Randall K. Saiki

Reverse dot‐blot detection of Thai β‐thalassaemia mutations

Summary. Pending curative therapy, newborn screening and prenatal diagnosis are essential to the management of (3 thalassaemia. Diagnosis using electrophoretic methods is difficult in the presence of composite phenotypes and high Hb F levels. Direct DNA detection of mutant alleles circumvents both problems, but the enormous diversity of β‐thalassaemia mutations poses challenges for this approach. Among PCR‐based tests, the reverse dot‐blot method enables screening several mutations with a single hybridization reaction. Unfortunately it has often been targeted to only the common mutations of a particular ethnic population, necessitating the use of more arduous detection methods for the less common mutations. We developed a reverse dot‐blot strip for the 10 β‐thalassaemia mutations, including the β‐thalassaemic haemoglobino‐pathies Hb E and Hb Malay, that account for 96% of j3 thalassaemia in Thailand, and another strip for six less common Thai mutations. The second strip precludes the need for more technically challenging methods. To avoid problems associated with secondary structure of amplified full‐length target DNA, we amplified and labelled β‐globin DNA as two shorter fragments that encompassed all known Thai mutations. Reverse dot‐blotting is a rapid, accurate method for detecting β‐thalassaemia mutations.

Survey of CF mutations in the clinical laboratory

BackgroundSince it is impossible to sequence the complete CFTR gene routinely, clinical laboratories must rely on test systems that screen for a panel of the most frequent mutations causing disease in a high percentage of patients. Thus, in a cohort of 257 persons that were referred to our laboratory for analysis of CF gene mutations, reverse line probe assays for the most common CF mutations were performed. These techniques were evaluated as routine first-line analyses of the CFTR gene status.MethodsDNA from whole blood specimens was extracted and subjected to PCR amplification of 9 exons and 6 introns of the CFTR gene. The resulting amplicons were hybridised to probes for CF mutations and polymorphisms, immobilised on membranes supplied by Roche Molecular Systems, Inc. and Innogenetics, Inc.. Denaturing gradient gel electrophoresis and sequencing of suspicious fragments indicating mutations were done with CF exon and intron specific primers.ResultsOf the 257 persons tested over the last three years (referrals based on 1) clinical symptoms typical for/indicative of CF, 2) indication for in vitro fertilisation, and 3) gene status determination because of anticipated parenthood and partners or relatives affected by CF), the reverse line blots detected heterozygote or homozygote mutations in the CFTR gene in 68 persons (26%). Eighty-three percent of those affected were heterozygous (47 persons) or homozygous (10 persons) for the ΔF508 allele. The only other CF-alleles that we found with these tests were the G542X allele (3 persons), the G551D allele (3 persons), the 3849+10kb C-T allele (2 persons) the R117H allele (2 persons) and the 621+1G-T allele (1 person).Of the fifteen IVS8-5T-polymorphisms detected in intron 8, seven (47%) were found in males referred to us from IVF clinics. These seven 5T-alleles were all coupled with a heterozygous ΔF508 allele, they make up 35% of the males with fertility problems (20 men) referred to us.ConclusionsIn summary, the frequency of CF chromosomes in the cohort examined with these tests was 26%, with the ΔF508 allele affecting 83% of the CF chromosomes. It is a substantial improvement for routine CF diagnostics to have available a test system for 30 mutations plus the polypyrimidine length variants in intron 8. Our results show that this test system allows a routine first-line analyses of the CFTR gene status.