Euroforgen-NoE collaborative exercise on LRmix to demonstrate standardization of the interpretation of complex DNA profiles.

There has been very little work published on the variation of reporting practices of mixtures between laboratories, but it has been previously demonstrated that there is little consistency. This is because there is no current uniformity of practice, so different laboratories will operate using different rules. The interpretation of mixtures is not solely a matter of using some software to provide 'an answer'. An assessment of a case will usually begin with a consideration of the circumstances of a crime. Assumptions made about the numbers of contributors follow from an examination of the electropherogram(s)--and these may differ between the prosecution and the defence hypotheses. There may be a necessity to evaluate several sets of hypotheses for any given case if the circumstances are uncertain. Once the hypotheses are formulated, the mathematical analysis is complex and can only be accomplished by the use of specialist software. In order to obtain meaningful results, it is essential that scientists are trained, not only in the use of the software, but also in the methodology to understand the likelihood ratio concept that is used. The Euroforgen-NoE initiative has developed a training course that utilizes the LRmix program to carry out the calculations. This software encompasses the recommendations of the ISFG DNA commissions on mixture interpretation and is able to interpret samples that may come from two or more contributors and may also be partial profiles. Recently, eighteen different laboratories were trained in the methodology. Afterwards they were asked to independently analyze two different cases with partial mixture DNA evidence and to write a statement court-report. We show that by introducing a structured training programme, it is possible to demonstrate, for the first time, that a high degree of standardization, leading to uniformity of results can be achieved by participating laboratories.

Short communication: Biological and genetic characterization of HIV type 1 subtype B and nonsubtype B transmitted viruses: usefulness for vaccine candidate assessment.

Due to the extraordinary degree of genetic diversity of HIV-1 and the structural complexity of its envelope glycoproteins, designing an effective vaccine is difficult, requiring the development of viral reagents to assess vaccine-elicited neutralizing antibodies. The aim of this study was to improve on our previously developed panel of HIV-1 strains of different genetic forms, focusing on strains from acute and recently acquired infections as the most representative of the transmitted viruses. HIV-1 primary isolates were expanded in peripheral blood mononuclear cells. Viral stocks of 40 ml each were produced. Syncytium-inducing (SI) phenotype, coreceptor use, and TCID(50)/ml were determined. Near full-length HIV-1 genomes were amplified by RT-nested PCR in four overlapping segments. Phylogenetic analyses were performed with neighbor-joining trees and bootscanning. Forty-four HIV-1 strains were included in the panel. Twenty-four (54.1%) strains were from early infections (16 acute and 8 recent); of them, 21 (87%) were sexually transmitted. NSI/R5 phenotype was detected in 37 (84.1%) viruses and SI/R5,X4 in another 7 (15.9%). TCID(50)/ml ranged between 10(4) and 10(6.6). Twelve different genetic forms constituted this panel: subtypes A1, B, C, F1, and G; circulating recombinant forms CRF02_AG, CRF14_BG, and CRF24_BG; and unique recombinant forms CRF02_AG/A3, BF1, CRF12_BF/B, and DF1G. In conclusion, in this study, we report the development of a comprehensive and well-characterized panel of HIV-1 isolates for assessing neutralization in HIV vaccine research. This panel is available for distribution through the Programme EVA Centre for AIDS Reagents, National Institute for Biological Standard and Control (NIBSC).

Development of a panel of well-characterized human immunodeficiency virus type 1 isolates from newly diagnosed patients including acute and recent infections.

The aim of this study was the development of a panel constituted by well-defined HIV-1 strains of different genetic forms, with a particular focus on isolates from acute and recent infections. Fourteen HIV-1 isolates, including four from acute and five from recent infections, were expanded in peripheral blood mononuclear cells. SI phenotype, coreceptors use, and TCID(50)/ml were determined. V3 net charge was calculated. Near full-length genomes were amplified by RT-nested PCR in four overlapping segments. Phylogenetic analyses were performed with neighbor-joining trees and bootscanning. Analysis of cysteine residues, lengths of variable regions, and potential N-linked glycosylation sites in gp120 and gp41 was performed. Viral stocks were produced. Thirteen strains were NSI/R5 and one SI/R5,X4. TCID(50)/ml ranged between 10(4.6) and 10(6). V3 net charge was <+5 in 12 sequences and +5 in two sequences. Near full-length HIV-1 genomes analysis identified viruses of the following genetic forms: eight subtype B, three subtype C, two CRF02_AG, and one subtype G. Cysteine residues that form the V1,V2,V3, and V4 loops were highly conserved. The number of potential N-linked glycosylation sites in gp120 and gp41 ranged between 24-29 and 4-6, respectively. Seven potential N-linked glycosylation sites in gp120 and three in gp41 were conserved. V1, V2, V4, and V5 variable regions exhibited substantial length variation. In addition, an analysis of transmitted and natural resistance to current antiretroviral drugs in these strains was performed. It is worth mentioning that the 13S mutation in the V3 sequence, associated with resistance to maraviroc, was observed in a subtype B strain that harbored resistance mutations to nucleoside reverse transcriptase inhibitors and to T20. The availability of a panel including strains from acute and recent infections should be a valuable resource for optimizing and standardizing vaccine candidate assessment. Near full-length genome characterization may be necessary for evaluating clade-specific reactivities.