Ring-like pore structures of SecA: Implication for bacterial protein-conducting channels

The export of many E. coli proteins such as proOmpA requires the cytosolic chaperone SecB and the membrane-bound preprotein translocase. Translocase is a multisubunit enzyme with the SecA protein as its peripheral membrane domain and the SecY/E protein as its integral domain. SecB, by binding to proOmpA in the cytosol, prevents its aggregation or association with membranes at nonproductive sites. The SecA receptor binds the proOmpA-SecB complex (Kd approximately 6 x 10(-8) M) through direct recognition of both the SecB (Kd approximately 2 x 10(-7) M) as well as the leader and mature domains of the precursor protein. SecB has a dual function in stabilizing the precursor and in passing it on to membrane-bound SecA, the next step in the pathway. SecA itself is bound to the membrane by its affinity (Kd approximately 4 x 10(-8) M) for SecY/E and for acidic lipids. The functions of SecB and SecA as a two-stage receptor system are linked by their affinity for each other.

SecA, the peripheral subunit of E. coli preprotein translocase, alternates between a membrane inserted and a deinserted state as part of the catalytic cycle of preprotein translocation. When SecA is complexed with SecY/E and preprotein, ATP drives a profound conformational change, leading to membrane insertion of a 30 kDa domain of SecA. The inserted domain is protease-inaccessible from the cytosolic side of the membrane, but becomes accessible upon membrane disruption. Concomitant with 30 kDa domain insertion, approximately 20 aminoacyl residues of the preprotein are translocated. Additional ATP, which may be hydrolyzed at the second ATP site of SecA, releases the translocated preprotein and allows the 30 kDa domain to deinsert, whence it can exchange with cytosolic SecA. Thus, SecA is the mobile subunit of an integral membrane transporter, consuming ATP during both the insertion and deinsertion phases of its catalytic cycle while guiding preprotein segments across the membrane.

The ATPase activity of SecA is stimulated by E. coli plasma membrane vesicles bearing SecY protein and a precursor protein such as proOmpA. This activity is termed "translocation ATPase". Liposomes alone can also stimulate SecA ATPase, but membrane proteins block this stimulation in native inner membranes. We define the stimulation of SecA ATPase by lipid as "SecA/lipid ATPase". SecA/lipid ATPase, translocation ATPase, and translocation into inner membrane vesicles require acidic phospholipids, suggesting an underlying unity of mechanism. ProOmpA and ATP stabilize liposome-bound SecA. Full SecA/lipid ATPase activity and stability are also seen when a mixture of a leader peptide and either OmpA or maltose binding protein (MBP) are added instead of proOmpA, while neither the leader peptide alone nor OmpA or MBP suffice. Cytosolic proteins in conjuction with a leader peptide are less active in this reaction, indicating that liposome-bound SecA protein recognizes both leader and mature domains.