AI Article Synopsis
- VemP is a secretory protein in Vibrio that regulates protein-transport activity by halting its own translation until the downstream secD2-secF2 genes, necessary for protein translocation, can be expressed.
- When protein-transport functions are operating efficiently, VemP's translation arrest is quickly canceled through its interaction with the SecY/E/G translocon, requiring specific trans factors and a critical cis element, Arg-85.
- The study identifies how VemP accurately monitors the function of SecD/F, revealing key elements that affect the stability and regulation of VemP's translation arrest via interactions at the SecY pore.
Article Abstract
VemP is a secretory protein in the Vibrio species that monitors cellular protein-transport activity through its translation arrest, allowing expression of the downstream secD2-secF2 genes in the same operon, which encode components of the protein translocation machinery. When cellular protein-transport function is fully active, secD2/F2 expression remains repressed as VemP translation arrest is canceled immediately. The VemP arrest cancellation occurs on the SecY/E/G translocon in a late stage in the translocation process and requires both trans factors, SecD/F and PpiD/YfgM, and a cis element, Arg-85 in VemP; however, the detailed molecular mechanism remains elusive. This study aimed to elucidate how VemP passing through SecY specifically monitors SecD/F function. Genetic and biochemical studies showed that SecY is involved in the VemP arrest cancellation and that the arrested VemP is stably associated with a specific site in the protein-conducting pore of SecY. VemP-Bla reporter analyses revealed that a short hydrophobic segment adjacent to Arg-85 plays a critical role in the regulated arrest cancellation with its hydrophobicity correlating with the stability of the VemP arrest. We identified Gln-65 and Pro-67 in VemP as novel elements important for the regulation. We propose a model for the regulation of the VemP arrest cancellation by multiple cis elements and trans factors with different roles.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC11470409 | PMC |
| http://dx.doi.org/10.1016/j.jbc.2024.107735 | DOI Listing |
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Article Synopsis
- VemP is a secretory protein in Vibrio that regulates protein-transport activity by halting its own translation until the downstream secD2-secF2 genes, necessary for protein translocation, can be expressed.
- When protein-transport functions are operating efficiently, VemP's translation arrest is quickly canceled through its interaction with the SecY/E/G translocon, requiring specific trans factors and a critical cis element, Arg-85.
- The study identifies how VemP accurately monitors the function of SecD/F, revealing key elements that affect the stability and regulation of VemP's translation arrest via interactions at the SecY pore.
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