Abstract
Monomeric autotransporters have been used extensively to transport recombinant proteins or protein domains to the cell surface of Gram-negative bacteria amongst others for antigen display. Genetic fusion of such antigens into autotransporters has yielded chimeras that can be used for vaccination purposes. However, not every fusion construct is transported efficiently across the cell envelope. Problems occur in particular when the fused antigen attains a relatively complex structure in the periplasm, prior to its translocation across the outer membrane. The latter step requires the interaction with periplasmic chaperones and the BAM (β-barrel assembly machinery) complex in the outer membrane. This complex catalyzes insertion and folding of β-barrel outer membrane proteins, including the β-barrel domain of autotransporters. Here, we investigated whether the availability of periplasmic chaperones or the BAM complex is a limiting factor for the surface localization of difficult-to-secrete chimeric autotransporter constructs. Indeed, we found that overproduction of in particular the BAM complex, increases surface display of difficult-to-secrete chimeras. Importantly, this beneficial effect appeared to be generic not only for a number of monomeric autotransporter fusions but also for fusions to trimeric autotransporters. Therefore, overproduction of BAM might be an attractive strategy to improve the production of recombinant autotransporter constructs.
Highlights
For many biotechnology applications, including recombinant protein production or vaccine development, it is considered an advantage to secrete proteins into the extra-cellular milieu or to display them on the surface of the producing bacteria [18, 19, 36, 54]
We found that overproduction of the β-Barrel assembly machinery (BAM) complex markedly improves surface display of such hemoglobin protease (Hbp) chimeras
Co‐overexpression of the BAM complex improved expression of Hbp-Display constructs (HbpD)‐ELL In earlier studies, we have reported on the limited tolerance of Hbp to transport folded heterologous protein domains across the outer membrane where such DTS constructs showed a decreased secretion efficiency when compared to wild-type Hbp or efficiently-secreted derivatives [13, 16, 41]
Summary
For many biotechnology applications, including recombinant protein production or vaccine development, it is considered an advantage to secrete proteins into the extra-cellular milieu or to display them on the surface of the producing bacteria [18, 19, 36, 54]. Phan et al Microb Cell Fact (2021) 20:176 the type Va subclass, the classical autotransporters, are proteolytically cleaved from their β-barrel domain after which they are released into the extra-cellular milieu or remain bound to the cell surface via non-covalent interactions (see Fig. 1 for the gene organization in classical autotransporters) Despite their apparent simplicity, type V secretion systems secrete some of the largest proteins encoded by bacterial genomes. They function in most cases as adhesin, protease, or toxin to support bacterial virulence [30]
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