Contribution of dppA to urease activity in Helicobacter pylori 26695

BACKGROUND: The gastric pathogen Helicobacter pylori produces urease in amounts up to 10% of its cell protein. This enzyme, which catalyzes the hydrolysis of urea to ammonia and carbon dioxide, protects the bacterium from gastric acid. Urease, a nickel metalloenzyme, requires active uptake of nickel ions from the environment to maintain its activity. NixA is a nickel transport protein that resides in the cytoplasmic membrane. Mutation of nixA significantly reduces but does not abolish urease activity, strongly suggesting the presence of a second transporter. We postulated that the dipeptide permease (dpp) genes that are homologous to the nik operon of Escherichia coli could be a second nickel transporter. The predicted Dpp polypeptides DppA, DppC, and DppD of H. pylori share approximately 40%, 53%, and 56% amino acid sequence identity with their respective E. coli homologs. METHODS: A mutation in dppA, constructed by insertional inactivation with a chloramphenicol resistance cassette, was introduced by allelic exchange into H. pylori strain 26695. RESULTS: When compared to the parental strain, urease activity was not decreased in a dppA mutant. CONCLUSIONS: DppA does not contribute to the synthesis of catalytically active urease in H. pylori 26695 and is likely not a nickel importer in H. pylori.     

Conserved low-affinity nickel-binding amino acids are essential for the function of the nickel permease NixA of Helicobacter pylori

Nickel acquisition is necessary for urease activity, a major virulence factor of the human gastric pathogen Helicobacter pylori. The nickel permease NixA of H. pylori is a member of the single-component nickel-cobalt transporter family. To identify functionally relevant amino acids of NixA, single-site exchanges were introduced into NixA via PCR-based mutagenesis. This study investigated one of the recognition motifs for this family in transmembrane segment III and other conserved amino acids, mostly with possible nickel-binding capacities. The mutant alleles were expressed in Escherichia coli, and activity of the altered permeases was analyzed by measuring nickel accumulation and urease activity. Expression was checked by immunoblotting after sodium dodecyl sulfate-polyacrylamide gel electrophoresis with a NixA-specific antibody. Replacement of Phe-75 and His-79-both part of the characteristic sequence motif-and of Asn-127, Thr-195, and Ser-197 with alanine abolished nickel uptake in the E. coli system. The results were unchanged if these amino acids were replaced with residues more similar to the original amino acid. The phenotype of the null mutants was independent of the culture medium. Mutation of Val-82, Tyr-242, Thr-260, His-181, and His-15 strongly affected uptake activity under nickel limitation on complex Luria-Bertani medium but had little effect in minimal medium. Eight other conserved amino acids (Ser-80, Ser-81, Phe-119, Trp-180, Tyr-183, Trp-244, Pro-249, and Asn-256) were found to be dispensable for the function of NixA. These results show that atypical nickel-binding amino acids play an important function in nickel uptake and that most of the essential amino acids are clustered in conserved motifs.     

Novel nickel transport mechanism across the bacterial outer membrane energized by the TonB/ExbB/ExbD machinery

Nickel is a cofactor for various microbial enzymes, yet as a trace element, its scavenging is challenging. In the case of the pathogen Helicobacter pylori, nickel is essential for the survival in the human stomach, because it is the cofactor of the important virulence factor urease. While nickel transport across the cytoplasmic membrane is accomplished by the nickel permease NixA, the mechanism by which nickel traverses the outer membrane (OM) of this Gram-negative bacterium is unknown. Import of iron-siderophores and cobalamin through the bacterial OM is carried out by specific receptors energized by the TonB/ExbB/ExbD machinery. In this study, we show for the first time that H. pylori utilizes TonB/ExbB/ExbD for nickel uptake in addition to iron acquisition. We have identified the nickel-regulated protein FrpB4, homologous to TonB-dependent proteins, as an OM receptor involved in nickel uptake. We demonstrate that ExbB/ExbD/TonB and FrpB4 deficient bacteria are unable to efficiently scavenge nickel at low pH. This condition mimics those encountered by H. pylori during stomach colonization, under which nickel supply and full urease activity are essential to combat acidity. We anticipate that this nickel scavenging system is not restricted to H. pylori, but will be represented more largely among Gram-negative bacteria.     

Activities of Urease and Nickel Uptake of Helicobacter pylori Proteins are Media- and Host-Dependent

Background:  Nickel-dependent urease activity and nickel supply are essential for successful colonization of Helicobacter pylori in the acidic environment of the human stomach. A comparison of media effects on these two activities have never been carried out. Additionally to H. pylori we cultivated an Escherichia coli strain expressing the urease and the nickel transporter NixA of H. pylori on the same four media and measured in all cases urease and nickel uptake activity.
Aim:  To compare nickel uptake and urease activity on an inter- and intraspecies level.
Results:  In H. pylori nickel uptake (four to 200 times) and urease activities (400 to 30,000 times) were found to be much higher in comparison to the tested E. coli strain after growth on all media. These differences could not be explained by reduced protein amounts in the heterologous host E. coli . On which media the two bacteria extracted most of the nickel were organism-dependent: E. coli on Brucella Broth, H. pylori on Trypticase Soy Broth, and Minimal Media.
Conclusion:  H. pylori took nickel much more efficiently up than E. coli . The observed differences in urease activity are most likely due to additional protein components absent in the recombinant E. coli strain. The observed variety in nickel uptake and urease activities on the different media in the same organism depended on the intrinsic nickel content and chelating capacities of media components. Different culture conditions may lead to varying results; generalizations should be concluded only after excluding their media dependence.     

Helicobacter pylori ABC transporter: effect of allelic exchange mutagenesis on urease activity.

Helicobacter pylori urease requires nickel ions in the enzyme active site for catalytic activity. Nickel ions must, therefore, be actively acquired by the bacterium. NixA (high-affinity nickel transport protein)-deficient mutants of H. pylori retain significant urease activity, suggesting the presence of alternate nickel transporters. Analysis of the nucleotide sequence of the H. pylori genome revealed a homolog of NikD, a component of an ATP-dependent nickel transport system in Escherichia coli. Based on this sequence, a 378-bp DNA fragment was PCR amplified from H. pylori genomic DNA and used as a probe to identify an H. pylori lambda ZAPII genomic library clone that carried these sequences. Four open reading frames of 621, 273, 984, and 642 bp (abcABCD) were revealed by sequencing and predicted polypeptides of 22.7, 9.9, 36.6, and 22.8 kDa, respectively. The 36.6-kDa polypeptide (AbcC) has significant homology (56% amino acid sequence identity) to an E. coli ATP-binding protein component of an ABC transport system, while none of the other putative proteins are significantly homologous to polypeptides in the available databases. To determine the possible contribution of these genes to urease activity, abcC and abcD were each insertionally inactivated with a kanamycin resistance (aphA) cassette and allelic exchange mutants of each gene were constructed in H. pylori UMAB41. Mutation of abcD resulted in an 88% decrease in urease activity to 27 +/- 31 mumol of NH3/min/mg of protein (P < 0.0001), and a double mutant of nixA and abcC resulted in the near abolishment of urease activity (1.1 +/- 1.4 mumol of NH3/min/mg of protein in the double mutant versus 228 +/- 92 mumol of NH3/min/mg of protein in the parent [P < 0.0001]). Synthesis of urease apoenzyme, however, was unaffected by mutations in any of the abc genes. We conclude that the abc gene cluster, in addition to nixA, is involved in production of a catalytically active urease.     

NikR-mediated regulation of Helicobacter pylori acid adaptation

Nickel is the cofactor of the Helicobacter pylori urease enzyme, a factor essential for the chronic colonization of the acidic hostile environment in the human stomach. The NikR regulatory protein directly controls urease expression and regulates the uptake of nickel, and is also able to regulate the expression of other regulatory proteins including the iron-responsive regulator Fur. Through regulatory crosstalk and overlapping regulons, the NikR protein controls the expression of many systems important for colonization and acid adaptation. Despite the paucity of regulatory proteins, this enables H. pylori to optimally adapt to conditions in the stomach, making it one of the most successful human pathogens.     

Nickel-binding and accessory proteins facilitating Ni-enzyme maturation in Helicobacter pylori

Helicobacter pylori colonizes the human gastric mucosa and this can lead to chronic gastritis, peptic and duodenal ulcers, and even gastric cancers. The bacterium colonizes over one-half of the worlds population. Nickel plays a major role in the bacteriums colonization and persistence attributes as two nickel enzyme sinks obligately contain the metal. Urease accounts for up to 10% of the total cellular protein made and is required for initial colonization processes, and the hydrogen oxidizing hydrogenase provides the bacterium a high-energy substrate yielding low potential electrons for energy generation. A battery of accessory proteins are needed for maturation or activation of each of the apoenzymes. These include Ni-chaperones and GTPases, some of which are unique to each Ni-enzyme and others that are individually required for maturation of both the Ni-enzymes. H. pylori’s need for some conventional hydrogenase maturation proteins playing roles in urease maturation may have to do with the poor nickel-sequestering ability of the UreE urease maturation protein compared to other systems. H. pylori also possesses a NixA nickel specific permease, a nickel dependent regulator (NikR), a recently identified nickel efflux system (CznABC), and a histidine-rich heat shock protein, HspA. Based on mutant analysis approaches all these proteins have roles in nickel homeostasis, in urease expression, and in host colonization. The His-rich putative nickel storage proteins Hpn and Hpn-like play roles in nickel detoxification and may influence the levels of Ni-activated urease that can be achieved.     

Helicobacter pylori NikR protein exhibits distinct conformations when bound to different promoters

Helicobacter pylori NikR (HpNikR) is a ribbon-helix-helix (RHH) DNA-binding protein that binds to several different promoter regions. The binding site sequences are not absolutely conserved. The ability of HpNikR to discriminate specific DNA sites resides partly in its nine-amino acid N-terminal arm. Previously, indirect evidence indicated that the arm exists in different conformations when HpNikR is bound to the nixA and ureA promoters. Here, we directly examined HpNikR conformation when it was bound to nixA and ureA DNA fragments by tethering (S)-1{[bis(carboxymethyl)amino]methyl}-2-{4-[(2-bromoacetyl)amino]phenylethyl}(carboxymethyl)amino]acetic acid, iron(III) to different positions in the N-terminal arm and RHH DNA binding domain. Different cleavage patterns at each promoter directly demonstrated that both the RHH domain and the arm adopt different conformations on the nixA and ureA promoters. Additionally, the two RHH domain dimers of the HpNikR tetramer are in distinct conformations at ureA. Site-directed mutagenesis identified an interchain salt bridge (Lys(48)-Glu(47')) in the RHH domain remote from the DNA binding interface that is required for high affinity binding to ureA but not nixA. Finally, DNA affinity measurements of wild-type HpNikR and a salt bridge mutant (K48A) to hybrid nixA-ureA promoters demonstrated that inverted repeat half-sites, spacers, and flanking DNA are all required for sequence-specific DNA binding by HpNikR. Notably, the spacer region made the largest contribution to DNA affinity. HpNikR exhibits a substantially expanded regulon compared with other NikR proteins. The results presented here provide a molecular basis for understanding regulatory network expansion by NikR as well as other prokaryotic regulatory proteins.