AI Article Synopsis
- All living cells have mechanisms to target proteins to their surfaces, with eukaryotes using signal sequences and sorting signals for this process.
- In bacteria, such as Streptococcus pyogenes, N-terminal signal sequences help direct the secretion of surface proteins like M protein and PrtF to specific areas within the cell.
- This research reveals that these signal sequences not only facilitate secretion but also contain information that can direct proteins to specific subcellular locations, highlighting a new complexity in how proteins are managed in cells.
Article Abstract
All living cells require specific mechanisms that target proteins to the cell surface. In eukaryotes, the first part of this process involves recognition in the endoplasmic reticulum of amino-terminal signal sequences and translocation through Sec translocons, whereas subsequent targeting to different surface locations is promoted by internal sorting signals. In bacteria, N-terminal signal sequences promote translocation across the cytoplasmic membrane, which surrounds the entire cell, but some proteins are nevertheless secreted in one part of the cell by poorly understood mechanisms. Here we analyse localized secretion in the Gram-positive pathogen Streptococcus pyogenes, and show that the signal sequences of two surface proteins, M protein and protein F (PrtF), direct secretion to different subcellular regions. The signal sequence of M protein promotes secretion at the division septum, whereas that of PrtF preferentially promotes secretion at the old pole. Our work therefore shows that a signal sequence may contain information that directs the secretion of a protein to one subcellular region, in addition to its classical role in promoting secretion. This finding identifies a new level of complexity in protein translocation and emphasizes the potential of bacterial systems for the analysis of fundamental cell-biological problems.
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