Sequence and expression of the SerJ immobilization antigen gene of Tetrahymena thermophila regulated by dominant epistasis

In ciliates, variable surface protein genes encoding the immobilization antigen (-ag) are expressed under different environmental conditions, including temperature and salt stress. These i-ags are GPI-linked and coat the entire external surface of the cell, including the cilia. In Tetrahymena thermophila-ag in natural isolates is the result of dominant epistasis masking the expression of the H i-ag ordinarily expressed at 20-36 degrees C. This report describes the expression and sequence of the Ser-ag. J is present on the cell surface up to 38 degrees C; above 38 degrees C SerSeranked by an A-rich 5' UTR and a 3' UTR containing putative mRNA destabilization motifs. The encoded J polypeptide consists of 438 amino acids and is rich in alanine, cysteine, serine and threonine. The N- and resemble signal peptide and GPI-anchor addition sites, respectively. The majority of the molecule consists of four imperfect repeats with 10 periodic cysteines per repeat in the pattern CX(6)CX(2)CX(21)CX(4)CX(13-15)CX(2)CX(18)CX(3)CX(11)CX(9-10). Although H i-ags encoded by paralogous SerH genes have 3.5 imperfect repeats with eight periodic cysteines per repeat, J nevertheless resembles H with respect to amino acid composition, codon usage, N- and C-termini, the arrangement of the cysteine periods, and regulation by mRNA stability. However, despite these similarities and epistasis, the evolutionary relationship between SerH and SerJ is unclear.     

Multiple Effects of Mutation on Expression of Alternative Cell Surface Protein Genes in Tetrahymena Thermophila

Genes at the SerH locus of the ciliated protist Tetrahymena thermophila specify the major (H) surface protein on cells grown at 20-36 degrees. Alternative proteins L, T, S and I are expressed under different conditions of temperature and culture media. Mutants unable to express SerH genes were examined for expression of these proteins, also called immobilization or i-antigens, at both H and non-H conditions. In all instances, one or more i-antigens were expressed in the absence of H, and, in most instances, expression of i-antigens under non-H conditions was also affected. Examples of the latter include both the continued expression of H-replacement antigens and the inability to express certain other i-antigens. Such multiple effects were observed in mutants with trans-acting (rseA, rseB, rseC, RseD) and cis-acting (H1-1 and H1-2) mutations, but not in mutants in which SerH is affected developmentally (B2092, B2101, B2103, B2107). These interactions suggest that the wild-type genes identified by mutation exert both positive and negative effects in the regulation of i-antigen gene expression.     

Highly divergent sequences of the pollen self-incompatibility (S) gene in class-I S haplotypes of Brassica campestris (syn. rapa) L

Self-incompatibility (SI) enables flowering plants to discriminate between self- and non-self-pollen. In Brassica, SI is controlled by the highly polymorphic S locus. The recently identified male determinant, termed SP11 or SCR, is thought to be the ligand of S receptor kinase, the female determinant. To examine functional and evolutionary properties of SP11, we cloned 14 alleles from class-I S haplotypes of Brassica campestris and carried out sequence analyses. The sequences of mature SP11 proteins are highly divergent, except for the presence of conserved cysteines. The phylogenetic trees suggest possible co-evolution of the genes encoding the male and female determinants.     

A Temperature-Sensitive Mutation of the Temperature-Regulated Serh3 I-Antigen Gene of Tetrahymena Thermophila: Implications for Regulation of Mutual Exclusion

The Ser genes of Tetrahymena thermophila specify alternative forms of a major cell surface glycoprotein, the immobilization or i-antigen (i-ag). Regulation of i-ag expression assures that at least one i-ag gene is expressed at all times. To learn more about the regulatory system and the possible role of i-ag itself, we studied SerH3-ts1, a temperature-sensitive allele of the temperature-regulated SerH3 gene normally expressed from 20-36°. In homozygotes grown at the nonpermissive temperature (>32°), H3 is not present on the cell surface, but the gene continues to be transcribed until its 36° cutoff. H3 formed at the permissive temperature is stable at nonpermissive temperatures, indicating that SerH3-ts1 is temperature-sensitive for synthesis rather than function. At nonpermissive temperatures, the S i-ag is expressed in place of H3. This result suggests that normal H protein may play a role in regulating S expression. SerH3-ts1 was isolated following mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Sequencing of SerH3-ts1 revealed a single A -> G transition at nucleotide 473, resulting in the substitution of glycine for aspartate. The affected residue is conserved in the internal repeats comprising the H protein, and the charge difference correlates with changes in electrophoretic mobility of the H3 protein.     

Nucleo-cytoplasmic interaction during macronuclear differentiation in ciliate protists: genetic basis for cytoplasmic control of SerH expression during macronuclear development in Tetrahymena thermophila

A novel class of mutations affecting the developmental expression of SerH cell surface antigen genes of Tetrahymena thermophila is described. Unlike previous categories of mutation, the four independently isolated mutations of this class act through the cytoplasm to affect SerH genes during macronuclear development. That is, macronuclei which develop under the influence of mutant cytoplasm do not subsequently express H, most likely because the developmental processing of SerH genes is affected. The cytoplasmic effect is specific for the SerH locus and is independent of which SerH allele is present. In place of H, hitherto unknown antigens are expressed. Expression of SerH can be rescued during development either by wild-type cytoplasm exchanged between conjugants or by the homozygous wild-type genotype. The mutations segregate independently of the SerH genes and identify one, possibly two, bistable genes. Possible models to explain these results are discussed.     

Isolation and Genetic Analysis of Mutations at the SerH Immobilization Antigen Locus of TETRAHYMENA THERMOPHILA

Multiple alleles at the SerH locus specify the major cell surface protein (immobilization antigen) of the ciliate Tetrahymena thermophila. Following mutagenesis of SerH1 homozygotes, two mutations, H1-1 and H1-2, were recovered in heterozygous form. Mutant homozygotes do not express H1 antigen, nor is H1 expressed in F1 progeny of crosses to wild-type strains homozygous for SerH2 or SerH3. H1-1 and H1-2 segregate without recombination from these wild-type alleles in expected F2 and testcross Mendelian ratios. H1-1 and H1-2 do, however, complement each other to express H1 antigen. Experiments suggest this complementation is due neither to recombination during macronuclear development nor to interallelic complementation of defective SerH1 gene products. These results suggest that SerH1 is intact in one mutant, and possibly both, although no such allele has been segregated in testcross progeny (N = 205). The hypothesis is presented that complementation between H1-1 and H1-2 is due to interaction between allele-specific regulators closely linked to the SerH1 gene.     

Comparative analysis of S haplotypes with very similar SLG alleles in Brassica rapa and Brassica oleracea

Self-incompatibility in Brassica is controlled by a single multi-allelic locus (the S locus) which harbors at least two highly polymorphic genes, SLG and SRK. SRK is a putative transmembrane receptor kinase and its amino acid sequence of the extracellular domain of SRK (the S domain) exhibits high homology to that of SLG. The amino acid sequences of the SLGs of S8 and S46 haplotypes of B. rapa are very similar and those of S23 and S29 haplotypes of B. oleracea were also found to be almost identical. In both cases, SLG and the S domain of SRK of the same haplotype were less similar. This seems to contradict the idea that SLG and SRK of the same haplotype have the same self-recognition specificity. In the transmembrane-kinase domain, the SRK alleles of the S8 and S46 haplotypes had almost identical nucleotide sequences in spite of their lower homology in the S domain. Such a cluster of nucleotide substitutions is probably due to recombination or related events, although recombination in the S locus is thought to be suppressed. Based on our observations, the recognition mechanism and the evolution of self-incompatibility in Brassica are discussed.     

Isolation and characterization of cDNA clones corresponding to two different human apoC-III alleles

We have recently reported that the human apolipoprotein A-I (apoA-I) and apolipoprotein C-III (apoC-III) genes are physically linked and that the presence of a DNA insertion in the apoA-I gene is correlated with apoA-I-apoC-III deficiency in patients with premature atherosclerosis. In addition, the presence of a polymorphic restriction endonuclease site (SacI) in the 3' noncoding region of apoC-III mRNA has been correlated with hypertriglyceridemia in humans. In this study, we report the isolation and characterization of cDNA clones containing the entire apoC-III mRNA coding sequence. The nucleotide-derived apoC-III amino acid sequence indicates that the apoC-III primary translational product contains a 20 amino acid N-terminal extension, which conforms with the general properties of known signal peptides, and is highly homologous to the recently reported rat apoC-III signal peptide. The DNA-derived apoC-III amino acid sequence differs from the previously reported apoC-III amino acid sequence at four amino acid residues. More specifically, at positions +32, +33, +37, +39, the DNA sequence predicts Glu, Ser, Gln, Ala, respectively, while the previously reported sequence specifies Ser, Gln, Ala, Gln, respectively. Finally, isolation and characterization of apoC-III cDNA clones, with or without the polymorphic SacI restriction site, indicated that the apoC-III nucleotide sequence corresponding to the Sac+ and Sac- clones differs at three nucleotide sites; however, the amino acid sequence specified by the Sac+ and Sac- alleles is identical.     

Exon variability of gene encoding glycerol-3-phosphate dehydrogenase of Ixodes ricinus ticks

We have previously found apparent differences in Gpdh allele frequences between borrelia infected and uninfected Ixodes ricinus as revealed by native gel electrophoresis of allozyme polymorphisms. The present study deals with the genetic basis of the observed allozyme polymorphism. Multiple sequence alignment of 36 Gpdh open reading frames identified a total of 40 polymorphic nucleotide sites. Of the 40 polymorphic nucleotide sites, 34 were silent (did not result in amino acid residue change), while six were active causing a change in the amino acid chain. All polymorphic amino acid sites were situated within the N-terminal NAD-binding domain, whereas the C-terminal substrate-binding domain was highly conserved. Analysis of the obtained Gpdh sequences and GPDH allozyme polymorphisms for individual ticks pointed to amino acid changes at positions 61 (glycine-to-glutamic acid), 64 (serine-to-cysteine) and 102 (glycine-to-arginine) as a key for differential mobility of GPDH allozymes in an electric field. Our findings are discussed in the context of the molecular basis of I. ricinus host finding behavior.     

The MHC E locus in macaques is polymorphic and is conserved between macaques and humans

Although the functions of the molecules encoded by the classical MHC class I loci are well defined, no function has been ascribed to the molecules encoded by the non-classical MHC class I loci. To investigate the evolution and conservation of the non-classical loci, we cloned and sequenced HLA-E homologues in macaques. We isolated four E locus alleles from five rhesus monkeys and two E locus alleles from one cynomolgus monkey, which indicated that the E locus in macaques is polymorphic. We also compared the rate of nucleotide substitution in the second intron of the macaque and human E locus alleles with that of exons two and three. The rate of nucleotide substitution was significantly higher in the introns, which suggested that the E locus has evolved under selective pressure. Additionally, comparison of the rates of synonymous and non-synonymous substitutions in the peptide binding region versus the remainder of the molecule suggested that the codons encoding the amino acids in the peptide binding region had been conserved in macaques and humans over the 36 million years since macaques and humans last shared a common ancestor.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers UO2976–UO2981     

Comparisons of the complete sequences of two collagen genes from Caenorhabditis elegans

Several collagen genes have been isolated from the nematode Caenorhabditis elegans. The complete nucleotide sequences of two of these genes, col-1 and col-2, have been determined. These collagen genes differ from vertebrate collagen genes in that they contain only one or two introns, their triple-helical regions are interrupted by nonhelical amino acid sequences and they are smaller. A high degree of nucleotide and amino acid homology exists between col-1 and col-2. In particular, the regions around cysteines and lysines are most highly conserved. The C. elegans genome contains 50 or more collagen genes, the majority of which probably encode cuticle collagens; col-1 and col-2 apparently are members of this large family of cuticle collagen genes.     

Reproducible and variable rearrangements of a Tetrahymena thermophila surface protein gene family occur during macronuclear development.

The expression of Tetrahymena surface proteins serotype H3 (SerH3) and serotype T (SerT) is under environmental regulation. SerH3 is expressed when cells are incubated between the temperatures of 20 and 35 degrees C, while SerT is expressed when cells are grown at temperatures above 35 degrees C. Using a SerH3 cDNA clone as a hybridization probe, we determined that (i) the SerH3 gene is a member of a multigene family; (ii) most members of this multigene family are variably rearranged during macronuclear development; and (iii) the gene which produces the SerH3 mRNA is reproducibly rearranged during macronuclear development.     

A novel zinc finger is required for Mcm10 homocomplex assembly

Mcm10 is a DNA replication factor that interacts with multiple subunits of the MCM2-7 hexameric complex. We report here that Mcm10 self-interacts and assembles into large homocomplexes (approximately 800 kDa). A conserved domain of 210 amino acid residues is sufficient for mediating self-interaction and complex assembly. A novel zinc finger within the conserved domain, CX10CX11CX2H, is essential for the homocomplex formation. Mutant alleles with amino acid substitutions at conserved cysteines and histidine in the zinc finger fail to assemble homocomplexes. A defect in homocomplex assembly correlates with defects in DNA replication and cell growth in the mutants. These observations suggest that homocomplex assembly is essential for Mcm10 function. Multisubunit Mcm10 homocomplexes may provide the structural basis for Mcm10 to interact with multiple subunits of the MCM2-7 hexamer.     

Cloning and complete sequence of an HLA-A2 gene: analysis of two HLA-A alleles at the nucleotide level

The gene for the HLA-A2 antigen has been cloned from the human lymphoblastoid cell line 721. Comparison of this sequence with the published sequence for HLA-A3 permits the examination of two alleles at the extremely polymorphic HLA-A locus. A high degree of sequence conservation was seen in both coding and noncoding DNA, 97.2% and 94.5%, respectively. Interestingly, the 3' untranslated region was the most conserved, with 99.5% homology. The polymorphism of the HLA-A antigens results from a high proportion of amino acid substitutions relative to the total nucleotide changes in exons 2 and 3. Unlike the clustered differences seen in this region on comparison of two H-2K alleles of mouse, nucleotide substitutions between the HLA-A2 and A3 alleles are evenly distributed. Substitutions at silent sites and within introns were used to calculate an intra-allelic divergence time of at least 10 to 15 million years for these two HLA-A alleles.     

Allelic variation of ovine MHC class II DQA1 and DQA2 genes

In the present study we characterize allelic variation of polymorphic OLA-DQA1 and OLA-DQA2 genes in sheep. To achieve this, PCR primers were designed to independently amplify the second exons of OLA-DQA1 and OLA-DQA2 genes. Single strand conformation polymorphism (SSCP) gel analyses reveals that there are at least 12 distinct OLA-DQA2 sequences, 10 of which have been characterized by sequencing. Six distinct OLA-DQA1 alleles have been sequenced in sheep and we can detect at least seven DQA1 alleles, including a null allele, by SSCP analysis. The second exon of the OLA-DQA2 gene is more polymorphic than the equivalent region of the OLA-DQA1 gene. Thirty-two per cent of nucleotide and 49% of amino acid sites showed variation at the DQA2 locus, compared to 20% of nucleotide and 33% of amino acid sites for DQA1 . Phylogenetic analysis of DQA sequences from a number of species show that sheep DQA1 sequences group together and are more similar to bovine DQA1 sequences than to sheep DQA2 alleles. The majority of OLA-DQA2 sequences are on the same main branch of the phylogenetic tree as bovine DQA2 sequences. However, three sheep DQA2 sequences have a tendency to group with putative bovine DQA3 sequences rather than to other ovine DQA2 alleles. A variety of SSCP gel conditions were tried in order to develop a typing system for the OLA-DQA2 gene. We describe a set of PCR and SSCP conditions which distinguish between all known OLA-DQA2 alleles.     

Expression pattern and raft association of NIPSNAP3 and NIPSNAP4, highly homologous proteins encoded by genes in close proximity to the ATP-binding cassette transporter A1

The highly homologous genes NIPSNAP3 and NIPSNAP4, with 87% amino acid identity, are members of the NIPSNAP family with putative roles in vesicular trafficking. NIPSNAP3 mRNA and NIPSNAP4 mRNA and protein were detected in multiple tissues and cells at varying degrees. Interestingly, NIPSNAP3 is most highly expressed in skeletal muscle, where NIPSNAP4 has a low mRNA abundance. NIPSNAP4 was found associated with membranes and partly localized in rafts. The ubiquitous expression of the highly conserved NIPSNAPs and their association with membranes further support an important cellular function of these proteins probably linked to vesicular trafficking. The NIPSNAP3 and NIPSNAP4 genes are located in close proximity to the 3' end of the ATP-binding cassette transporter A1 (ABCA1), whose mutations cause familial high-density lipoprotein deficiency syndromes. The adjacent genomic location and the finding that ABCA1 is a regulator of vesicular trafficking may indicate a functional relation of these proteins, even though NIPSNAP4 does not interact directly with ABCA1 nor is its expression altered in cells with mutated ABCA1.     

Structure of a duck H3 variant histone gene: a H3 subtype with four cysteine residues

A duck recombinant DNA phage library was screened for H3 histone genes, and the sequence of a variant H3 gene, which appears not to be part of a histone gene cluster, has been determined. As derived from the nucleotide sequence, this gene codes for a 135-amino acid (aa) protein (as any other H3) and shows 10 aa substitutions compared with most published H3 structures. Six of these aa changes are based on one nucleotide (nt) substitutions in arginine codons. This results in three new histidines and, in addition to the highly conserved cysteine at position 110, three more cysteines are found in this H3 histone subtype.     

Human plasma apolipoproteins A-IV-0 and A-IV-3. Molecular basis for two rare variants of apolipoprotein A-IV-1

Human apolipoprotein (apo) A-IV is a polymorphic plasma protein controlled by two codominant alleles at a single genetic locus. Thus far, five different isoproteins (apoA-IV-0 to apoA-IV-4) have been described in Caucasians. We have recently identified the nucleotide and amino acid substitutions that are the basis for the most common isoproteins, apoA-IV-1 and apoA-IV-2. In this report, the mutations producing the two rare isoproteins apoA-IV-0 and apoA-IV-3 are described. Analysis of the apoA-IV-0 allele revealed an insertion of 12 nucleotides in a carboxyl-terminal region, which is highly conserved among human, rat, and mouse A-IV apolipoproteins. This in-frame insertion of the 4 amino acids Glu-Gln-Gln-Gln between residues 361 and 362 of the mature protein produces the 1 charge unit more acidic apoA-IV-0 isoprotein (pI 4.92). In the apoA-IV-3 allele we identified a single G to A substitution that converts the glutamic acid (GAG) at position 230 of the mature protein to a lysine (AAG), thus adding 2 positive charge units to the apoA-IV-1 isoprotein (pI 4.97) and forming the more basic apoA-IV-3 isoprotein (pI 5.08). Comparison with the mouse and rat A-IV apolipoproteins revealed that this residue, located at position 4 of the 10th/11th amphiphilic alpha-helical repeat, is also highly conserved in evolution.     

Evidence for the requirement of protein synthesis and protein kinase activity in the temperature regulated stability of a Tetrahymena surface protein mRNA.

In Tetrahymena thermophila, the expression of the temperature-specific surface protein SerH3 is controlled primarily by a temperature-dependent change in the stability of its mRNA. The change in SerH3 mRNA stability occurs very rapidly after a shift in incubation temperature. This change in temperature could affect SerH3 mRNA stability directly by producing structural changes in the mRNA or regulatory factors acting on SerH3 mRNA. Alternatively, the temperature change could act indirectly through a signal transduction pathway leading to de novo synthesis of new regulatory factors or modifications of existing regulatory factors. To address these issues, we monitored the effect of temperature on an in vitro SerH3 mRNA decay assay and the in vivo effects of a variety of inhibitors against protein synthesis and protein kinases on SerH3 mRNA stability. The results of Northern analysis of SerH3 mRNAs in an in vitro mRNA decay assay indicate that temperature alone can not change the half-life of this mRNA. Furthermore, slot blot analysis of cytoplasmic RNAs show that protein synthesis and the action of protein kinases are not required for SerH3 mRNA turnover in cells grown at 30 degrees C. In contrast, our results indicate that the rapid decay of the SerH3 mRNA in cells grown at 30 degrees C and shifted to 40 degrees C requires a one time serine/threonine phosphorylation event which occurs at the temperature shift. In addition, the data show that a regulatory protein involved in rapid SerH3 mRNA decay must be newly and continuously synthesized following the temperature shift from 30 to 40 degrees C. These data show the complexity of temperature regulated mRNA decay and indicate that phosphorylation and protein synthesis are major factors in this process.