Abstract
The methylotrophic yeast Pichia pastoris is a popular heterologous expression host for the recombinant production of a variety of prokaryotic and eukaryotic proteins. The rapid emergence of P. pastoris as a robust heterologous expression host was facilitated by the ease with which it can be manipulated and propagated, which is comparable to that of Escherichia coli and Saccharomyces cerevisiae. P. pastoris offers further advantages such as the tightly-regulated alcohol oxidase promoter that is particularly suitable for heterologous expression of foreign genes. While recombinant production of bacterial toxins and their derivatives is highly desirable, attempts at their heterologous expression using the traditional E. coli expression system can be problematic due to the formation of inclusion bodies that often severely limit the final yields of biologically active products. However, recent literature now suggests that P. pastoris may be an attractive alternative host for the heterologous production of bacterial toxins, such as those from the genera Bacillus, Clostridium, and Corynebacterium, as well as their more complex derivatives. Here, we review the recombinant production of bacterial toxins and their derivatives in P. pastoris with special emphasis on their potential clinical applications. Considering that de novo design and construction of synthetic toxin genes have often been necessary to achieve optimal heterologous expression in P. pastoris, we also present general guidelines to this end based on our experience with the P. pastoris expression of the Bacillus thuringiensis Cyt2Aa1 toxin.
Highlights
Despite their crucial roles in vaccine development, therapeutic applications, control of crop pests and disease vectors, as well as in basic research and functional characterization, heterologous expression of bacterial
P. pastoris is a robust recombinant expression host that has seemingly emerged as an alternative heterologous expression host for a variety of bacterial toxins and their derivatives
P. pastoris may be better suited than the E. coli- and S. cerevisiae-based expression systems and it may allow higher yields of biologically active recombinant protein as it can be grown to high cell densities under aerobic conditions
Summary
P. pastoris is a robust recombinant expression host that has seemingly emerged as an alternative heterologous expression host for a variety of bacterial toxins and their derivatives. Secretory targeting is an advantageous strategy for the recombinant production of toxins and/or their derivatives that require proteolytic processing and/or proper disulphide bond-formation for their activity. In this respect, P. pastoris may be better suited than the E. coli- and S. cerevisiae-based expression systems and it may allow higher yields of biologically active recombinant protein as it can be grown to high cell densities under aerobic conditions. A further potential problem that is often encountered during heterologous expression of the bacterial toxins in P. pastoris centers on differences in the codon bias of the A+T-rich prokaryotic toxin genes that can minimize or even preclude the recombinant production of the fulllength proteins. AOX: alcohol oxidase; AOX1: P. pastoris major alcohol oxidase gene; tcp: total cell protein; BoNT and TeNT, botulinum and tetanus neurotoxins, respectively; BoNT(HC) and TeNT(HC), the carboxyl-terminal domain of the heavy chain fragment of the botulinum and tetanus neurotoxins, respectively; LT and CT: the heat-labile E. coli enterotoxin and the V. cholerae toxin, respectively; LTB and CTB: B subunit of the heat-labile E. coli enterotoxin and the V. cholerae toxin, respectively; CHO: Chinese hamster ovary; Cef: cell-elongating factor; IT: immunotoxin; DT: diphtheria toxin; DT390: truncated version of DT corresponding to the first 390 amino acid residues
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