Low-frequency human platelet antigens as triggers for neonatal alloimmune thrombocytopenia.

BACKGROUND: Twenty-four low-frequency human platelet antigens (LFHPAs) have been implicated as immunogens in neonatal alloimmune thrombocytopenia (NAIT). We performed studies to define more fully how often these antigens trigger maternal immunization leading to NAIT. STUDY DESIGN AND METHODS: In a Phase 1 study, fathers of selected NAIT cases not resolved by serologic testing but thought to have a high likelihood of NAIT on clinical and serologic grounds were typed for LFHPAs by DNA sequencing. In a Phase 2 study, high-throughput methods were used to type fathers of 1067 consecutive unresolved NAIT cases for LFHPAs. Mothers of 1338 unresolved cases were also typed to assess the prevalence of LFHPAs in a population racially/ethnically similar to the fathers. RESULTS: In Phase 1, LFHPAs were identified in 16 of 244 fathers (6.55%). In Phase 2, LFPAs were found in only 28 of 1067 fathers (2.62%). LFHPAs were identified in 27 of 1338 maternal samples (2.01%). HPA-9bw was by far the most common LFHPA identified in the populations studied and was the only LFHPA that was significantly more common in fathers than in mothers of affected infants (p = 0.02). CONCLUSIONS: Maternal immunization against recognized LFHPAs accounts for only a small fraction of the cases of apparent NAIT not resolved by standard serologic testing. Typing of the fathers of such cases for LFHPAs is likely to be rewarding only when a maternal antibody specific for a paternal platelet glycoprotein is demonstrated and/or there is compelling clinical evidence for NAIT.

A simplified method for screening siblings for HLA identity using short tandem repeat (STR) polymorphisms.

Identifying an HLA-matched sibling donor for hematopoietic stem cell transplantation (HSCT) is time-consuming and expensive, and often limited by reimbursement caps imposed by insurance providers. To improve the effectiveness and efficiency of screening for HLA-matched siblings, we developed an assay for determining HLA identity using a panel of nine informative short tandem repeat (STR) loci located throughout the HLA complex. The STR panel was assessed for accuracy in identifying HLA-matched siblings in 88 family workups comprising a total of 132 related donor and recipient typing comparisons. All sibling pairs with identical STR alleles were also HLA identical. Of the 48 pairs mismatched at one or more STR alleles, all were genotypically HLA non-identical at one or more loci. The sensitivity and specificity of STR analysis for identifying HLA-matched siblings were 91% and 100%, respectively. Three false negatives occurred due to an STR mutation or possible HLA-DPB1/DQB1 recombination. Additionally, STR genotyping provided additional information allowing determination of the extent of HLA identity in families where HLA haplotype inheritance was ambiguous, due to extensive homozygosity or shared parental haplotypes. The HLA STR assay is a reliable and rapid test that can be used to inexpensively screen potential sibling donors for HLA identity.

Genetic variability at the human FMO1 locus: significance of a basal promoter yin yang 1 element polymorphism (FMO1*6).

The flavin-containing monooxygenases (FMOs) are important for the disposition of a variety of toxicants, therapeutics, and dietary components. Although FMO1 is the dominant isoform in fetal liver and adult kidney and intestine and despite up to a 10-fold intersubject variation in expression, a paucity of information is available on FMO1 genetic variability. To address this issue, 24 samples from the Coriell DNA Polymorphism Discovery Resource Panel were sequenced revealing 10 common single nucleotide polymorphisms (SNPs): four located upstream of the structural gene; three within exonic sequences; one within the intron 1 splice donor site; and two with the 3'-untranslated region. Six of these variants are novel. Compared with other FMO loci within the chromosome 1q23-25 cluster, FMO1 seems more highly conserved. Of the identified FMO1 SNPs, only a C>A transversion 9536 base pairs upstream of the exon 2 ATG start codon (g.-9536C>A) would likely affect function, because it lies within the conserved core binding sequence for the yin yang 1 (YY1) transcription factor. Electrophoretic mobility shift assays demonstrated that the g.-9536C>A transversion eliminated YY1 binding. Furthermore, data from transient expression assays in HepG2 cells suggested this SNP could account for a 2- to 3-fold loss of FMO1 promoter activity. Genotype analysis revealed a g.-9,536A allele (FMO1*6) frequency of 13 and 11% in African- and northern European-Americans, respectively, but a significantly higher frequency of 30% in Hispanic-Americans. Thus, the FMO1*6 variant may account for some of the observed interindividual variation in FMO1 expression.

Alternative processing of the human FMO6 gene renders transcripts incapable of encoding a functional flavin-containing monooxygenase.

The flavin-containing monooxygenases (FMOs) are a family of five microsomal enzymes important for the oxidative metabolism of environmental toxicants, natural products, and therapeutics. With the exception of FMO5, the FMO are encoded within a single gene cluster on human chromosome 1q23-25. As part of the human genome effort, an FMO-like gene, FMO6, was identified between FMO3 and FMO2 (GenBank accession no. AL021026). Sequence analysis of this putative FMO family member revealed nothing that would a priori argue against a functional gene and encoded protein. When FMO6 expression was examined by reverse transcriptase coupled polymerase chain reaction DNA amplification, transcripts were identified in 8 of 11 human liver samples, but 0 of 4 kidney biopsy samples. However, in all cases, the observed transcripts were shorter than predicted. Sequence analysis revealed skipping of exon 4, exons 3 and 4, and/or the use of alternative splice donor or acceptor sites in introns 3, 4, 6, and 8, resulting in nine unique transcripts. Based on an analysis of possible open reading frames, none of these transcripts would encode a functional FMO enzyme. Taking advantage of the high sequence identity between FMO3 and FMO6, it is posited that the loss of binding sites for the serine-arginine-rich splicing factor protein family within exons 3 and 4 contributes to the exon skipping events, although the most commonly observed alternative splice event results from a 21-bp insertion immediately 3' to the predicted FMO6 intron 8 splice acceptor site, diminishing the efficiency of this site.