Identification of putative substrates for the periplasmic chaperone YfgM in Escherichia coli using quantitative proteomics

Publication date

2015-01-01

Authors

Götzke, Hansjörg
Muheim, Claudio
Altelaar, MaartenORCID 0000-0001-5093-5945ISNI 0000000393438329
Heck, Albert J RORCID 0000-0002-2405-4404ISNI 0000000393921118
Maddalo, GianlucaISNI 000000011975066X
Daley, Daniel O.

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Document Type

Article
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cc_by

Abstract

How proteins are trafficked, folded, and assembled into functional units in the cell envelope of Gram-negative bacteria is of significant interest. A number of chaperones have been identified, however, the molecular roles of these chaperones are often enigmatic because it has been challenging to assign substrates. Recently we discovered a novel periplasmic chaperone, called YfgM, which associates with PpiD and the SecYEG translocon and operates in a network that contains Skp and SurA. The aim of the study presented here was to identify putative substrates of YfgM. We reasoned that substrates would be incorrectly folded or trafficked when YfgM was absent from the cell, and thus more prone to proteolysis (the loss-of-function rationale). We therefore used a comparative proteomic approach to identify cell envelope proteins that were lower in abundance in a strain lacking yfgM, and strains lacking yfgM together with either skp or surA. Sixteen putative substrates were identified. The list contained nine inner membrane proteins (CusS, EvgS, MalF, OsmC, TdcB, TdcC, WrbA, YfhB, and YtfH) and seven periplasmic proteins (HdeA, HdeB, AnsB, Ggt, MalE, YcgK, and YnjE), but it did not include any lipoproteins or outer membrane proteins. Significantly, AnsB (an asparaginase) and HdeB (a protein involved in the acid stress response), were lower in abundance in all three strains lacking yfgM. For both genes, we ruled out the possibility that they were transcriptionally down-regulated, so it is highly likely that the corresponding proteins are misfolded/mistargeted and turned-over in the absence of YfgM. For HdeB we validated this conclusion in a pulse-chase experiment. The identification of HdeB and other cell envelope proteins as potential substrates will be a valuable resource for follow-up experiments that aim to delineate molecular the function of YfgM.

Keywords

asparaginase, chaperone, envelope protein, Escherichia coli protein, lipoprotein, membrane protein, outer membrane protein, periplasmic protein, protein AnsB, protein CusS, protein EvgS, protein Ggt, protein HdeA, protein HdeB, protein MalE, protein MalF, protein OsmC, protein TdcB, protein TdcC, protein WrbA, protein YcgK, protein YfgM, protein YfhB, protein YnjE, protein YtfH, unclassified drug, article, bacterial gene, bacterial strain, controlled study, Escherichia coli, inner membrane, liquid chromatography, loss of function mutation, nonhuman, protein analysis, protein degradation, protein expression, protein folding, protein metabolism, quantitative analysis, structural proteomics, tandem mass spectrometry

Citation

Götzke, H, Muheim, C, Altelaar, A F M, Heck, A J R, Maddalo, G & Daley, D O 2015, 'Identification of putative substrates for the periplasmic chaperone YfgM in Escherichia coli using quantitative proteomics', Molecular & Cellular Proteomics, vol. 14, no. 1, pp. 216-226. https://doi.org/10.1074/mcp.M114.043216