- Volume 159, Issue Pt_8, 2013
Volume 159, Issue Pt_8, 2013
- Physiology and Biochemistry
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Three functional β-carbonic anhydrases in Pseudomonas aeruginosa PAO1: role in survival in ambient air
Bacterial β-class carbonic anhydrases (CAs) are zinc metalloenzymes catalysing reversible hydration of CO2. They maintain the intracellular balance of CO2/bicarbonate required for biosynthetic reactions and represent a new group of antimicrobial drug targets. Genome sequence analysis of Pseudomonas aeruginosa PAO1, an opportunistic human pathogen causing life threatening infections, identified three genes, PAO102, PA2053 and PA4676, encoding putative β-CAs that share 28–45 % amino acid sequence identity and belong to clades A and B. The genes are conserved among all sequenced pseudomonads. The CAs were cloned, heterologously expressed and purified. Metal and enzymic analyses confirmed that the proteins contain Zn2+ and catalyse hydration of CO2 to bicarbonate. PAO102 (psCA1) was 19–26-fold more active, and together with PA2053 (psCA2) showed CA activity at both pH 7.5 and 8.3, whereas PA4676 (psCA3) was active only at pH 8.3. Circular dichroism spectroscopy suggested that psCA2 and psCA3 undergo pH-dependent structural changes. Taken together, the data suggest that psCA1 may belong to type I and psCA3 to type II β-CAs. Immunoblot analysis showed that all three CAs are expressed in PAO1 cells when grown in ambient air and at 5 % CO2; psCA1 appeared more abundant under both conditions. Growth studies of transposon mutants showed that the disruption of psCA1 impaired PAO1 growth in ambient air and caused a minor defect at high CO2. Thus, psCA1 contributes to the adaptation of P. aeruginosa to low CO2 conditions and will be further studied for its role in virulence and as a potential antimicrobial drug target in this organism.
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Function of formate dehydrogenases in Desulfovibrio vulgaris Hildenborough energy metabolism
The genome of the sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough encodes three formate dehydrogenases (FDHs), two of which are soluble periplasmic enzymes (FdhAB and FdhABC3) and one that is periplasmic but membrane-associated (FdhM). FdhAB and FdhABC3 were recently shown to be the main enzymes present during growth with lactate, formate or hydrogen. To address the role of these two enzymes, ΔfdhAB and ΔfdhABC3 , mutants were generated and studied. Different phenotypes were observed in the presence of either molybdenum or tungsten, since both enzymes were important for growth on formate in the presence of Mo, whereas in the presence of W only FdhAB played a role. Both ΔfdhAB and ΔfdhABC3 mutants displayed defects in growth with lactate and sulfate providing the first direct evidence for the involvement of formate cycling under these conditions. In support of this mechanism, incubation of concentrated cell suspensions of the mutant strains with lactate and limiting sulfate also gave elevated formate concentrations, as compared to the wild-type strain. In contrast, both mutants grew similarly to the wild-type with H2 and sulfate. In the absence of sulfate, the wild-type D. vulgaris cells produced formate when supplied with H2 and CO2, which resulted from CO2 reduction by the periplasmic FDHs. The conversion of H2 and CO2 to formate allows the reversible storage of reducing power in a much more soluble molecule. Furthermore, we propose this may be an expression of the ability of some sulfate-reducing bacteria to grow by hydrogen oxidation, in syntrophy with organisms that consume formate, but are less efficient in H2 utilization.
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The methylotrophic Bacillus methanolicus MGA3 possesses two distinct fructose 1,6-bisphosphate aldolases
More LessThe thermotolerant Gram-positive methylotroph Bacillus methanolicus is able to grow with methanol, glucose or mannitol as a sole carbon and energy source. Fructose 1,6-bisphosphate aldolase (FBA), a key enzyme of glycolysis and gluconeogenesis, is encoded in the genome of B. methanolicus by two putative fba genes, the chromosomally located fbaC and fbaP on the naturally occurring plasmid pBM19. Their amino acid sequences share 75 % identity and suggest a classification as class II aldolases. Both enzymes were purified from recombinant Escherichia coli and were found to be active as homotetramers. Both enzymes were activated by either manganese or cobalt ions, and inhibited by ADP, ATP and EDTA. The kinetic parameters allowed us to distinguish the chromosomally encoded FBAC from the plasmid encoded FBAP, since FBAC showed higher affinity towards fructose 1,6-bisphosphate (K m of 0.16±0.01 mM as compared to 2±0.08 mM) as well as higher glycolytic catalytic efficiency (31.3 as compared to 0.8 s−1 mM−1) than FBAP. However, FBAP exhibited a higher catalytic efficiency in gluconeogenesis (50.4 as compared to 1.4 s−1 mM−1 with dihydroxyacetone phosphate and 4 as compared to 0.4 s−1 mM−1 with glyceraldehyde 3-phosphate as limiting substrate). The aldolase-negative Corynebacterium glutamicum mutant Δfda could be complemented with both FBA genes from B. methanolicus. Based on the kinetic data, we propose that FBAC acts as major aldolase in glycolysis, whereas FBAP acts as major aldolase in gluconeogenesis in B. methanolicus.
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Enterobacterial common antigen and O-specific polysaccharide coexist in the lipopolysaccharide of Yersinia enterocolitica serotype O : 3
Yersinia enterocolitica serotype O : 3 produces two types of lipopolysaccharide (LPS) molecules to its surface. In both types the lipid A (LA) structure is substituted by inner core (IC) octasaccharide to which either outer core (OC) hexasaccharide or homopolymeric O-polysaccharide (OPS) is linked. In addition, enterobacterial common antigen (ECA) can be covalently linked to LPS, however, via an unknown linkage. To elucidate the relationship between ECA and LPS in Y. enterocolitica O : 3 and the effect of temperature on their expression, LPS was isolated from bacteria grown at 22 °C and 37 °C by consequent hot phenol/water and phenol-chloroform-light petroleum extractions to obtain LPS preparations free of ECA linked to glycerophospholipid. In immunoblotting, monoclonal antibodies TomA6 and 898, specific for OPS and ECA, respectively, reacted both with ladder-like bands and with a slower-migrating smear suggesting that the ECA and OPS epitopes coexist on the same molecules. These results were supported by immunoblotting with a monovalent Y. enterocolitica O : 3 ECA-specific rabbit antiserum. Also, two or three 898-positive (and monovalent-positive) TomA6-negative bands migrated at the level of the LA–IC band in LPS samples from certain OC mutants, most likely representing LA–IC molecules carrying 1–3 ECA repeat units but no OPS. These bands were also present in Y. enterocolitica O : 9 OC mutants; however, coexistence of ECA and OPS in the same molecules could not be detected. Finally, the LA–IC–ECA bands were missing from LPS of bacteria grown at 37 °C and also the general reduction in wild-type bacteria of ECA-specific monovalent-reactive material at 37 °C suggested that temperature regulates the expression of ECA. Indeed, RNA-sequencing analysis showed significant downregulation of the ECA biosynthetic gene cluster at 37 °C.
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