Jyoti Velayudhan scite author profile

The genome sequence of Helicobacter pylori suggests that this bacterium possesses several Fe acquisition systems, including both Fe2+‐ and Fe3+‐citrate transporters. The role of these transporters was investigated by generating insertion mutants in feoB, tonB, fecA1 and fecDE. Fe transport in the feoB mutant was ≈ 10‐fold lower than in the wild type (with 0.5 μM Fe), irrespective of whether Fe was supplied in the Fe2+ or Fe3+ form. In contrast, transport rates were unaffected by the other mutations. Complementation of the feoB mutation fully restored both Fe2+ and Fe3+ transport. The growth inhibition exhibited by the feoB mutant in Fe‐deficient media was relieved by human holo‐transferrin, holo‐lactoferrin and Fe3+‐dicitrate, but not by FeSO4. The feoB mutant had less cellular Fe and was more sensitive to growth inhibition by transition metals in comparison with the wild type. Biphasic kinetics of Fe2+ transport in the wild type suggested the presence of high‐ and low‐affinity uptake systems. The high‐affinity system (apparent Ks = 0.54 μM) is absent in the feoB mutant. Transport via FeoB is highly specific for Fe2+ and was inhibited by FCCP, DCCD and vanadate, indicating an active process energized by ATP. Ferrozine inhibition of Fe2+ and Fe3+ uptake implied the concerted involvement of both an Fe3+ reductase and FeoB in the uptake of Fe supplied as Fe3+. Taken together, the results are consistent with FeoB‐mediated Fe2+ uptake being a major pathway for H. pylori Fe acquisition. feoB mutants were unable to colonize the gastric mucosa of mice, indicating that FeoB makes an important contribution to Fe acquisition by H. pylori in the low‐pH, low‐O2 environment of the stomach.

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l -Serine Catabolism via an Oxygen-Labile l -Serine Dehydratase Is Essential for Colonization of the Avian Gut by Campylobacter jejuni

Velayudhan

et al. 2004

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Campylobacter jejuni is a microaerophilic, asaccharolytic bacterium. The identity of the carbon and energy sources used by C. jejuni in vivo is unknown, but the genome sequence of strain NCTC11168 indicates the presence of genes for catabolism of a limited range of amino acids, including serine. Specific omission of L-serine from a defined medium containing a mixture of amino acids led to a dramatic decrease in cell yields. As C. jejuni does not have a biosynthetic serine requirement, this supports earlier suggestions that L-serine is a preferentially catabolized amino acid. Serine transport was found to be mediated by at least two systems in strain 11168; a high-capacity, low-affinity L-serine-specific system encoded by Cj1625c (sdaC) and a higheraffinity L-serine/L-threonine system responsible for residual L-serine transport in an sdaC mutant. Catabolism of L-serine to pyruvate and ammonia is carried out by SdaA (encoded by Cj1624c), which was overexpressed, purified, and shown to be an oxygen-labile iron-sulfur enzyme. L-Serine dehydratase activity in an sdaA mutant was reduced 10-fold compared to that in the wild type, but the residual activity (due to the anabolic L-threonine dehydratase) could not support either growth on or utilization of L-serine in defined media. However, although sdaA mutants showed no obvious growth defect in complex media, they completely failed to colonize 3-week-old chickens as assayed both by cloacal swabs taken over a 6-week period and by cecal colony counts postmortem. In contrast, the isogenic parent strain colonized chickens to high levels within 1 week of inoculation. The results show that an active SdaA is essential for colonization of the avian gut by C. jejuni and imply that catabolism of L-serine is crucially important for the growth of this bacterium in vivo.

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Analysis of gluconeogenic and anaplerotic enzymes in Campylobacter jejuni: an essential role for phosphoenolpyruvate carboxykinase

2002

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Campylobacter jejuni is unable to utilize glucose as a carbon source due to the absence of the key glycolytic enzyme 6-phosphofructokinase. The genome sequence of C. jejuni NCTC 11168 indicates that homologues of all the appropriate enzymes for gluconeogenesis from phosphoenolpyruvate (PEP) are present, in addition to the anaplerotic enzymes pyruvate carboxylase (PYC), phosphoenolpyruvate carboxykinase (PCK) and malic enzyme (MEZ). Surprisingly, a pyruvate kinase (PYK) homologue is also present. To ascertain the role of these enzymes, insertion mutants in pycA, pycB, pyk and mez were generated. However, this could not be acheived for pckA, indicating that PCK is an essential enzyme in C. jejuni. The lack of PEP synthase and pyruvate orthophosphate dikinase activities confirmed a unique role for PCK in PEP synthesis. The pycA mutant was unable to grow in defined medium with pyruvate or lactate as the major carbon source, thus indicating an important role for PYC in anaplerosis. Sequence and biochemical data indicate that the PYC of C. jejuni is a member of the α 4 β 4 , acetyl-CoA-independent class of PYCs, with a 65 8 kDa subunit containing the biotin moiety. Whereas growth of the mez mutant was comparable to that of the wild-type, the pyk mutant displayed a decreased growth rate in complex medium. Nevertheless, the mez and pyk mutants were able to grow with pyruvate, lactate or malate as carbon sources in defined medium. PYK was present in cell extracts at a much higher specific activity [S 800 nmol min N1 (mg protein) N1 ] than PYC or PCK [T 65 nmol min N1 (mg protein) N1 ], was activated by fructose 1,6-bisphosphate and displayed other regulatory properties strongly indicative of a catabolic role. It is concluded that PYK may function in the catabolism of unidentified substrates which are metabolized through PEP. In view of the high K m of MEZ for malate (" " " 9 mM) and the lack of a growth phenotype of the mez mutant, MEZ seems to have only a minor anaplerotic role in C. jejuni.

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The role of ferritins in the physiology of Salmonella enterica sv. Typhimurium: a unique role for ferritin B in iron‐sulphur cluster repair and virulence

Velayudhan¹,

Castor²,

Richardson³

et al. 2007

Molecular Microbiology

129

111

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Essential Role of Ferritin Pfr in Helicobacter pylori Iron Metabolism and Gastric Colonization

et al. 2002

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The reactivity of the essential element iron necessitates a concerted expression of ferritins, which mediate iron storage in a nonreactive state. Here we have further established the role of the Helicobacter pylori ferritin Pfr in iron metabolism and gastric colonization. Iron stored in Pfr enabled H. pylori to multiply under severe iron starvation and protected the bacteria from acid-amplified iron toxicity, as inactivation of the pfr gene restricted growth of H. pylori under these conditions. The lowered total iron content in the pfr mutant, which is probably caused by decreased iron uptake rates, was also reflected by an increased resistance to superoxide stress. Iron induction of Pfr synthesis was clearly diminished in an H. pylori feoB mutant, which lacked high-affinity ferrous iron transport, confirming that Pfr expression is mediated by changes in the cytoplasmic iron pool and not by extracellular iron. This is well in agreement with the recent discovery that iron induces Pfr synthesis by abolishing Fur-mediated repression of pfr transcription, which was further confirmed here by the observation that iron inhibited the in vitro binding of recombinant H. pylori Fur to the pfr promoter region. The functions of H. pylori Pfr in iron metabolism are essential for survival in the gastric mucosa, as the pfr mutant was unable to colonize in a Mongolian gerbil-based animal model. In summary, the pfr phenotypes observed give new insights into prokaryotic ferritin functions and indicate that iron storage and homeostasis are of extraordinary importance for H. pylori to survive in its hostile natural environment.

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