The PduL Phosphotransacylase Is Used To Recycle Coenzyme A within the Pdu Microcompartment

Liu, Yu; Jorda, Julien; Yeates, Todd O.; Bobik, Thomas A.

doi:10.1128/jb.00056-15

Cited by 38 publications

(54 citation statements)

References 49 publications

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“…Together with previous reports by other groups, peptide‐mediated targeting seems to be suitable to rationally reprogram the Pdu‐BMC with various heterologous proteins. Four native EPs (PduD, PduL, PduP, PduV) are currently available that had been engineered to compete with the native EPs, thus allowing to control the ratio between the heterologous proteins to be encapsulated . However, our observations indicate that the nature of the cargo‐protein might influence targeting efficiency and encapsulation in a so far elusive manner, too, thereby complicating the rational design.…”

Section: Resultsmentioning

confidence: 98%

Engineering bacterial microcompartments with heterologous enzyme cargos

Wagner

Capitain

Richter

et al. 2016

Engineering in Life Sciences

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Bacterial microcompartments (BMCs) are intracellular proteinaceous organelles devoid of a lipid membrane that encapsulates enzymes of metabolic pathways. Salmonella enterica synthesizes propanediol‐utilization BMCs containing enzymes involved in the degradation of 1,2‐propanediol. BMCs can be designed to enclose heterologous proteins, paving the way to engineered catalytic microreactors. Here, we investigate broader applicability of this design principle by directing three different enzymes to the BMC. We demonstrate that β‐galactosidase, esterase Est5, and cofactor‐dependent glycerol dehydrogenase can be directed to the BMC and copurified with the microcompartment shell in a catalytically active form. We show that the BMC shell protects enzymes from pH‐dependent but not from temperature stress. Moreover, we provide evidence that the heterologously expressed BMCs act as a moderately selective diffusion barrier for lipophilic small molecules.

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Section: Resultsmentioning

confidence: 98%

Engineering bacterial microcompartments with heterologous enzyme cargos

Wagner

Capitain

Richter

et al. 2016

Engineering in Life Sciences

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“…One of these four loci, the GUF locus in D. psychrophila, encodes a PTA_PTB-like PTAC; these are typically associated with only a subset of EUT BMC loci (5). PduL homologs contain an N-terminal EP for encapsulation within the BMC (25). Phylogenetically, the PduL homologs from the same locus type tend to group together and form clades (Fig.…”

Section: Resultsmentioning

confidence: 99%

Bioinformatic Characterization of Glycyl Radical Enzyme-Associated Bacterial Microcompartments

Zarzycki

Erbilgin

Kerfeld

2015

Appl Environ Microbiol

137

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Bacterial microcompartments (BMCs) are proteinaceous organelles encapsulating enzymes that catalyze sequential reactions of metabolic pathways. BMCs are phylogenetically widespread; however, only a few BMCs have been experimentally characterized. Among them are the carboxysomes and the propanediol-and ethanolamine-utilizing microcompartments, which play diverse metabolic and ecological roles. The substrate of a BMC is defined by its signature enzyme. In catabolic BMCs, this enzyme typically generates an aldehyde. Recently, it was shown that the most prevalent signature enzymes encoded by BMC loci are glycyl radical enzymes, yet little is known about the function of these BMCs. Here we characterize the glycyl radical enzyme-associated microcompartment (GRM) loci using a combination of bioinformatic analyses and active-site and structural modeling to show that the GRMs comprise five subtypes. We predict distinct functions for the GRMs, including the degradation of choline, propanediol, and fuculose phosphate. This is the first family of BMCs for which identification of the signature enzyme is insufficient for predicting function. The distinct GRM functions are also reflected in differences in shell composition and apparently different assembly pathways. The GRMs are the counterparts of the vitamin B 12 -dependent propanediol-and ethanolamine-utilizing BMCs, which are frequently associated with virulence. This study provides a comprehensive foundation for experimental investigations of the diverse roles of GRMs. Understanding this plasticity of function within a single BMC family, including characterization of differences in permeability and assembly, can inform approaches to BMC bioengineering and the design of therapeutics. In the last decade, an accumulation of countervailing evidence has overturned the long-held verdict that bacteria are primitive organisms lacking intracellular organization. In addition to membrane-bound organelles like the magnetosomes of magnetotactic bacteria (1, 2) or the anammoxosomes found in some members of the Planctomycetes, bacteria also form protein-based organelles known as bacterial microcompartments (BMCs) (3-5). The defining feature of all BMCs is a shell composed of homologous proteins containing the Pfam00936 domain. A protein with a single copy of the Pfam00936 domain that forms hexamers is referred to as BMC-H; a second type of shell protein consists of a fusion of two Pfam00936 domains and forms pseudohexameric trimers and is referred to as BMC-T. The hexamers and pseudohexamers are thought to tile into the facets of the shell (3, 6). A third type of shell protein containing the Pfam03319 domain forms pentamers that are assumed to cap the vertices of an apparently icosahedral shell and is referred to as BMC-P (3, 7). The BMC-H, BMC-T, and BMC-P oligomers are typically perforated by pores, through which metabolite exchange with the cytosol is assumed to be mediated. Residues flanking the pores are generally polar and well conserved among orthologs, and mutation of the residu...

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“…Notably, the amino acid sequence of the AldDH can be used to independently reconstruct BMC phylogeny 6, 8 . An alcohol dehydrogenase and a phosphotransacylase (either a PduL-like/pfam06130 50,85 PTAC, which is found mostly associated with BMCs or a EutD-like/pfam01515 86 PTAC, a type that is ubiquitous and often referred to as housekeeping) recycle the NAD + and the CoA cofactors (Figure 1B). …”

Section: The Functional Diversity Of Bmcsmentioning

confidence: 99%

Bacterial microcompartments

et al. 2018

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Bacterial microcompartments (BMCs) are self-assembling organelles that consist of an enzymatic core that is encapsulated by a selectively permeable protein shell. The potential to form BMCs is widespread, found across the Kingdom Bacteria. BMCs have crucial roles in carbon dioxide fixation in autotrophs and the catabolism of organic substrates in heterotrophs. They contribute to the metabolic versatility of bacteria, providing a competitive advantage in specific environmental niches. Although BMCs were first visualized more than sixty years ago, it is mainly in the last decade that progress has been made in understanding their metabolic diversity and the structural basis of their assembly and function. This progress has not only heightened our understanding of their role in microbial metabolism but it is also beginning to enable their use in a variety of applications in synthetic biology. In this Review, we focus on recent insights into the structure, assembly, diversity and function of BMCs.

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The PduL Phosphotransacylase Is Used To Recycle Coenzyme A within the Pdu Microcompartment

Cited by 38 publications

References 49 publications

Engineering bacterial microcompartments with heterologous enzyme cargos

Engineering bacterial microcompartments with heterologous enzyme cargos

Bioinformatic Characterization of Glycyl Radical Enzyme-Associated Bacterial Microcompartments

Bacterial microcompartments

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