Tetanus Toxin Synthesis is Under the Control of A Complex Network of Regulatory Genes in Clostridium tetani.

Clostridium tetani produces a potent neurotoxin, the tetanus toxin (TeNT), which is responsible for an often-fatal neurological disease (tetanus) characterized by spastic paralysis. Prevention is efficiently acquired by vaccination with the TeNT toxoid, which is obtained by C.tetani fermentation and subsequent purification and chemical inactivation. C.tetani synthesizes TeNT in a regulated manner. Indeed, the TeNT gene (tent) is mainly expressed in the late exponential and early stationary growth phases. The gene tetR (tetanus regulatory gene), located immediately upstream of tent, encodes an alternative sigma factor which was previously identified as a positive regulator of tent. In addition, the genome of C.tetani encodes more than 127 putative regulators, including 30 two-component systems (TCSs). Here, we investigated the impact of 12 regulators on TeNT synthesis which were selected based on their homology with related regulatory elements involved in toxin production in other clostridial species. Among nine TCSs tested, three of them impact TeNT production, including two positive regulators that indirectly stimulate tent and tetR transcription. One negative regulator was identified that interacts with both tent and tetR promoters. Two other TCSs showed a moderate effect: one binds to the tent promoter and weakly increases the extracellular TeNT level, and another one has a weak inverse effect. In addition, CodY (control of dciA (decoyinine induced operon) Y) but not Spo0A (sporulation stage 0) or the DNA repair protein Mfd (mutation frequency decline) positively controls TeNT synthesis by interacting with the tent promoter. Moreover, we found that inorganic phosphate and carbonate are among the environmental factors that control TeNT production. Our data show that TeNT synthesis is under the control of a complex network of regulators that are largely distinct from those involved in the control of toxin production in Clostridium botulinum or Clostridium difficile.

Biochemical characterisation of recombinant Streptomyces pristinaespiralis L-lysine cyclodeaminase.

L-Lysine cyclodeaminase from Streptomyces pristinaespiralis was heterologously expressed in Escherichia coli, isolated to 90% purity after two purification steps and characterised. The size of the isolated recombinant enzyme was in agreement with the theoretical size calculated from the corresponding gene. We demonstrated that our preparation converts L-lysine to L-pipecolic acid (enantiomeric excess >95%) after isolating and identifying the conversion product by LC/MS, NMR and IR. This conversion followed Michaelis-Menten kinetics with a K(m) of 1.39+/-0.32 mM. The enzyme activity was maximal at pH 6.7. Reducing conditions, the presence of glycerol and in particular the presence of iron(II) significantly enhanced the L-lysine cyclodeaminase activity. Although the heat stability of the enzyme diminished significantly after 37 degrees C, the initial rate of reaction was maximal at 61 degrees C. We found no requirement for an external cofactor for full activity, although sequence data indicate NAD+ as cofactor. Upon enzyme denaturation, NAD+ release was observed, which indicates very tight binding of NAD+ to the enzyme. In parallel we developed selection and screening assays for lysine cyclodeaminase, which we adapted to microtitre plate format and validated. Among twenty-eight lysine analogues screened for turnover/binding to the enzyme, three were identified as substrates (L-ornithine, 5-hydroxylysine and L-4-thialysine), while another six (4-azalysine, L-2,4-diaminobutyric acid, 1,5-diaminopentane, N-epsilon-trifluoroacetyl-L-lysine, N-epsilon-Boc-L-lysine and N-epsilon-methyl-L-lysine) were shown to compete against L-lysine turnover without being converted by the enzyme. All substrates displayed Michaelis-Menten kinetics upon turnover by lysine cyclodeaminase. Our results indicate that the lysine cyclodeaminase from Streptomyces pristinaespiralis is a highly enantioselective enzyme at the substrate recognition and conversion levels, in both cases in favour of the l-isomer.

Anaerobic pathways of glycerol dissimilation by Enterobacter agglomerans CNCM 1210: limitations and regulations.

Continuous cultures of Enterobacter agglomerans CNCM 1210 were performed under regulated pH conditions (pH 7.0) with glycerol or glucose (20 g l-1) as carbon source. Cultures grown on glucose produced mainly acetate, ethanol and formate. In contrast, 1,3-propanediol (PPD) was the main product with glycerol. The carbon flow distribution at branching metabolic points was investigated. Higher PPD yields with increased dilution rate were correlated with an important increase in the relative ratio of glycerol dehydratase to glycerol dehydrogenase. Determination of intracellular triose-phosphate and fructose 1,6-biphosphate concentrations demonstrated that glyceraldehyde-3-phosphate dehydrogenase is the limiting step in glycerol dissimilation. At the pyruvate branching point, pyruvate dehydrogenase (PDH) activity was systematically detected. The pyruvate flow shifted to PDH is suspected to represent up to 22% of the acetyl-CoA formed. In addition, this enzyme pattern combined with the enhanced in vivo lactate dehydrogenase activity at high growth rates, was correlated with a decrease in the pyruvate formate-lyase activity. A regulation of this latter enzyme by the accumulation of triose-phosphate is suspected.