Differentiation of H. pylori Strains Using PCR RFLP.

Helicobacter pylori strains have been shown to display considerable heterogeneity with respect to DNA sequence. Diverse restriction fragment length polymorphism (RFLP) patterns are generated among strains by restriction endonuclease digestion of whole chromosomal DNA (1-3), digestion of specific polymerase chain reaction (PCR) products (4), or arbitrary primer-PCR and random amplified polymorphic DNA-PCR (5-7). These techniques demonstrate numerous distinct and reproducible patterns that can be used to differentiate strains. Sequence analyses of specific genes have confirmed that there are frequent nucleotide substitutions among strains, usually in the third position of codons, which may not result in amino acid substitution within the corresponding polypeptides (8). This type of heterogeneity is found in all H. pylori strains, whether they are considered virulent or nonvirulent.

Proteus mirabilis urease: transcriptional regulation by UreR.

Proteus mirabilis urease catalyzes the hydrolysis of urea, initiating the formation of urinary stones. The enzyme is critical for kidney colonization and the development of acute pyelonephritis. Urease is induced by urea and is not controlled by the nitrogen regulatory system (ntr) or catabolite repression. Purified whole-cell RNA from induced and uninduced cultures of P. mirabilis and Escherichia coli harboring cloned urease sequences was probed with a 4.2-kb BglI fragment from within the urease operon. Autoradiographs of slot blots demonstrated 4.2- and 5.8-fold increases, respectively, in urease-specific RNA upon induction with urea. Structural and accessory genes necessary for urease activity, ureD, A, B, C, E, and F, were previously cloned and sequenced (B. D. Jones and H. L. T. Mobley, J. Bacteriol. 171:6414-6422, 1989). A 1.2-kb EcoRV-BamHI restriction fragment upstream of these sequences confers inducibility upon the operon in trans. Nucleotide sequencing of this fragment revealed a single open reading frame of 882 nucleotides, designated ureR, which is transcribed in the direction opposite that of the urease structural and accessory genes and encodes a 293-amino-acid polypeptide predicted to be 33,415 Da in size. Autoradiographs of sodium dodecyl sulfate-polyacrylamide gels of [35S]methionine-labeled polypeptides obtained by in vitro transcription-translation of the PCR fragments carrying only ureR yielded a single band with an apparent molecular size of 32 kDa. Fragments carrying an in-frame deletion within ureR synthesized a truncated product. The predicted UreR amino acid sequence contains a potential helix-turn-helix motif and an associated AraC family signature and is similar to that predicted for a number of DNA-binding proteins, including E. coli proteins that regulate acid phosphatase synthesis (AppY), porin synthesis (EnvY), and rhamnose utilization (RhaR). These data suggest that UreR governs the inducibility of P. mirabilis urease.

Purification of recombinant Helicobacter pylori urease apoenzyme encoded by ureA and ureB.

Helicobacter pylori, a gram-negative, microaerophilic, spiral-shaped bacterium, is an etiologic agent of human gastritis and peptic ulceration and is highly restricted to the gastric mucosa of humans. Urease, synthesized at up to 6% of the soluble cell protein, hydrolyzes urea, thereby releasing ammonia, which may neutralize acid, allowing survival of the bacterium and initial colonization of the gastric mucosa. The urease protein is encoded by two subunit genes, ureA and ureB; however, accessory genes are necessary for enzyme activity. H. pylori urease genes were isolated from a cosmid gene bank and subcloned on a 5.8-kb Sau3A partial fragment carrying ureCDAB, corresponding to four open reading frames described by A. Labigne, V. Cussac, and P. Courcoux (J. Bacteriol. 173:1920-1931, 1991). Clones were confirmed as ureas gene sequences by polymerase chain reaction amplification. The recombinant enzyme was purified from the soluble protein of French press lysates of Escherichia coli DH5 alpha(pHP402) by chromatography on DEAE-Sepharose, Phenyl-Sepharose, Mono-Q, and Superose 6 resins. Fractions containing a catalytically inactive apoenzyme were identified by an enzyme-linked immunosorbent assay (ELISA) by using antisera to native UreA (29.5 kDa) and UreB (66 kDa). Purified recombinant urease was indistinguishable from native enzyme on a Superose 6 column and on Coomassie blue-stained sodium dodecyl sulfate-polyacrylamide gels. The protein reacted specifically on Western blots (immunoblots) with anti-UreA and anti-UreB antibodies and was recognized with an intensity equal to that of the native enzyme in an ELISA using human sera. Clones containing only ureA and ureB also produced an assembled but inactive enzyme. Enzyme activity was not restored by in trans complementation with cloned urease accessory gene sequences from Proteus mirabilis or Morganella morganii. H. pylori urease genes (ureCDAB) subcloned into pACYC184 were also not complemented with any of 1,000 cosmid clones containing H. pylori chromosomal sequences. However, larger clones containing 4.5 kb of DNA downstream of ureB synthesized catalytically active urease when grown in minimal medium. These data indicate that the ureA and ureB genes encoding H. pylori urease are transcribed and translated in E. coli and that these genes alone are sufficient for the synthesis and assembly of the native size enzyme. Genes downstream of ureB, however, are necessary for production of a catalytically active urease.

Use of polymerase chain reaction-amplified Helicobacter pylori urease structural genes for differentiation of isolates.

Helicobacter pylori has been demonstrated as an etiologic agent of human gastritis and peptic ulcer formation. However, there is no straightforward basis to distinguish different isolates. We used the polymerase chain reaction (PCR) to amplify the urease structural subunit genes, ureA and ureB, which, when digested with appropriate restriction endonucleases, allow the differentiation of patterns on agarose gels. PCR amplification was possible with DNA rapidly extracted from H. pylori by alkaline lysis and phenol-chloroform. The 2.4-kb PCR products amplified from 22 clinical isolates and subjected to HaeII restriction endonuclease digestion produced 10 distinct patterns on agarose gels, with two patterns being shared between five and six strains. PCR amplification of the urease genes may enable the differentiation of closely related H. pylori strains by restriction digest analysis of PCR-amplified ureA and ureB genes.

Evidence for a DNA inversion system in Bordetella pertussis.

The expression of virulence-associated genes in Bordetella pertussis can be lost in three ways: phase variation, antigenic modulation, or serotype conversion. The mechanism(s) of these alterations in gene expression is unclear. B. pertussis chromosomal DNA was probed with cloned pin genes from Escherichia coli and cloned hin genes from Salmonella typhimurium. DNA duplex melting temperature experiments indicated significant homology between B. Pertussis chromosomal DNA and both DNA inversion genes. Southern blots using the hin gene probe showed homology with a 15 kb EcoRI fragment of B. pertussis chromosomal DNA. We postulate here that B. pertussis contains a DNA inversion system which may be responsible for serotype conversion or virulence phase change in this organism.