Genotyping of RHD by multiplex polymerase chain reaction analysis of six RHD-specific exons

Qualitative RHD variants are the result of the replacement of RHD exons by their RHCE counterparts or of point mutations in RHD causing amino acid substitutions. For RHD typing, the use of at least two RHD typing polymerase chain reaction (PCR) assays directed at different regions of RHD is advised to prevent discrepancies between phenotyping and genotyping results, but even then discrepancies occur. A multiplex RHD PCR based on amplification of six RHD-specific exons in one reaction mixture is described. Six RHD-specific primer sets were designed to amplify RHD exons 3, 4, 5, 6, 7, and 9. DNA from 119 donors (87 D+, 14 D- and 18 with known D variants; whites and nonwhites) with known Rh phenotypes was analyzed. All six RHD-specific exons from 85 D+ individuals were amplified, whereas none of the RHD exons from 13 D- individuals were amplified. Multiplex PCR analysis showed that the genotypes of two donors typed as D+ were DIVa and DVa. Red cell typing confirmed these findings. From all D variants tested (DIIIc, DIVa, DIVb, DVa, DVI, DDFR, DDBT) and from RoHar, RHD-specific exons were amplified as expected from the proposed genotypes. The multiplex PCR assay is reliable in determining genotypes in people who have the D+ and partial D phenotypes as well as in discovering people with new D variants. Because the multiplex PCR is directed at six regions of RHD, the chance of discrepancies is markedly reduced. The entire analysis can be performed in one reaction mixture, which results in higher speed, higher accuracy, and the need for smaller samples. This technique might be of great value in prenatal RHD genotypin

A new case of dup(3q) syndrome due to a pure duplication of 3qter.

Item does not contain fulltextThe characteristic clinical features of the dup(3q) syndrome include typical facial features, mental and growth retardation, and (often) congenital heart anomalies. However, pure duplication of 3qter is rare because most of the reported cases are patients who carry an unbalanced translocation and, in addition to the duplication for 3qter, have a deletion for another chromosomal segment. A new case with a pure duplication of 3q detected in a 2-month-old boy is presented here. Extensive cytogenetic analysis revealed an inverted duplication of the distal part of 3q (chromosomal band 3q26.3 up to the telomere), with no (detectable) loss of the original telomeric sequences. Clinical evaluation revealed several phenotypic hallmarks characteristic for the dup(3q) syndrome. By comparing the duplicated region of this patient with the duplicated regions of the other patients with a pure duplication of 3q, we were able to localize the critical region for the dup(3q) phenotype to band 3q26.3. Alongside this new case with a pure duplication of 3q, an overview of six previous cases is given