Analysing two dinucleotide repeats of FVIII gene in Iranian population.

Using dinucleotide repeats for carrier detection and prenatal diagnosis of haemophilia A patients, led us to find different alleles and their frequencies in Iranian population. Polymerase chain reaction (PCR) amplification of two short tandem repeat (STR) loci of factor VIII (FVIII) gene was performed, and the PCR products were resolved on 10% native polyacrylamide gel, and samples were analysed with sequenced DNA markers made of PCR cloning of the dinucleotide FVIII gene fragments. Seven different alleles were observed for intron 13 STR, having 18-24 (CA) repeating units and five alleles for intron 22 STR having 24-28 repeating units of (CACT). Bands produced during dinucleotide study were defined in detail so this could improve the genotyping of heterozygotes and homozygotes. Conformational band produced were characterized to specify the dinucleotide pattern. Our results confirm the Hardy-Weinberg proportions of the heterozygosity rate of the 85 analysed individuals. The observed heterozygosity rate for intron 13 and 22 was 52% and 59% respectively. Our data also indicate that our population is closer to caucasians than to any other populations. Finding different dinucleotide repeat alleles and their frequencies has made it possible to identify carriers and provide prenatal diagnosis with more confidence. This allows antenatal diagnosis to be performed in the vast majority of carriers.

Fluorescent cationic probes of mitochondria. Metrics and mechanism of interaction.

Mitochondria strongly accumulate amphiphilic cations. We report here a study of the association of respiring rat liver mitochondria with several fluorescent cationic dyes from differing structural classes. Using gravimetric and fluorometric analysis of dye partition, we find that dyes and mitochondria interact in three ways: (a) uptake with fluorescence quenching, (b) uptake without change in fluorescence intensity, and (c) lack of uptake. For dyes that quench upon uptake, the extent of quenching correlates with the degree of aggregation of the dye to dimers, as predicted by theory (Tomov, T.C. 1986. J. Biochem. Biophys. Methods. 13:29-38). Also predicted is the relationship observed between quenching and the mitochondria concentration when constant dye is titrated with mitochondria. Not predicted is the relationship observed between quenching and dye concentration when constant mitochondria are titrated with dye. Because a limit to dye uptake exists, in this case, the degree of quenching decreases as dye is added. A Langmuir isotherm analysis gives phenomenological parameters that predict quenching when it is observed as a function of dye concentration. By allowing for a decrease in membrane potential, caused by incorporation of cationic dye into the lipid bilayer, a modification of the Tomov theory predicts the dye titration data. We present a model of cationic dye-mitochondria interaction and discuss the use of these as probes of mitochondrial membrane potential.