components is likely responsible for controlling CW synthesis by the division machinery.

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Structure of the peptidoglycan polymerase RodA resolved by evolutionary coupling analysis

Cited by 121 publications

References 48 publications

The EVcouplings Python framework for coevolutionary sequence analysis

The EVcouplings Python framework for coevolutionary sequence analysis

DHHC20 palmitoyl-transferase reshapes the membrane to foster catalysis

An activation pathway governs cell wall polymerization by a bacterial morphogenic machine

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