A. Evans scite author profile

The deltaproteobacterium Myxococcus xanthus predates upon members of the soil microbial community by secreting digestive factors and lysing prey cells. Like other Gram-negative bacteria, M. xanthus produces outer membrane vesicles (OMVs), and we show here that M. xanthus OMVs are able to kill Escherichia coli cells. The OMVs of M. xanthus were found to contain active proteases, phosphatases, other hydrolases and secondary metabolites. Alkaline phosphatase activity was found to be almost exclusively associated with OMVs, implying that there is active targeting of phosphatases into OMVs, while other OMV components appear to be packaged passively. The kinetic properties of OMV alkaline phosphatase suggest that there may have been evolutionary adaptation of OMV enzymes to a relatively indiscriminate mode of action, consistent with a role in predation. In addition, the observed regulation of production, and fragility of OMV activity, may protect OMV-producing cells from exploitation by M. xanthus cheating genotypes and/or other competitors. Killing of E. coli by M. xanthus OMVs was enhanced by the addition of a fusogenic enzyme (glyceraldehyde-3-phosphate dehydrogenase; GAPDH), which triggers fusion of vesicles with target membranes within eukaryotic cells. This suggests that the mechanism of prey killing involves OMV fusion with the E. coli outer membrane. M. xanthus secretes GAPDH, which could potentially modulate the fusion of co-secreted OMVs with prey organisms in nature, enhancing their predatory activity.

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Efficient Bacterial Export of a Eukaryotic Cytoplasmic Cytochrome

Karim

Kaderbhai

Evans

et al. 1993

Nat Biotechnol

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The soluble core domain of cytochrome b5 of liver endoplasmic reticulum was appended at its amino terminus to full-length alkaline phosphatase secretory signal sequence including the ribosomal binding site. The chimeric precursor gene was placed under the transcriptional control of the native pho promoter in a prokaryotic expression vector. Induction of Escherichia coli by growth in a phosphate-limited medium resulted in abundant synthesis of cytochrome b5 as detected spectrophotometrically and by visual transformation of the bacteria to a pink color. The signal-appended cytochrome b5, but not the corresponding signal-deficient derivative, was translocated across the bacterial inner membrane and processed to yield authentic, haem-assembled cytochrome b5 within the periplasm. The eventual processing of the chimeric cytochrome b5 precursor was unusual regarding the known reaction specificity of signal peptidase. The exported, mature haemoprotein was biochemically indistinguishable from its native mammalian counterpart. At peak induction, approximately 6 mg of correctly matured cytochrome b5 per liter of culture was exported. This amount of cytochrome b5 constituted 6% (w/w) of the periplasmic protein. The appearance of the exported apo-cytochrome b5 preceded the formation of holo-protein. Thus the eukaryotic cytoplasmic protein was efficiently exported from E. coli and post-translocationally modified to generate a functional haemoprotein in the periplasm.

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Processing of chimeric mammalian cytochrome b5 precursors in Escherichia coli: reaction specificity of signal peptidase and identification of an aminopeptidase in post-translocational processing

Harding

Karim

Kaderbhai

et al. 1993

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A chimeric precursor interlinked by an arginine residue between the full-length signal sequence of alkaline phosphatase and the eukaryotic cytoplasmic cytochrome b5 was constructed. Expression of the chimeric precursor protein in Escherichia coli resulted in efficient export of spectrally authentic cytochrome b5 into the periplasm [Karim, Harding, Evans, Kaderbhai and Kaderbhai (1993) Bio/Technology 11, 612-618]. On sequencing, the apparent absence of arginine at the N-terminus of the secreted cytochrome b5 implied that the chimera was either miscleaved by signal peptidase or further processed following signal excision by an uncharacterized peptidase. The influence of the N-terminal region of cytochrome b5 on the unusual processing of the chimeric precursor was investigated by engineering a number of variant forms in which the region between Arg+1 and the mature portion of cytochrome b5 was extended and varied. Observations of the in vivo processed patterns of these variant cytochrome b5 forms exported into the periplasm revealed that the absence of arginine was due to neither miscleavage of the translocated precursor by the signal peptidase nor the nature of the early region of cytochrome b5. In fact, the selective excision of the arginine residue occurred subsequent to signal sequence deletion by an aminopeptidase which was sensitive to the metal chelator o-phenanthroline. We show that this aminopeptidase also participates in the trimming of the N-terminal arginine residue of the bacterial alkaline phosphatase to generate the three isoenzymes in the periplasm.

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A. Evans

Predatory activity of Myxococcus xanthus outer-membrane vesicles and properties of their hydrolase cargo

Efficient Bacterial Export of a Eukaryotic Cytoplasmic Cytochrome

Processing of chimeric mammalian cytochrome b5 precursors in Escherichia coli: reaction specificity of signal peptidase and identification of an aminopeptidase in post-translocational processing

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