Abstract
BACKGROUND: Cupriavidus necator has attracted much attention as a platform for the production of polyhydroxyalkanoate (PHA) and other useful materials. Therefore, an appropriate modulation of gene expression is needed for producing the desired materials effectively. However, there is insufficient information on the genetic engineering techniques required for this in C. necator. RESULTS: We found that the disruption of a potential ribosome binding site (RBS) in the phaC1 gene in C. necator caused a small decrease in the PhaC1 expression level. We applied this result to finely regulate the expression of other genes. Several gene expression cassettes were constructed by combining three Escherichia coli derived promoters (P(lacUV5), P(trc) and P(trp)) to the potential RBS of phaC1 or its disruptant, respectively. Their expression levels were then determined via a lacZ reporter assay in C. necator strains. The promoter strengths were both ranked similarly for the cells that were cultured with fructose or palm kernel oil as a sole carbon source (P(trc) ≥ P(lacUV5) > P(trp)), both of which were much stronger than the phaC1 promoter. The disruption of RBS had minute attenuation effect on the expression level of these expression cassettes with E. coli promoters. Furthermore, they were used to finely regulate the (R)-3-hydroxyhexanoate (3HHx) monomer ratio in the production of poly[(R)-3-hydroxybutyrate-co-3-hydroxyhexanoate] (PHBHHx) via R-specific enoyl-CoA hydratases (PhaJs). The 3HHx composition in PHBHHx is crucial because it defines the thermal and mechanical properties of the resulting plastic material. The C. necator mutant strains, whose PhaJ expression was controlled under the gene expression cassettes, could be used to produce PHBHHx with various 3HHx compositions in the same culture conditions. CONCLUSIONS: We constructed and evaluated several gene expression cassettes consisting of promoters and RBSs that finely regulate transcription and translation. These were then applied to finely modulate the monomer composition in the production of PHBHHx by recombinant C. necator.