24 research outputs found
Cross-talk between catalytic and regulatory elements in a DEAD motor domain is essential for SecA function
SecA, a remarkable nanomachine
Biological cells harbor a variety of molecular machines that carry out mechanical work at the nanoscale. One of these nanomachines is the bacterial motor protein SecA which translocates secretory proteins through the protein-conducting membrane channel SecYEG. SecA converts chemically stored energy in the form of ATP into a mechanical force to drive polypeptide transport through SecYEG and across the cytoplasmic membrane. In order to accommodate a translocating polypeptide chain and to release transmembrane segments of membrane proteins into the lipid bilayer, SecYEG needs to open its central channel and the lateral gate. Recent crystal structures provide a detailed insight into the rearrangements required for channel opening. Here, we review our current understanding of the mode of operation of the SecA motor protein in concert with the dynamic SecYEG channel. We conclude with a new model for SecA-mediated protein translocation that unifies previous conflicting data
Nucleotide and Phospholipid-Dependent Control of PPXD and C-Domain Association for SecA ATPase
The formation of new nucleoli during macronuclear development of the hypotrichous ciliate Stylonychia lemnae visualized by in situ hybridization
Maercker C, Harjes P, Neben M, Niemann H, Sianidis G, Lipps HJ. The formation of new nucleoli during macronuclear development of the hypotrichous ciliate Stylonychia lemnae visualized by in situ hybridization. Chromosome Res. 1997;5(5):333-335
Preprotein-controlled catalysis in the helicase motor of SecA
The cornerstone of the functionality of almost all motor proteins is the regulation of their activity by binding interactions with their respective substrates. In most cases, the underlying mechanism of this regulation remains unknown. Here, we reveal a novel mechanism used by secretory preproteins to control the catalytic cycle of the helicase âDEAD' motor of SecA, the preprotein translocase ATPase. The central feature of this mechanism is a highly conserved salt-bridge, Gate1, that controls the opening/closure of the nucleotide cleft. Gate1 regulates the propagation of binding signal generated at the Preprotein Binding Domain to the nucleotide cleft, thus allowing the physical coupling of preprotein binding and release to the ATPase cycle. This relay mechanism is at play only after SecA has been previously âprimed' by binding to SecYEG, the transmembrane protein-conducting channel. The Gate1-controlled relay mechanism is essential for protein translocase catalysis and may be common in helicase motors