Platelet glycoprotein I(b)alpha and integrin alpha2 beta1 polymorphisms: gene frequencies and linkage disequilibrium in a population diversity panel.

Genetic variants in the GP1BA and ITGA2 genes have been proposed as potential modifiers for arterial vascular disease and bleeding disorders. Since ancestry may play an important role in the prevalence of these variants, we sought to determine their allele frequency and linkage disequilibrium in a collection of 1064 DNA samples from 51 ethnic groups. We studied haplotypes of ITGA2 defined by single nucleotide substitutions at positions -52, 807, and 1648, and GP1BA variants defined by sequence changes in positions -5 (Kozak), 1018 (T145M, HPA-2) and 1285 (VNTR A, B, C and D). Frequency of haplotypes of ITGA2 showed considerable variation across the different groups, with a higher prevalence of the haplotype -52C or T/807C/1648A observed in African compared with caucasian and Asian populations. The haplotypes 52C/807T/1648A and -52T/807T/1648A were not observed in caucasians or South Americans. While relative frequencies of the GP1BA Kozak alleles were comparable across groups, the methionine allele (HPA-2b) showed a higher frequency in Africa (0.26) than in the other groups. We also observed a high prevalence of the VNTR B allele in the African and Israeli populations. Haplotype analysis revealed incomplete linkage disequilibrium between the HPA-2 and VNTR alleles. Incorporation of GP1BA variants into the set of SNPs already genotyped by the HapMap project disrupted the pre-existing haplotype block. These data provide a valuable resource for optimal selection of variants best tailored for association studies of vascular disease or bleeding disorders when examining individuals of different ancestral origins.

Nitric oxide synthase and cGMP-mediated stimulation of renin secretion.

The interaction between nitric oxide (NO) and renin is controversial. cAMP is a stimulating messenger for renin, which is degraded by phosphodiesterase (PDE)-3. PDE-3 is inhibited by cGMP, whereas PDE-5 degrades cGMP. We hypothesized that if endogenous cGMP was increased by inhibiting PDE-5, it could inhibit PDE-3, increasing endogenous cAMP, and thereby stimulate renin. We used the selective PDE-5 inhibitor zaprinast at 20 mg/kg body wt ip, which we determined would not change blood pressure (BP) or renal blood flow (RBF). In thiobutabarbital (Inactin)-anesthetized rats, renin secretion rate (RSR) was determined before and 75 min after administration of zaprinast or vehicle. Zaprinast increased cGMP excretion from 12.75 +/- 1.57 to 18.67 +/- 1.87 pmol/min (P < 0.003), whereas vehicle had no effect. Zaprinast increased RSR sixfold (from 2.95 +/- 1.74 to 17.62 +/- 5.46 ng ANG I. h(-1) x min(-1), P < 0.024), while vehicle had no effect (from 4.08 +/- 2.02 to 3.87 +/- 1.53 ng ANG I x h(-1) x min(-1)). There were no changes in BP or RBF. We then tested whether the increase in cGMP could be partially due to the activity of the neuronal isoform of NO synthase (nNOS). Pretreatment with the nNOS inhibitor 7-nitroindazole (7-NI; 50 mg/kg body wt) did not change BP or RBF but attenuated the renin-stimulating effect of zaprinast by 40% compared with vehicle. In 7-NI-treated animals, zaprinast-stimulated cGMP excretion was attenuated by 48%, from 9.17 +/- 1.85 to 13.60 +/- 2.15 pmol/min, compared with an increase from 10.94 +/- 1.90 to 26.38 +/- 3.61 pmol/min with zaprinast without 7-NI (P < 0.04). This suggests that changes in endogenous cGMP production at levels not associated with renal hemodynamic changes are involved in a renin-stimulatory pathway. One source of this cGMP may be nNOS generation of NO in the kidney.