Inactivation of the Escherichia coli K-12 twin-arginine translocation system promotes increased hydrogen production.

The effect of deleting the genes encoding the twin-arginine translocation (Tat) system on H2 production by Escherichia coli strain MC4100 and its formate hydrogenlyase upregulated mutant (DeltahycA) was investigated. H2 evolution tests using two mutant strains defective in Tat transport (DeltatatC and DeltatatA-E) showed that the rate doubled from 0.88+/-0.28 mL H2 mg dry weight-1 L culture-1 in the parental strain, to 1.70+/-0.15 and 1.75+/-0.18 mL H2 mg dry weight-1 L culture-1, respectively, in the DeltatatC and DeltatatA-E strains. This increase was comparable to that of a previously characterized hydrogen over-producing E. coli strain carrying a DeltahycA allele. Construction of a tatC, DeltahycA double deletion strain did not increase hydrogen production further. Inactivation of the Tat system prevents correct assembly of the uptake hydrogenases and formate dehydrogenases in the cytoplasmic membrane and it is postulated that the subsequent loss of basal levels of respiratory-linked hydrogen and formate oxidation accounts for the observed increases in formate-dependent hydrogen evolution.

Spontaneous sequence duplications within capsule genes cap8E and tts control phase variation in Streptococcus pneumoniae serotypes 8 and 37.

Capsule phase variants were isolated from serotype 8 and serotype 37 pneumococcal sorbarods. Sequence duplications within the essential capsule genes - cap8E (type 8) and tts (type 37) - were found to introduce frameshifts and generate acapsular phenotypes. Capsular revertants possessed wild-type cap8E and tts genes, indicating the precise excision of these duplications. Reversion frequencies (OFF-ON) fit a linear relationship between log(frequency of reversion) and log(length of duplication), previously found for serotype three pneumococci [Waite, R. D., Struthers, J. K. & Dowson, C. G. (2001). Mol Microbiol 42, 1223-1232]. This study provides evidence that capsule phase variation can occur in pneumococcal serotypes with either simple (one to three genes) or complex capsule-encoding loci (12 genes). Given the key role of CapE (the first monosaccharide transferase) in other clinically important pneumococci, such as serotypes 14 and 19F with complex capsular loci, the observed duplication within cap8E suggests that capsule phase variation could be controlled by tandem sequence duplication in capE homologues in other pneumococcal serotypes that construct their capsules through polymerization of lipid-linked intermediates.