Primers suitable for the amplification of the gene encoding the class 1 outer membrane protein of Neisseria meningitidis by the polymerase chain reaction (PCR) were designed from published DNA sequences and used to study the gene in eight meningococcal strains of different serogroup, serotype and subtype. At high annealing stringency one product, shown to correspond to the class 1 protein gene, was amplified from each strain. For three strains an additional smaller product, provisionally identified as the gene encoding the class 3 outer membrane protein, was amplified at lower annealing stringencies. Nucleotide sequence analysis of the PCR products corresponding to the class 1 proteins established the differences in the primary structure of the proteins between each of the subtypes and other outer-membrane proteins from Neisseria spp. These differences impose constraints on possible structural models of these proteins. Most amino acid sequence variation occurred in two domains of between 8 and 17 amino acids; there was an additional region which varied mainly between classes of outer membrane protein and there were nine conserved regions. Using appropriate primers it was possible to distinguish between class 1 outer membrane protein genes from strains of different subtypes by the PCR.
Molecular approaches to the rapid analysis of the serotyping antigens of Neisseria meningitidis, the class 2 and 3 outer membrane proteins (OMPs), were developed, evaluated, and used to study 12 antigenic variants of these proteins. A primer set for the polymerase chain reaction (PCR) amplification of the genes encoding these antigens was devised. Low-stringency amplification of meningococcal chromosomal DNA with this primer set resulted in the amplification of two products from each strain, whereas at higher stringencies only one product was amplified in most strains. Southern hybridization techniques and restriction analyses were used to differentiate the PCR products amplified at high stringencies from strains expressing class 2 or class 3 OMPs; these PCR products were further characterized by the determination of their nucleotide sequences, confirming that they represented the amplified class 2 and class 3 OMP genes. Analyses of these and other nucleotide sequences enabled the construction of a phenogram illustrating the interrelationships between Neisseria OMP branes were prepared by a spheroplast lysis method modified from that of Witholt et al. (38). A single colony from 3620 on August 1, 2020 by guest
Live attenuated vaccines, developed with molecular genetical techniques, require new approaches for their quality control. To develop novel quality control tests that enhanced and extended existing procedures, the attenuated vaccine strain Salmonella -hi Ty2la and its parent strain Ty2 were characterized by pulsed-field gel electrophoresis (PFGE) and direct nucleotide sequence analysis. Mutant and parent strains were distinguished using fingerprints generated by the resolution on PFGE of chromosomal DNA digested with each of the enzymes Sfil, Spel or Xbal. These fingerprints were stable through multiple in v i m passages of the vaccine strain and were identical from one batch of vaccine to another. It was also possible t o distinguish between the mutant and parent strains by direct nucleotide sequence analysis of the gal€ gene. This analysis identified two base changes in the gene from strain Ty2la: a single base deletion causing a frameshift that would result in a truncated gene produd, accounting for the gal€ phenotype; and a transition that eliminated an AIul restriction site. The consequent change in the A M fingerprint of the gal€ gene in strain Ty2la provided a rapid, PCRbased alternative to the use of differential media or biochemical assays for the identification of the vaccine strain.
The class 1 outer membrane protein (OMP), a major variable surface antigen of Neisseria meningitidis, is a component of novel meningococcal vaccines currently in field trials. Serological variants of the protein are also used to serosubtype meningococci. Most of the amino acid changes that give rise to antigenic variants of the protein occur in two variable regions (VR1 and VR2) that are thought to form loops on the cell surface. The polymerase chain reaction (PCR) was used to amplify the nucleotide sequences encoding VR1 and VR2 from the chromosomal DNA of N. meningitidis strain M1080. These were cloned in frame into the lamB gene of the Escherichia coli expression vector pAJC264. Whole-cell enzyme-linked immunosorbent assays (ELISAs), using monoclonal antibodies, and SDS-PAGE confirmed that, upon induction, strains of E. coli carrying these constructs expressed hybrid LamB proteins containing the N. meningitidis surface loops. These strains were used to immunize rabbits and the resultant polyclonal antisera reacted specifically with the class 1 OMP of reference strain M1080 (P1.7). Immunogold labelling of meningococcal cells and whole-cell dot-blot analyses with these antisera showed that the variable epitopes were exposed on the cell surface and confirmed that this approach could be used to obtain serosubtype-specific antisera. The binding profiles of the antisera were determined from their reactions with overlapping synthetic peptides and their reactivity compared with that of relevant serosubtype-specific monoclonal antibodies. This approach was used successfully to raise antisera against two other class 1 OMP VR2s. A fourth antiserum raised against a VR2, including the P1.1 epitope, was not subtype specific.
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