Localization of the human salivary protein complex (SPC) to chromosome band 12p13.2

In situ hybridization of a 3H-labeled probe containing a fragment from PRP-1, a genomic clone with human salivary proline-rich protein gene sequences, revealed significant labeling on the short arm of human chromosome 12 in metaphase preparations from two individuals. Fifty-three percent of metaphases exhibited labeling on one or both chromosomes 12. Additional cells scored at the 850-1,000 band level revealed a significant proportion (52% [32/61] grains, p less than 0.005) of the labeled sites on chromosome 12 to be on band 12p13.2. This probe for a human salivary proline-rich protein gene fragment, probably PMS, is from a cluster of 13 linked genes designated as the human salivary protein complex (SPC). Studies of the DNA of human-mouse somatic-cell hybrids have assigned the SPC to chromosome 12, but have not provided a regional localization (Azen et al, 1985). This paper reports the localization of the SPC to a specific chromosomal band, 12p13.2.     

Genetic polymorphisms of Pe and Po salivary proteins with probable linkage of their genes to the salivary protein gene complex (SPC)

Two new genetic polymorphisms (Pe and Po) are found in human parotid saliva. Each polymorphism is determined by the autosomal inheritance of one expressed (dominant) and one unexpressed (recessive) allele. Autosomal inheritance is supported by studies of 63 families including 264 children for Pe and 57 families including 242 children for Po. For randomly collected salivas, gene frequencies in 317 whites are Pe+ = 0.76 and Pe- = 0.24; in 408 whites, Po+ = 0.75 and Po- = 0.25; in 51 blacks, Pe+ = 0.76 and Pe- = 0.24; and in 59 blacks, Po+ = 0.77 and Po- = 0.23. Both Pe and Po proteins react immunologically with polyclonal antisera prepared to proline-rich proteins PRPs. The Pe protein has an isoelectric point of approximately pH 6.1-6.3, and the Po protein has an isoelectric point greater than pH 8.0. In randomly collected salivas, the Pe and Po proteins are associated with other known salivary PRPs. The Pe protein is most strongly associated with the CON 1 and Ps proteins, is less strongly associated with the Pr and Pa proteins, and is not significantly associated with the PmF, PmS, PIF, Db, Con 2, or Gl proteins. If it is assumed that the strength of these associations (presumed linkage disequilibrium) may be related in part to map distance, then these data roughly fit the linear order of PRP genes as previously determined from recombination data derived from family linkage studies. The Po protein is associated with the PmS protein. There is evidence for probable linkage of Pe and Po to the SPC (salivary protein gene complex): Pe to Pa (nine families, lod score at theta = 0 is 2.67) and Po to CON 2 (three families, lod score at theta = 0 is 2.35).     

Description of a genetic polymorphism of a human proline-rich salivary protein,Pc, and its relationship to other proteins in the salivary protein complex (SPC)

A new polymorphism, Pc, has been identified in human saliva. Two proteins, Pc 1 and Pc 2, are determined by alleles Pc1 and Pc2, respectively, which show autosomal codominant inheritance. No null phenotype has been encountered in 225 randomly collected salivas. The frequencies of the two alleles differ in the Black and White American populations, with Pc1 and Pc2 being 0.670 and 0.330 in the Black (N = 47) and 0.461 and 0.539 in the White (N = 178) populations, respectively. The alleles are in equilibrium in the two populations and segregation analyses (30 families) do not suggest the existence of a null allele in either population. Of seven polymorphic human salivary proteins determined by genes in the salivary protein complex (SPC), Pc phenotypes show association only with Ps phenotypes. Based on that association, our linkage studies, and the biochemical similarities with other SPC proteins, we tentatively conclude that Pc is a member of the SPC, bringing the total number of genes in that group to 13.     

Expression of human salivary protein genes

Human proline-rich proteins (PRPs) are polymorphic, homologous in sequence, and linked in a cluster called the human salivary protein complex (SPC). Recently this complex was localized to human chromosome band 12p13.2 (Mamulaet al., Cytogenet. Cell Genet. 39:279, 1985). We have isolated a PRP cDNA, EO27, from a human parotid gland library, identified it by DNA sequencing, and used it to study the molecular and cellular biology of PRP production. Cell-free translation and mRNA characterization with EO27 indicate that the numerous PRPs seen in saliva are produced from relatively few, large precursors, probably by posttranslational cleavage. This supports an hypothesis originally proposed by Friedman and Karn in 1977 (Am. J. Hum. Genet. 29:44A;Biochem. Genet. 15:549) and later supported by biochemical studies (Karnet al., Biochem Genet. 17:1061, 1979) and molecular studies (Mamulaet al., Fed. Proc. 43:1522, 1984; Maedaet al., J. Biol. Chem. 260:1123, 1985). EO27 was also used in this study to localize PRP mRNA production to the acinar cells of the parotid gland byin situ hybridization.     

Chromosomal localization of three human poly(A)-binding protein genes and four related pseudogenes

In humans, the poly(A)-binding proteins (PABPs) comprise a small nuclear isoform and a conserved gene family that displays at least three functional proteins: PABP1, inducible PABP (iPABP), and PABP3, plus four pseudogenes (1, 2, 3, and PABP4). In situ hybridization of PABP3 cDNA as the probe on metaphasic chromosomes have revealed five possible loci for this gene family at 2q21-q22, 13q11-q12, 12q13.3-q15, 8q22, and 3q24-q25. Amplifications of specific DNA fragments from a human-rodent somatic cell hybrid panel have allowed us to associate PABP1 and PABP3 with 8q22 and 13q11-q12, respectively. The iPABP gene has been assigned to chromosome 1. This result, compared with radiation hybrid database information, strengthens the location of this gene to 1p32-p36. The pseudogenes PABP4, 1, and 2 have been assigned to chromosomes 15, 4, and 14, respectively. Three loci detected on chromosome spreads are not associated with any amplified fragment. They might represent other related PABP genes not yet identified.     

Human salivary proline-rich protein genes on chromosome 12.

A DNA probe (PRP1) for the proline-rich protein (PRP) genes was used to analyze the segregation of human PRP genes in human X mouse somatic cell hybrids. Endonuclease restriction analysis of 22 independent hybrid clones segregating human chromosomes demonstrated that PRP genes segregate with human chromosome 12 only and were therefore assigned to that chromosome. The PRP1 probe should prove useful for further mapping studies of human chromosome 12.     

The binding of calcium to a salivary phosphoprotein, protein C, and comparison with calcium binding to protein A, a related salivary phosphoprotein.

The binding of Ca2+ to a salivary phosphoprotein, protein C, was studied by equilibrium dialysis. In 5mM-Tris/HCl buffer, pH 7.5, protein C bound 190 nmol of Ca2+/mg of protein. The apparent dissociation constant, K, was determined to be 1.9 x 10(-4)M and the binding of Ca2+ to the protein was non-co-operative. The binding of Ca2+ to protein C apparently depends on groups which ionize above pH 5.0. Ca2+ binding decreased with increased concentration of the dialysis buffer and on addition of SrCL2, MgCl2 and MnCl2 to the dialysis buffer. Digestion of protein C with trypsin or collagenase or heating of the protein to 60 degrees or 100 degrees C had little or no effect on the Ca2+ binding. Digestion of protein C with alkaline phosphatase caused a decrease in the amount of protein-bound Ca2+. This was also found for another salivary phosphoprotein, protein A. In the absence of Ca2+ the S020,w for protein C was 1.29 S and in the presence of Ca2+ it was 1.46S. Ca2+ may cause a conformational change in the protein or an aggregation of the protein molecules. No conformational changes of protein C in the presence of Ca2+ could be detected by circular dichroism or nuclear magnetic resonance.     

Identification of a processed protein related to the human chaperonins (hsp 60) protein in mammalian kidney.

The chaperonin family of proteins, which includes GroEL protein of E. coli, yeast heat shock protein (hsp-60) and the ribulose-1-5-bisphosphate carboxylase (Rubis Co.) subunit binding protein of plant chloroplasts, shows strong sequence homology to the Chinese hamster ovary (CHO) mitochondrial P1 protein. We have identified a 60 kDa protein from bovine kidney which by N-terminal sequencing gives the amino acid sequence AKDVKFGADARALLMLQGVDLLADA. Bovine whole kidney membranes were delipidated, solubilized with octyl glucoside and fractionated over an affinity column using the amiloride analog 5-N pyrazine amiloride as the ligand. After extensive washing with 200 mM NaCl, the column was eluted with pH 4.0 buffer. Analysis of column fractions on a 7.5% polyacrylamide gel revealed 3-4 bands with a predominant band at 60,000 Da. Amino acid analysis after transfer to immobilon membranes demonstrated sequence identity to the human HSP (60), extending 24 amino acids from the N-terminus, but lacking the leader sequence. These data indicate that a processed form of a protein related to the human HSP (60) chaperonin is associated with a membrane fraction in the mammalian kidney, and that the processed form of the protein binds strongly to an amiloride affinity support.     

Identification of the human herpesvirus 6 glycoprotein H and putative large tegument protein genes.

Determination of the nucleotide sequences of two molecular clones of human herpesvirus 6 (HHV-6) (strain GS) and comparison with those of human cytomegalovirus (HCMV) has allowed the identification of the genes for the glycoprotein H (gH) and the putative large tegument protein of HHV-6. Two molecular clones of fragments of HHV-6, the BamHI-G fragment (7,981 bp) of the clone termed pZVB43 and a HindIII fragment (8,717 bp) of the clone termed pZVH14, represent approximately 10% of the HHV-6 genome (16,689). An open reading frame within the BamHI-G fragment was designated the gH gene of HHV-6 because of the extensive sequence similarity of its predicted product (79,549 Da) to the HCMV gH gene product. The predicted product (239,589 Da) of an open reading frame within clone pZVH14 showed homology to the predicted product of the proposed gene of HCMV representing the large tegument protein. Computer analyses indicated a closer relationship of the predicted peptides of these HHV-6 genes to those of HCMV than to those of the other human herpesviruses Epstein-Barr virus, herpes simplex virus type 1, and varicella-zoster virus. The gH gene was more conserved among the human herpesvirus group, while significant sequence similarity of the tegument gene could be found only with that of HCMV. The data reported here with one conserved gene (gH) and a more divergent gene (tegument) support previous reports that HHV-6 and HCMV are more closely related to each other than to the other well-characterized human herpesviruses.     

Tracing the evolution of a large protein complex in the eukaryotes, NADH:ubiquinone oxidoreductase (Complex I)

The increasing availability of sequenced genomes enables the reconstruction of the evolutionary history of large protein complexes. Here, we trace the evolution of NADH:ubiquinone oxidoreductase (Complex I), which has increased in size, by so-called supernumary subunits, from 14 subunits in the bacteria to 30 in the plants and algae, 37 in the fungi and 46 in the mammals. Using a combination of pair-wise and profile-based sequence comparisons at the levels of proteins and the DNA of the sequenced eukaryotic genomes, combined with phylogenetic analyses to establish orthology relationships, we were able to (1) trace the origin of six of the supernumerary subunits to the alpha-proteobacterial ancestor of the mitochondria, (2) detect previously unidentified homology relations between subunits from fungi and mammals, (3) detect previously unidentified subunits in the genomes of several species and (4) document several cases of gene duplications among supernumerary subunits in the eukaryotes. One of these, a duplication of N7BM (B17.2), is particularly interesting as it has been lost from genomes that have also lost Complex I proteins, making it a candidate for a Complex I interacting protein. A parsimonious reconstruction of eukaryotic Complex I evolution shows an initial increase in size that predates the separation of plants, fungi and metazoa, followed by a gradual adding and incidental losses of subunits in the various evolutionary lineages. This evolutionary scenario is in contrast to that for Complex I in the prokaryotes, for which the combination of several separate, and previously independently functioning modules into a single complex has been proposed.     

Genetic studies of human acidic salivary protein (Pa).

The phenotypic expression of a dominantly inherited human salivary acidic protein (Pa) has been described in acid-urea starch and in Tris-borate acrylamide gel systems. Estimates of the Pa+ allelic frequencies in American Caucasians, American blacks, and Orientals are .21, .14, and .42, respectively. The genetic and biochemical similarities to another series of proline-rich salivary proteins, Pr, and to a pair of similarly staining salivary proteins, Db (double band), are evaluated. It is concluded that either one locus or two (or three) tightly linked loci are viable explanations for this polymorphic system(s). It is suggested that the three factors, Pa, Pr, and Db, be treated as separate loci to allow clarification of their genetic relationships.     

Molecular determinants of voltage-dependent human ether-a-go-go related gene (HERG) K+ channel block

The structural determinants for the voltage-dependent block of ion channels are poorly understood. Here we investigate the voltage-dependent block of wild-type and mutant human ether-a-go-go related gene (HERG) K(+) channels by the antimalarial compound chloroquine. The block of wild-type HERG channels expressed in Xenopus oocytes was enhanced as the membrane potential was progressively depolarized. The IC(50) was 8.4 +/- 0.9 microm when assessed during 4-s voltage clamp pulses to 0 mV. Chloroquine also slowed the apparent rate of HERG deactivation, reflecting the inability of drug-bound channels to close. Mutation to alanine of aromatic residues (Tyr-652 or Phe-656) located in the S6 domain of HERG greatly reduced the potency of channel block by chloroquine (IC(50) > 1 mm at 0 mV). However, mutation of Tyr-652 also altered the voltage dependence of the block. In contrast to wild-type HERG, block of Y652A HERG channels was diminished by progressive membrane depolarization, and complete relief from block was observed at +40 mV. HERG channel block was voltage-independent when the hydroxyl group of Tyr-652 was removed by mutating the residue to Phe. Together these findings indicate a critical role for Tyr-652 in voltage-dependent block of HERG channels. Molecular modeling was used to define energy-minimized dockings of chloroquine to the central cavity of HERG. Our experimental findings and modeling suggest that chloroquine preferentially blocks open HERG channels by cation-pi and pi-stacking interactions with Tyr-652 and Phe-656 of multiple subunits.     

The human mitochondrial ribosomal protein genes: mapping of 54 genes to the chromosomes and implications for human disorders.

Mitochondria possess their own translational machinery, which is composed of components distinct from their cytoplasmic counterparts. To investigate the possible involvement of mitochondrial ribosomal defects in human disease, we mapped nuclear genes that encode mitochondrial ribosomal proteins (MRPs). We generated sequence-tagged sites (STSs) of individual MRP genes that were able to be detected by PCR. They were placed on an STS content map of the human genome by typing of radiation hybrid panels. We located 54 MRP genes on the STS-content map and assigned these genes to cytogenetic bands of the human chromosomes. Although mitochondria are thought to have originated from bacteria, in which the genes encoding ribosomal proteins are clustered into operons, the mapped MRP genes are widely dispersed throughout the genome, suggesting that transfer of each MRP gene to the nuclear genome occurred individually. We compared the assigned positions with candidate regions for mendelian disorders and found certain genes that might be involved in particular diseases. This map provides a basis for studying possible roles of MRP defects in mitochondrial disorders.     

Identification of a human cytoplasmic poly(A) nuclease complex stimulated by poly(A)-binding protein

The poly(A) tail shortening in mRNA, called deadenylation, is the first rate-limiting step in eukaryotic mRNA turnover, and the polyadenylate-binding protein (PABP) appears to be involved in the regulation of this step. However, the precise role of PABP remains largely unknown in higher eukaryotes. Here we identified and characterized a human PABP-dependent poly(A) nuclease (hPAN) complex consisting of catalytic hPan2 and regulatory hPan3 subunits. hPan2 has intrinsically a 3' to 5' exoribonuclease activity and requires Mg2+ for the enzyme activity. On the other hand, hPan3 interacts with PABP to simulate hPan2 nuclease activity. Interestingly, the hPAN nuclease complex has a higher substrate specificity to poly(A) RNA upon its association with PABP. Consistent with the roles of hPan2 and hPan3 in mRNA decay, the two subunits exhibit cytoplasmic co-localization. Thus, the human PAN complex is a poly(A)-specific exoribonuclease that is stimulated by PABP in the cytoplasm.     

Kinetoplastid RNA-editing-associated protein 1 (REAP-1): a novel editing complex protein with repetitive domains.

Kinetoplastid RNA editing consists of the addition or deletion of uridines at specific sites within mitochondrial mRNAs. This unusual RNA processing event is catalyzed by a ribonucleoprotein (RNP) complex that includes editing site-specific endoribonuclease, RNA ligase and terminal uridylnucleotidyl transferase (Tutase) among its essential enzymatic activities. To identify the components of this RNP, monoclonal antibodies were raised against partially purified editing complexes. One antibody reacts with a mitochondrially located 45 kDa polypeptide (p45) which contains a conserved repetitive amino acid domain. p45 co-purifies with RNA ligase and Tutase in a large ( approximately 700 kDa) RNP, and anti-p45 antibody inhibits in vitro RNA editing. Thus, p45 is the first kinetoplastid RNA-editing-associated protein (REAP-1) that has been cloned and identified as a protein component of a functional editing complex.