Abstract
Trimeric autotransporter adhesins (TAAs) are a family of bacterial outer membrane (OM) proteins that are comprised of three identical subunits. Each subunit contains an N-terminal extracellular ("passenger") domain and a short C-terminal segment that contributes four β strands to a single 12-stranded β barrel. The mechanism by which the passenger domains are translocated across the OM and the energetics of the translocation reaction are poorly understood. To address these issues, we examined the secretion of modified versions of the passenger domain of UpaG, a TAA produced by Escherichia coli CFT073. Using the SpyTag-SpyCatcher system to probe passenger domain localization, we found that both intrinsically disordered polypeptides fused to the UpaG passenger domain and artificially disulfide-bonded polypeptides were secreted effectively but relatively slowly. Surprisingly, we also found that in some cases, the three nonnative passenger domain segments associated with a single trimer were secreted sequentially. Photo-cross-linking experiments indicated that incompletely assembled UpaG derivatives remained bound to the barrel assembly machinery (Bam) complex until all three passenger domains were fully secreted. Taken together, our results strongly suggest that the secretion of polypeptides through the TAA pathway is coordinated with the assembly of the β barrel domain and that the folding of passenger domains in the extracellular space maximizes the rate of secretion. Furthermore, our work provides evidence for an unprecedented sequential mode of protein translocation, at least under specific experimental conditions.IMPORTANCE Trimeric autotransporter adhesins (TAAs) are specialized bacterial outer membrane proteins consisting of three identical subunits. TAAs contain large extracellular domains that trimerize and promote virulence, but the mechanism by which they are secreted is poorly understood. We found that the extracellular domains of a native TAA were secreted rapidly but that disordered and artificially folded polypeptides fused to native passenger domains were secreted in a slow, sequential fashion. Our results strongly suggest that the efficient secretion of native extracellular domains is driven by their trimerization following export but that alternative energy sources can be harnessed to secrete nonnative polypeptides. Furthermore, we obtained evidence that TAA extracellular domains are secreted before the assembly of the linked membrane spanning domain is completed.
Highlights
Trimeric autotransporter adhesins (TAAs) are a family of bacterial outer membrane (OM) proteins that are comprised of three identical subunits
To gain insight into the mechanism by which the passenger domains of TAAs are transported across the OM, we examined the secretion of both native and modified passenger domain fragments of a TAA produced by E. coli CFT073 (UpaG) in vivo
Given that the accumulation of triply modified STUpaGΔ2 and ST-UpaGΔ2 (S1624C/S1652C) parallels the disappearance of the crosslinking product, these results strongly suggest that the  barrel domain of UpaGΔ2 is released from the barrel assembly machinery (Bam) complex only after the passenger domain translocation reaction has been completed
Summary
Trimeric autotransporter adhesins (TAAs) are a family of bacterial outer membrane (OM) proteins that are comprised of three identical subunits. The Bam complex in Escherichia coli consists of BamA, an integral OMP that contains a  barrel domain, and five periplasmic POTRA (polypeptide transport-associated) domains that mediate interactions with four lipoprotein subunits (BamB to BamE). On the basis of the BamA crystal structure and molecular dynamics simulations, it has been proposed that substrates enter the pore of the  barrel in an unfolded conformation and form hairpins that insert into the lipid bilayer sequentially through a lateral gate produced by the transient separation of the first and last  strands [29] Consistent with this “budding” model, artificial disulfide bonds that lock the BamA  barrel into a closed conformation create lethal phenotypes and inhibit Bam complex function in vitro [28, 30]. Cross-linking experiments have clearly shown that TAA  barrels begin to assemble prior to membrane integration [36]
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