Typing

About: Typing is a research topic. Over the lifetime, 5010 publications have been published within this topic receiving 146539 citations.

Serotyping and subtyping of Neisseria meningitidis isolates by co-agglutination, dot-blotting and ELISA.

Abstract: Typing of meningococci with a panel of serotype and subtype specific monoclonal antibodies (MAbs) was compared in co-agglutination, dot-blotting and ELISA tests. Twenty reference strains, 50 case isolates and 133 throat isolates from healthy carriers were studied. The typing results with dot-blotting and ELISA were identical, whereas co-agglutination gave different results for three case and 24 carrier strains. The distribution of serotypes and subtypes among the strains is reported. The combination of the subtypes P1.1 and P1.15 in a serotype 15 patient strain was observed. With one case strain and 15 carrier strains, neither serotype nor subtype could be determined. Non-typable and non-subtypable isolates were further characterised by sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Co-agglutination is useful for typing small numbers of strains with a few MAbs, but less suitable for large-scale typing than the other two methods. Dot-blotting needs less expensive equipment, smaller volumes of antibodies and fewer manipulations than ELISA.

DNA typing of the HLA-A gene: population study and identification of four new alleles in Japanese

Abstract: With the use of polymerase chain reaction (PCR) and sequence-specific oligonucleotide probe (SSOP), we established a DNA typing method of the HLA-A locus. A pair of primers to amplify the highly polymorphic region of HLA-A gene including exon 2 and exon 3 was designed and the amplified DNAs were hybridized with 91 types of 32P labeled SSOPs. This method allowed discrimination of all known HLA-A alleles except for two combinations, A*0201 or A*0209 and A*0207 or A*0215N, which have identical sequences in exon 2 and exon 3. Another pair of primers was designed for amplification of exon 4 and the PCR products were hybridized with 5 SSOPs to distinguish A*0201 and A*0207 from A*0209 and A*0215N, respectively. In this study, 81 B-lymphoblastoid cell lines (BLCL) homozygous for HLA and 553 unrelated healthy Japanese individuals were determined for their HLA-A genotypes. Based on the genotyping results, frequency of HLA-A alleles and linkage disequilibrium between HLA-A and HLA-B in the Japanese population were investigated. In addition, four new HLA-A alleles were identified and their nucleotide sequences in exon 2 and exon 3 were determined to confirm the typing results.

Microsatellite markers for typing Aspergillus fumigatus isolates.

Abstract: The use of microsatellites as highly polymorphic DNA markers for the typing of isolates of Aspergillus fumigatus was investigated. Four CA repeats were selected by screening an A. fumigatus DNA library with a (CA)10 oligonucleotide. Primers flanking these CA repeats were designed to amplify each locus. One primer of each pair was labeled with a fluorophore, and the PCR products were analyzed with an automatic sequencer and the GeneScan software. For each primer set and for a given isolate, one band was detected and was assigned to an allele because A. fumigatus is haploid. With 50 clinical isolates, 50 environmental isolates, and 2 reference strains we obtained 12, 11, 10, and 23 different alleles for the four CA microsatellites, respectively (discriminatory power, 0.994). The results were identical by whatever DNA extraction technique was used. Interestingly, no clustering between environmental and clinical isolates was observed, suggesting that every isolate is potentially pathogenic. Microsatellite markers appear suitable for use in large epidemiological studies of invasive aspergillosis.

Molecular typing and epidemiology of enteroviruses identified from an outbreak of aseptic meningitis in Belgium during the summer of 2000

Abstract: Non-polio enteroviruses are the most common cause of aseptic meningitis worldwide. From May to September 2000, a major outbreak of aseptic meningitis occurred in Belgium. Cerebrospinal fluid samples (CSF) of 122 patients were found to contain enterovirus RNA using diagnostic RT-PCR that targeted a 231-bp gene fragment in the 5' noncoding region. In addition, a molecular typing method was developed based on RT-nested PCR and sequencing directly from CSF(a) 358-bp fragment in the aminoterminal part of the VP1 capsid protein. To identify the enterovirus type, nucleotide sequences of the VP1 amplicons were compared to all the enterovirus VP1 sequences available in GenBank. Echovirus 30 (31.2%), echovirus 13 (23.8%), and echovirus 6 (20.5%) were identified most frequently during the epidemic. Coxsackievirus B5 was present in 15.6% of the samples, and could be subdivided in two distinct epidemic clusters, coxsackievirus B5a (10.7%) and B5b (4.9%). Other enteroviruses encountered were echovirus 16 (5.7%), echovirus 18 (1.6%), coxsackievirus B4 (0.8%) and echovirus 7 (0.8%). The high prevalence of echovirus 13, considered previously a rare serotype, indicates it is an emerging epidemic type. To verify the typing results and to explore further the intratypical genetic variation, phylogenetic analysis was carried out. Geographical clustering of most of the strains within each type and subtype could be observed. The RT-nested PCR strategy, carried out directly on clinical samples, is a simple and rapid method for adequate molecular typing of the Group B enteroviruses causing aseptic meningitis.

HLA-DRB1*01 subtyping by allele-specific PCR amplification: a sensitive, specific and rapid technique.

Abstract: The two DR1-associated cellular specificities Dw1 and Dw20, as well as DR'Br' (Dw'BON'), cannot be unequivocally assigned by serological typing or restriction fragment length polymorphism (RFLP) analysis. We have developed and compared two polymerase chain reaction-based (PCR) typing methods for distinguishing these DRB1 alleles; allele-specific amplification of DRB1*01 alleles followed by an agarose gel electrophoresis detection step and group-specific DRB1*01 amplification followed by hybridization with sequence-specific oligonucleotide probes. The two typing strategies gave completely concordant results in the 33 DRB1*01-positive and the 46 DRB1*01-negative individuals and cell lines studied. No false-negative or false-positive typing results were obtained. All possible heterozygous combinations of the DRB1*0101-0103 alleles could be distinguished by both typing methods. DRB1*01 subtyping by allele-specific PCR amplification was performed in less than 3 hours, including PCR amplification, detection and interpretation steps. The technique will be a valuable complement to DR typing by serology and RFLP analysis. Allele-specific DRB1 amplifications or group-specific amplifications followed by directed allele-specific amplifications of DRB1 alleles, typing based on the absence or presence of amplified products, may well prove to be the technical innovation that will firmly establish PCR-based DR typing in routine clinical tissue typing.