RESUMO
Production of soluble proteins is essential for structure/function studies, however, this usually requires milligram amounts of protein, which can be difficult to obtain with traditional expression systems. Recently, the Gram-negative bacterium Vibrio natriegens appeared as a novel and alternative host platform for production of proteins in high yields. Here, we used a commercial strain derived from V. natriegens (Vmax™ X2) to produce soluble bacterial and fungal proteins in milligram scale, which we struggled to achieve in Escherichia coli. These proteins include the cholera toxin (CT) and N-acetyl glucosamine binding protein A (GbpA) from Vibrio cholerae, the heat-labile enterotoxin (LT) from E. coli and the fungal nematotoxin CCTX2 from Coprinopsis cinerea. CT, GbpA and LT are secreted by the Type II secretion system in their natural hosts. When these three proteins were produced in Vmax, they were also secreted, and could be recovered from the growth media. This simplified the downstream purification procedure and resulted in considerably higher protein yields compared to production in E. coli (6- to 26-fold increase). We also tested Vmax for protein deuteration using deuterated minimal media with deuterium oxide as solvent, and achieved a 3-fold increase in yield compared to the equivalent protocol in E. coli. This is good news since isotopic labeling is expensive and often ineffective, but represents a necessary prerequisite for some structural techniques. Thus, Vmax represents a promising host for production of challenging expression targets and for protein deuteration in amounts suitable for structural biology studies.
RESUMO
The cytolethal distending toxins (CDTs) produced by many Gram-negative pathogens are tripartite genotoxins with a single catalytic subunit (CdtB) and two cell-binding subunits (CdtA + CdtC). CDT moves by vesicle carriers from the cell surface to the endosomes and through the Golgi apparatus en route to the endoplasmic reticulum (ER). CdtA dissociates from the rest of the toxin before reaching the Golgi apparatus, and CdtB separates from CdtC in the ER. The free CdtB subunit, which is only active after holotoxin disassembly, then crosses the ER membrane and enters the nucleus where it generates DNA breaks. We hypothesized that the acidified lumen of the endosomes is responsible for separating CdtA from the CdtB/CdtC heterodimer. To test this prediction, possible acid-induced disruptions to the CDT holotoxin were monitored by size exclusion chromatography and surface plasmon resonance. We found that CDT could not efficiently assemble from its individual subunits at the early endosome pH of 6.3. Partial disassembly of the CDT holotoxin also occurred at pH 6.3, with complete separation of CdtA from an intact CdtB/CdtC heterodimer occurring at both pH 6.0 and the late endosome pH of 5.6. Acidification caused the precipitation of CdtA at pH 6.5 and below, but neither CdtB nor CdtC were affected by a pH as low as 5.2. Circular dichroism further showed that the individual CdtB subunit adopts a different secondary structure as compared to its structure in the holotoxin. We conclude the first stage of CDT disassembly occurs in the early endosomes, where an acid-induced alteration to CdtA releases it from the CdtB/CdtC heterodimer.
