An expanded histatin gene polymorphism and test of a possible disease resistant phenotype.

Histatins are small molecular weight salivary proteins that are important in the non-immune host defense system. Two frequent cis-linked coding-change mutations were previously described in exon 5 of the HIS2 gene of Blacks. The polymorphic mutant allele was termed HIS2(2) and the wild-type allele HIS2(1). We here describe two new non-coding change polymorphisms of the HIS2 gene: a deletion in intron 5 (7183-7198 del) and a C-->T mutation in exon 5 [C-->T (7104)] that characterize two new HIS2 alleles, HIS2(3) and HIS2(4) respectively. Both mutations occur on a HIS2(1) background. The HIS2(3) allele occurred only in Afro-Americans, but not in 67 Japanese, 51 Chinese and 50 Whites. Among 66 random DNA samples from Afro-Americans, frequencies of HIS2(1), HIS2(2), HIS2(3) and HIS2(4) were 0.67, 0.22, 0.05 and 0.07 respectively, with a heterozygosity of 0.45. The frequencies of the HIS2(4) allele in 50 Whites and 50 Chinese were 0.06, and 0.1 respectively. In a comparison of 60 matched saliva and DNA samples from the Afro-American population, the DNA-based mutation analysis reliably identified salivary histatin phenotypes. The salivary histatin polymorphism (inferred from PCR analysis) was used to test a biologically plausible hypothesis, that the mutant histatin phenotype (coded by the HIS2(2) allele) confers relative resistance to severe and fatal malaria. In a study of 185 Black Tanzanian subjects, there were no significant differences in HIS2(2) allelic frequencies between the various test groups: for 86 cerebral malaria subjects, 54 uncomplicated malaria subjects, and 45 combined asymptomatic parasitemia and health controls, HIS2(2) frequencies were 0.16, 0.17 and 0.17 respectively. Thus, there was no support for the hypothesis in this population.

PRB1, PRB2, and PRB4 coded polymorphisms among human salivary concanavalin-A binding, II-1, and Po proline-rich proteins.

Six closely linked PRP (proline-rich protein) genes code for many salivary PRPs that show frequent length and null variants. From determined protein sequences and DNA sequence analysis of variant alleles, we here report the coding and molecular basis for Con (concanavalin A-binding) and Po (parotid "o") protein polymorphisms. The Con1 glycoprotein is encoded in exon 3 of a PRB2 allele (PRB2L CON1+) with a potential N-linked glycosylation site. Because of a probable gene conversion encompassing > or = 684 bp of DNA, the "PRB2-like" Con2 glycoprotein is encoded in exon 3 of a PRB1 allele (PRB1M CON2+) with a potential glycosylation site. The PmF protein is also encoded in the PRB1M CON2+ allele, thus explaining the previously reported association between Con2 and PmF proteins. A PRB2L CON1 allele contains a single nt missense change [TCT(Ser)-->CCT (Pro)] that abolishes the potential N-linked glycosylation site (NKS-->NKP) in the Con1 protein, and this explains the Con- type. The Po protein and a glycoprotein (II-1) are encoded in the PRB4 gene, and both proteins are absent in the presence of a mutation in the PRB4M PO- allele that contains a single nt change (G--C) at the +1 invariant position of the intron 3 5'donor splice site. The genetically determined absence of the II-1 glycoprotein leads to altered in vitro binding of Streptococcus sanguis 10556 to salivary proteins, which suggests a biological consequence for null mutations of the PRB4 gene.

Interactions between mutants with defects in two Ca2(+)-dependent K+ currents of Paramecium tetraurelia.

Paramecium tetraurelia possesses two Ca2(+)-dependent K+ currents, activated upon depolarization IK(Ca,d), or upon hyperpolarization IK(Ca,h). The two currents are mediated by pharmacologically distinct ion channel populations. Three mutations of P. tetraurelia affect these currents. Pantophobiac A mutations (pntA) cause calmodulin sequence defects, resulting in the loss of both Ca2(+)-dependent K+ currents. A second mutation, TEA-insensitive A (teaA), greatly enhances IK(Ca,d) but has no affect on IK(Ca,h). A third mutation, restless (rst), also increases IK(Ca,d) slightly, but its principle effect is in causing an early activation of IK(Ca,h). Interactions between the products of these three genes were investigated by constructing three double mutants. Both teaA and rst restore IK(Ca,d) and IK(Ca,h) in pantophobiac A1, but the phenotypes of teaA and rst are not corrected by a second mutation. These observations may indicate a role for the gene products of teaA and rst in regulating the activity of IK(Ca,d) and IK(Ca,h), respectively.

Genetic analysis of mutants with a reduced Ca2+-dependent K+ current in Paramecium tetraurelia.

Two mutants of Paramecium tetraurelia with greatly reduced Ca2+-dependent K+ currents have been isolated and genetically analyzed. These mutants, designated pantophobiac, give much stronger behavioral responses to all stimuli than do wild-type cells. Under voltage clamp, the Ca2+-dependent K+ current is almost completely eliminated in these mutants, whereas the Ca2+ current is normal. The two mutants, pntA and pntB, are recessive and unlinked to each other. pntA is not allelic to several other ion-channel mutants of P. tetraurelia. The microinjection of a high-speed supernatant fraction of wild-type cytoplasm into either pantophobiac mutant caused a temporary restoration to the wild-type phenotype.