Structural Characterization of Complex of Adenylation Domain and Carrier Protein by Using Pantetheine Cross-Linking Probe

Miyanaga, Akimasa; Kurihara, Shohei; Chisuga, Taichi; Kudo, Fumitaka; Eguchi, Tadashi

doi:10.1021/acschembio.0c00403

Cited by 21 publications

(29 citation statements)

References 27 publications

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“…By engineering a Cys into the A domain active site via site-specific mutagenesis, Scheming and Tarry activated the A domain to make a disulfide bond with the PCP Ppant arm thiol (110), a linkage reminiscent of the disulfidebased cross-link between AcpP and FabF shown in Figure 4C. In another 'trapping' strategy that leverages mutagenesis, Miyanaga et al (111) showed that incorporating a Cys into the A domain active site and installing an electrophilic bromoacetamide pantetheine crosslinking probe on the PCP activates the PCP-A complex formation. Taken together, these approaches highlight additional flexibility in how type II PKS ACPs can potentially be stabilized in complex to other enzymes by altering the nucleophilicity and/or the electrophilicity of the component proteins and/or protein-bound substrates.…”

Section: Connections To Other Biosynthetic Pathways That Use Assembly Line Enzymologymentioning

confidence: 99%

Probing the structure and function of acyl carrier proteins to unlock the strategic redesign of type II polyketide biosynthetic pathways

Sulpizio¹,

Crawford²,

Koweek³

et al. 2021

Journal of Biological Chemistry

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Type II polyketide synthases (PKSs) are protein assemblies, encoded by biosynthetic gene clusters in microorganisms, that manufacture structurally complex and pharmacologically relevant molecules. Acyl carrier proteins (ACPs) play a central role in biosynthesis by shuttling malonyl-based building blocks and polyketide intermediates to catalytic partners for chemical transformations. Because ACPs serve as central hubs in type II PKSs, they can also represent roadblocks to successfully engineering synthases capable of manufacturing ‘unnatural natural products.’ Therefore, understanding ACP conformational dynamics and protein interactions is essential to enable the strategic redesign of type II PKSs. However, the inherent flexibility and transience of ACP interactions pose challenges to gaining insight into ACP structure and function. In this review, we summarize how the application of chemical probes and molecular dynamic simulations has increased our understanding of the structure and function of type II PKS ACPs. We also share how integrating these advances in type II PKS ACP research with newfound access to key enzyme partners, such as the ketosynthase-chain length factor, sets the stage to unlock new biosynthetic potential.

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Section: Connections To Other Biosynthetic Pathways That Use Assembly Line Enzymologymentioning

confidence: 99%

Probing the structure and function of acyl carrier proteins to unlock the strategic redesign of type II polyketide biosynthetic pathways

Sulpizio¹,

Crawford²,

Koweek³

et al. 2021

Journal of Biological Chemistry

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“…Initially, 150 mM of each pantetheineamide probe was mixed with 5 mM ATP, 7.5 mM MgCl 2 , 0.5 mM CoaA, 0.7 mM CoaD, 0.6 mM CoaE, 2.5 mM Sfp and 100 mM VinL in a buffer consisting of 50 mM NaH 2 PO 4 /K 2 HPO 4 pH 8.0 (total volume 25 ml). The VinL modification reaction was carried out at 301 K for 3 h. The conversion of apo VinL to modified VinL was confirmed by LC-ESI-MS analysis as described previously (Miyanaga et al, 2020). Next, the cross-linking reaction was initiated by adding 15 mM wild-type or mutant VinK directly into the reaction mixture.…”

Section: Cross-linking Reactionmentioning

confidence: 99%

“…Because we had previously synthesized bromoacetamide, chloroacetamide and trans-3-chloroacrylamide pantetheine probes (Fig. 2a), we enzymatically loaded these probes onto apo VinL in a one-pot reaction, as described previously (Miyanaga et al, 2020). The CoaA, CoaD and CoaE proteins from the CoA-biosynthetic pathway (Haushalter et al, 2008) were used for the conversion of each pantetheineamide to a CoA derivative, and the phosphopantetheinyl transferase Sfp (Quadri et al, 1998) was used to attach the phosphopanthetheineamide moiety of the resulting CoA derivative to Ser36 of apo VinL to generate each modified VinL protein.…”

Section: Cross-linking Reactionmentioning

confidence: 99%

Complex structure of the acyltransferase VinK and the carrier protein VinL with a pantetheine cross-linking probe

et al. 2021

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Acyltransferases are responsible for the selection and loading of acyl units onto carrier proteins in polyketide and fatty-acid biosynthesis. Despite the importance of protein–protein interactions between the acyltransferase and the carrier protein, structural information on acyltransferase–carrier protein interactions is limited because of the transient interactions between them. In the biosynthesis of the polyketide vicenistatin, the acyltransferase VinK recognizes the carrier protein VinL for the transfer of a dipeptidyl unit. The crystal structure of a VinK–VinL covalent complex formed with a 1,2-bismaleimidoethane cross-linking reagent has been determined previously. Here, the crystal structure of a VinK–VinL covalent complex formed with a pantetheine cross-linking probe is reported at 1.95 Å resolution. In the structure of the VinK–VinL–probe complex, the pantetheine probe that is attached to VinL is covalently connected to the side chain of the mutated Cys106 of VinK. The interaction interface between VinK and VinL is essentially the same in the two VinK–VinL complex structures, although the position of the pantetheine linker slightly differs. This structural observation suggests that interface interactions are not affected by the cross-linking strategy used.

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“…Mechanism-based crosslinking probes have been used to probe protein-protein interactions in NRPSs. 19,20 Recently, Aldrich and co-workers utilized crosslinking probes to study the interactions between the PCP and C domains 19 and Eguchi and co-workers applied crosslinking probes to obtain structural information of PCP-A domain complexes. 20 Here we introduce the development of new crosslinking probes and their application with mutagenesis studies to investigate the NRPS E domain mechanism.…”

Section: Introductionmentioning

confidence: 99%

“…19,20 Recently, Aldrich and co-workers utilized crosslinking probes to study the interactions between the PCP and C domains 19 and Eguchi and co-workers applied crosslinking probes to obtain structural information of PCP-A domain complexes. 20 Here we introduce the development of new crosslinking probes and their application with mutagenesis studies to investigate the NRPS E domain mechanism. We had previously identified chlorovinylglycine, a mechanism-based inhibitor of alanine racemase, as a PCP and E domain crosslinker.…”

Section: Introductionmentioning

confidence: 99%

Developing crosslinkers specific for epimerization domain in NRPS initiation modules to evaluate mechanism

Kim

Ishikawa

et al. 2022

RSC Chem. Biol.

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Structural Characterization of Complex of Adenylation Domain and Carrier Protein by Using Pantetheine Cross-Linking Probe

Cited by 21 publications

References 27 publications

Probing the structure and function of acyl carrier proteins to unlock the strategic redesign of type II polyketide biosynthetic pathways

Probing the structure and function of acyl carrier proteins to unlock the strategic redesign of type II polyketide biosynthetic pathways

Complex structure of the acyltransferase VinK and the carrier protein VinL with a pantetheine cross-linking probe

Developing crosslinkers specific for epimerization domain in NRPS initiation modules to evaluate mechanism

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