Intronless Open Reading Frame Research Articles

TaTGW6-A1, an ortholog of rice TGW6, is associated with grain weight and yield in bread wheat

The TGW6 gene encodes a novel indole-3-acetic acid-glucose hydrolase and plays a significant role in improving thousand grain weight (TGW) and yield in rice. In the current study, a TGW6 ortholog from bread wheat chromosome 3AL was isolated and designated as TaTGW6-A1. Sequencing and alignment analysis showed that the cloned TaTGW6-A1 consists of a 987-bp intronless open reading frame. Three single-nucleotide polymorphisms (SNPs) were identified between cultivars with higher and lower TGW, forming two haplotypes, TaTGW6-A1a and TaTGW6-A1b. A derived cleaved amplified polymorphic sequence marker, TaTGW6-A1-CAPS, was developed to differentiate the two haplotypes. Linkage analysis using the wheat 90K iSelect SNP array mapped TaTGW6-A1-CAPS at 18 cM from BobWhite_c47304_56 in a RIL population derived from Zhou 8425B/Chinese Spring. A QTL for yield at the TaTGW6-A1 locus explained 17.4 % of the phenotypic variance in average yield over four environments. Association analysis on 242 Chinese and foreign cultivars indicated that TaTGW6-A1 was significantly associated with TGW. The cumulative frequency of the TaTGW6-A1a allele associated with higher TGW was approximately 80 %, indicating that the TaTGW6-A1a allele was positively selected in wheat breeding. In conclusion, TaTGW6-A1 in conjunction with its molecular marker may contribute as a valuable gene in improving yield potential in wheat.

A GRAS‐like gene of sunflower (Helianthus annuus L.) alters the gibberellin content and axillary meristem outgrowth in transgenic Arabidopsis plants

The GRAS proteins belong to a plant transcriptional regulator family that function in the regulation of plant growth and development. Despite their important roles, in sunflower only one GRAS gene (HaDella1) with the DELLA domain has been reported. Here, we provide a functional characterisation of a GRAS-like gene from Helianthus annuus (Ha-GRASL) lacking the DELLA motif. The Ha-GRASL gene contains an intronless open reading frame of 1,743 bp encoding 580 amino acids. Conserved motifs in the GRAS domain are detected, including VHIID, PFYRE, SAW and two LHR motifs. Within the VHII motif, the P-H-N-D-Q-L residues are entirely maintained. Phylogenetic analysis reveals that Ha-GRASL belongs to the SCARECROW LIKE4/7 (SCL4/7) subfamily of the GRAS consensus tree. Accumulation of Ha-GRASL mRNA at the adaxial boundaries from P6/P7 leaf primordia suggests a role of Ha-GRASL in the initiation of median and basal axillary meristems (AMs) of sunflower. When Ha-GRASL is over-expressed in Arabidopsis wild-type plants, the number of lateral bolts increases differently from untransformed plants. However, Ha-GRASL slightly affects the lateral suppressor (las-4-) mutation. Therefore, we hypothesise that Ha-GRASL and LAS are not functionally equivalent. The over-expression of Ha-GRASL reduces metabolic flow of gibberellins (GAs) in Arabidopsis and this modification could be relevant in AM development. Phylogenetic analysis includes LAS and SCL4/7 in the same major clade, suggesting a more recent separation of these genes with respect to other GRAS members. We propose that some features of their ancestor, as well as AM initiation and outgrowth, are partially retained in both LAS and SCL4/7.

Arylamine N‐acetyltransferases: from drug metabolism and pharmacogenetics to drug discovery

Arylamine N-acetyltransferases (NATs) are polymorphic drug-metabolizing enzymes, acetylating arylamine carcinogens and drugs including hydralazine and sulphonamides. The slow NAT phenotype increases susceptibility to hydralazine and isoniazid toxicity and to occupational bladder cancer. The two polymorphic human NAT loci show linkage disequilibrium. All mammalian Nat genes have an intronless open reading frame and non-coding exons. The human gene products NAT1 and NAT2 have distinct substrate specificities: NAT2 acetylates hydralazine and human NAT1 acetylates p-aminosalicylate (p-AS) and the folate catabolite para-aminobenzoylglutamate (p-abaglu). Human NAT2 is mainly in liver and gut. Human NAT1 and its murine homologue are in many adult tissues and in early embryos. Human NAT1 is strongly expressed in oestrogen receptor-positive breast cancer and may contribute to folate and acetyl CoA homeostasis. NAT enzymes act through a catalytic triad of Cys, His and Asp with the architecture of the active site-modulating specificity. Polymorphisms may cause unfolded protein. The C-terminus helps bind acetyl CoA and differs among NATs including prokaryotic homologues. NAT in Salmonella typhimurium supports carcinogen activation and NAT in mycobacteria metabolizes isoniazid with polymorphism a minor factor in isoniazid resistance. Importantly, nat is in a gene cluster essential for Mycobacterium tuberculosis survival inside macrophages. NAT inhibitors are a starting point for novel anti-tuberculosis drugs. Human NAT1-specific inhibitors may act in biomarker detection in breast cancer and in cancer therapy. NAT inhibitors for co-administration with 5-aminosalicylate (5-AS) in inflammatory bowel disease has prompted ongoing investigations of azoreductases in gut bacteria which release 5-AS from prodrugs including balsalazide.

Intracellular targeting of ascomycetous catalase-peroxidases (KatG1s)

Bifunctional catalase-peroxidases (KatGs) are heme oxidoreductases widely spread among bacteria, archaea and among lower eukaryotes. In fungi, two KatG groups with different localization have evolved, intracellular (KatG1) and extracellular (KatG2) proteins. Here, the cloning, expression analysis and subcellular localization of two novel katG1 genes from the soil fungi Chaetomium globosum and Chaetomium cochliodes are reported. Whereas, the metalloenzyme from Ch. globosum is expressed constitutively, Ch. cochliodes KatG1 reveals a slight increase in expression after induction of oxidative stress by cadmium ions and hydrogen peroxide. The intronless open reading frames of both Sordariomycetes katG1 genes as well as of almost all fungal katG1s possess two peroxisomal targeting signals (PTS1 and PTS2). Peroxisomal localization of intracellular eukaryotic catalase-peroxidases was verified by organelle separation and immunofluorescence microscopy. Co-localization with the peroxisomal enzyme 3-ketoacyl-CoA-thiolase was demonstrated for KatGs from Magnaporthe grisea, Chaetomium globosum and Chaetomium cochliodes. The physiological role of fungal catalase-peroxidases is discussed.Electronic supplementary materialThe online version of this article (doi:10.1007/s00203-013-0887-5) contains supplementary material, which is available to authorized users.

Features of a unique intronless cluster of class I small heat shock protein genes in tandem with box C/D snoRNA genes on chromosome 6 in tomato (Solanum lycopersicum)

Physical clustering of genes has been shown in plants; however, little is known about gene clusters that have different functions, particularly those expressed in the tomato fruit. A class I 17.6 small heat shock protein (Sl17.6 shsp) gene was cloned and used as a probe to screen a tomato (Solanum lycopersicum) genomic library. An 8.3-kb genomic fragment was isolated and its DNA sequence determined. Analysis of the genomic fragment identified intronless open reading frames of three class I shsp genes (Sl17.6, Sl20.0, and Sl20.1), the Sl17.6 gene flanked by Sl20.1 and Sl20.0, with complete 5' and 3' UTRs. Upstream of the Sl20.0 shsp, and within the shsp gene cluster, resides a box C/D snoRNA cluster made of SlsnoR12.1 and SlU24a. Characteristic C and D, and C' and D', boxes are conserved in SlsnoR12.1 and SlU24a while the upstream flanking region of SlsnoR12.1 carries TATA box 1, homol-E and homol-D box-like cis sequences, TM6 promoter, and an uncharacterized tomato EST. Molecular phylogenetic analysis revealed that this particular arrangement of shsps is conserved in tomato genome but is distinct from other species. The intronless genomic sequence is decorated with cis elements previously shown to be responsive to cues from plant hormones, dehydration, cold, heat, and MYC/MYB and WRKY71 transcription factors. Chromosomal mapping localized the tomato genomic sequence on the short arm of chromosome 6 in the introgression line (IL) 6-3. Quantitative polymerase chain reaction analysis of gene cluster members revealed differential expression during ripening of tomato fruit, and relatively different abundances in other plant parts.

The reductase domain in a Type I fatty acid synthase from the apicomplexan Cryptosporidium parvum: Restricted substrate preference towards very long chain fatty acyl thioesters

BackgroundThe apicomplexan Cryptosporidium parvum genome possesses a 25-kb intronless open reading frame (ORF) that predicts a multifunctional Type I fatty acid synthase (CpFAS1) with at least 21 enzymatic domains. Although the architecture of CpFAS1 resembles those of bacterial polyketide synthases (PKSs), this megasynthase is predicted to function as a fatty acyl elongase as our earlier studies have indicated that the N-terminal loading unit (acyl-[ACP] ligase) prefers using intermediate to long chain fatty acids as substrates, and each of the three internal elongation modules contains a complete set of enzymes to produce a saturated fatty acyl chain. Although the activities of almost all domains were confirmed using recombinant proteins, that of the C-terminal reductase domain (CpFAS1-R) was yet undetermined. In fact, there were no published studies to report the kinetic features of any reductase domains in bacterial PKSs using purified recombinant or native proteins.ResultsIn the present study, the identity of CpFAS1-R as a reductase is confirmed by in silico analysis on sequence similarity and characteristic motifs. Phylogenetic analysis based on the R-domains supports a previous notion on the bacterial origin of apicomplexan Type I FAS/PKS genes. We also developed a novel assay using fatty acyl-CoAs as substrates, and determined that CpFAS1-R could only utilize very long chain fatty acyl-CoAs as substrates (i.e., with activity on C26 > C24 > C22 > C20, but no activity on C18 and C16). It was capable of using both NADPH and NADH as electron donors, but prefers NADPH to NADH. The activity of CpFAS1-R displayed allosteric kinetics towards C26 hexacosanoyl CoA as a substrate (h = 2.0; Vmax = 32.8 nmol min-1 mg-1 protein; and K50 = 0.91 mM).ConclusionsWe have confirmed the activity of CpFAS1-R by directly assaying its substrate preference and kinetic parameters, which is for the first time for a Type I FAS, PKS or non-ribosomal peptide synthase (NRPS) reductase domain. The restricted substrate preference towards very long chain fatty acyl thioesters may be an important feature for this megasynthase to avoid the release of product(s) with undesired lengths.

Cloning and molecular characterization of the gene encoding the Aureobasidin A biosynthesis complex in Aureobasidium pullulans BP-1938

The gene ( aba1) encoding the NRPS complex responsible for the synthesis of the cyclic peptide antibiotic Aureobasidin A (AbA) in Aureobasidium pullulans BP-1938, was cloned using a combination of PCR and library screening approaches. The aba1 gene was found to consist of a single, intronless open reading frame (ORF) of 34,980 bp, encoding an 11,659 amino acid protein with a calculated molecular mass of 1,286,254 Da. Putative promoter and translation start elements were identified upstream from the putative ATG in the aba1 gene, and a consensus poly(A) addition signal (AATAAA) was identified 191 bp downstream of the translation termination codon (TGA). As predicted by the structure AbA, the aba1 gene encodes an enzyme composed of nine biosynthetic modules, eight of which contain adenylation domains with recognizable amino acid specificity-conferring code elements, and four of which contain embedded methylation domains. The biosynthetic module located at position one in the aba1 gene lacks recognizable specificity-conferring code elements, consistent with it being responsible for incorporation of the 2-hydroxy-3-methylpentanoic acid residue at that position in AbA. An unusual feature of the aba1 gene sequence is a very high degree of shared identity among eight of the biosynthetic modules, at both the nucleotide and amino acid level. The majority of the modules share better than 70% nucleotide identity with another module in the complex, and modules with the same amino acid adenylation specificity share up to 95% identity. Insertion of a hygromycin B phosphotransferase ( HPT) gene cassette in place of the module 4 sequence in aba1 resulted in a cessation of AbA production, thus validating that the isolated gene encodes the AbA biosynthesis complex.

Characterization of a ribonuclease gene and encoded protein from the reptile, Iguana iguana

In this work we identify an intronless open reading frame encoding an RNase A ribonuclease from genomic DNA from the Iguana iguana IgH2 cell line. The iguana RNase is expressed primarily in pancreas, and represents the majority of the specific enzymatic activity in this tissue. The encoded sequence shares many features with its better-known mammalian counterparts including the crucial His 12, Lys 40 and His 114 catalytic residues and efficient hydrolytic activity against yeast tRNA substrate ( k cat/ K m = 6 × 10 4 M −1 s −1), albeit at a reduced pH optimum (pH 6.0). Although the catalytic activity of the iguana RNase is not diminished by human placental RI, iguana RNase is not bactericidal nor is it cytotoxic even at micromolar concentrations. Phylogenetic analysis indicates moderate (46%) amino acid sequence similarity to a pancreatic RNase isolated from Chelydra serpentina (snapping turtle) although no specific relationship could be determined between these RNases and the pancreatic ribonucleases characterized among mammalian species. Further analysis of ribonucleases from non-mammalian vertebrate species is needed in order to define relationships and lineages within the larger RNase A gene superfamily.

Arabidopsis emb175 and other ppr knockout mutants reveal essential roles for pentatricopeptide repeat (PPR) proteins in plant embryogenesis

Pentatricopeptide repeat proteins (PPRPs) constitute one of the largest superfamilies in plants, with more than 440 identified in the Arabidopsis thaliana (L.) Heynh genome. While some PPRPs are known to take part in organelle gene expression, little is known about the broader biological contexts of PPRP gene function. Here, using developmental- and reverse-genetic approaches, we demonstrate that a number of PPRPs are essential early in plant development. We have characterized the Arabidopsis embryo-defective175 mutant and identified the EMB175 gene. Emb175 consistently displays aberrant cell organization and undergoes morphological arrest before the globular-heart transition. The emb175 mutation disrupts an intronless open reading frame encoding a predicted chloroplast-localized PPR protein- the first to be rigorously associated with an early embryo-lethal phenotype. To determine if other PPRP genes act in embryogenesis, we searched Arabidopsis insertion mutant collections for pprp knockout alleles, and identified 29 mutants representing 11 loci potentially associated with embryo-defective phenotypes. We assessed gene structures, T-DNA insertion position, and allelism for these loci and were able to firmly establish essential functions for six PPRP genes in addition to EMB175. Interestingly, Nomarski DIC microscopy revealed diverse embryonic defects in these lines, ranging from early lethality to dramatic late-stage morphological defects such as enlarged shoot apices and stunted cotyledons. Together, emb175 and these pprp knockout mutants establish essential roles for PPRPs in embryogenesis, thus broadening the known organismal context for PPRP gene function. The diversity of emb-pprp knockout phenotypes indicates that mutation of different PPRPs can, directly or indirectly, have distinct impacts on embryo morphogenesis.

Identification and characterization of the α- l-arabinofuranosidase B of Fusarium oxysporum f. sp. dianthi

The gene encoding α- l-Arabinofuranosidase B ( abfB) from the phytopathogenic fungus Fusarium oxysporum f. sp. dianthi ( Fod) was identified, cloned, sequenced and heterologously expressed. AbfB consists in an intronless open reading frame of 1500-bp coding for a protein of 499 aminoacid residues. The partially purified fusion protein has an apparent molecular mass of approximately 58 kDa and exhibits α- l-arabinofuranosidase activity. The specific activity of the recombinant enzyme was 1.07 units mg −1 protein. Optimal activity is attained at pH 4.0 and 50 °C. Interestingly, the abfB gene is actively transcribed in carnation plants infected with Fod. Its upregulation during the infection process suggests a possible role of this gene as virulence factor in the phytopathogenicity of this fungus.

Cryptosporidiumparvum: the first protist known to encode a putative polyketide synthase

We are reporting a putative multifunctional Type I polyketide synthase (PKS) gene from the apicomplexan Cryptosporidium parvum ( CpPKS1). The 40 kb intronless open reading frame (ORF) predicts a single polypeptide of 13,414 amino acids with a molecular mass of 1516.5 kDa. Sequence analysis identified at least 29 enzymatic domains within this protein. These domains are organized into an N-terminal loading unit, seven polyketide chain elongation modules, and a carboxy terminator unit. The loading domain consists of an acyl-CoA ligase (AL) and an acyl carrier protein (ACP). All seven elongation modules contain between two and five of the six domains required for the elongation of two-carbon (C2) acyl units, i.e. ketoacyl synthase, acyl transferase, dehydrase, enoyl reductase, ketoreductase and/or ACP. The carboxy terminator is homologous to various reductases, suggesting that the final elongated product is not hydrolytically released by thioesterases as observed in most Type I PKS and all fatty acid synthetase (FAS) systems, but by a reducing reaction, which has been demonstrated in some non-ribosomal peptide synthase systems. The protein sequence and domain organization of CpPKS1 protein resembles a previously reported C. parvum fatty acid synthase (CpFAS1), which is encoded by a 25 kb ORF. Maximum likelihood phylogenetic analysis of acyl transferases within PKS/FAS from C. parvum and other organisms clearly differentiates acetate-extending clades from those incorporating propionate. All acyl transferase domains from CpPKS1, and a previously reported CpFAS1, clustered within the acetate-extending group, suggesting the likelihood that only non-methylated C2 units are incorporated by C. parvum polyketide and fatty acid synthases. The expression of CpPKS1 was confirmed by reverse transcription-polymerase chain reaction and immunofluorescence microscopy. Many polyketides are medically significant antibiotics, anticancer agents, toxins, or signaling molecules. Therefore, it is interesting to speculate what role CpPKS1 might play in this apicomplexan and the disease caused by this opportunistic infection of AIDS patients.

A Non-Golgi α1,2-Fucosyltransferase That Modifies Skp1 in the Cytoplasm of Dictyostelium

Skp1 is a subunit of the SCF-E3 ubiquitin ligase that targets cell cycle and other regulatory factors for degradation. In Dictyostelium, Skp1 is modified by a pentasaccharide containing the type 1 blood group H trisaccharide at its core. To address how the third sugar, fucose alpha1,2-linked to galactose, is attached, a proteomics strategy was applied to determine the primary structure of FT85, previously shown to copurify with the GDP-Fuc:Skp1 alpha 1,2-fucosyltransferase. Tryptic-generated peptides of FT85 were sequenced de novo using Q-TOF tandem mass spectrometry. Degenerate primers were used to amplify FT85 genomic DNA, which was further extended by a novel linker polymerase chain reaction method to yield an intronless open reading frame of 768 amino acids. Disruption of the FT85 gene by homologous recombination resulted in viable cells, which had altered light scattering properties as revealed by flow cytometry. FT85 was necessary and sufficient for Skp1 fucosylation, based on biochemical analysis of FT85 mutant cells and Escherichia coli that express FT85 recombinantly. FT85 lacks sequence motifs that characterize all other known alpha 1,2-fucosyltransferases and lacks the signal-anchor sequence that targets them to the secretory pathway. The C-terminal region of FT85 harbors motifs found in inverting Family 2 glycosyltransferase domains, and its expression in FT85 mutant cells restores fucosyltransferase activity toward a simple disaccharide substrate. Whereas most prokaryote and eukaryote Family 2 glycosyltransferases are membrane-bound and oriented toward the cytoplasm where they glycosylate lipid-linked or polysaccharide precursors prior to membrane translocation, the soluble, eukaryotic Skp1-fucosyltransferase modifies a protein that resides in the cytoplasm and nucleus.

Sulfation of Endothelial Mucin by Corneal Keratan N-Acetylglucosamine 6-O-Sulfotransferase (GST-4β)

Intestinal N-acetylglucosamine 6-O-sulfotransferase (I-GlcNAc6ST, GST-4α) and corneal N-acetylglucosamine 6-O-sulfotransferases (C-GlcNAc6ST, GST-4β) are two highly homologous GlcNAc 6-O-sulfotransferase isozymes encoded by two intronless open reading frames that reside ∼50 kb apart on human chromosome 16q23.1. I-GlcNAc6ST has been shown to catalyze 6-O-sulfation of the endothelial mucin GlyCAM-1. C-GlcNAc6ST catalyzes 6-O-sulfation of GlcNAc in keratan sulfate and null-mutations in its encoding gene cause human macular corneal dystrophy. We show here that C-GlcNAc6ST efficiently catalyzes sulfation of GlyCAM-1 when coexpressed with the latter in COS-7 cells. We have further compared expression in human of both enzymes by Northern analysis with isozyme-specific probes. While I-GlcNAc6T is expressed mostly in intestinal tissue, larger C-GlcNAc6ST transcripts are found predominantly in the brain.

Chromosomal localization and genomic organization for the galactose/ N-acetylgalactosamine/N-acetylglucosamine 6-O-sulfotransferase gene family.

The galactose/N-acetylgalactosamine/N-acetylglucosamine 6-O-sulfotransferases (GSTs) are a family of Golgi-resident enzymes that transfer sulfate from 3'phosphoadenosine 5'phospho-sulfate to the 6-hydroxyl group of galactose, N-acetylgalactosamine, or N-acetylglucosamine in nascent glycoproteins. These sulfation modifications are functionally important in settings as diverse as cartilage structure and lymphocyte homing. To date six members of this gene family have been described in human and in mouse. We have determined the chromosomal localization of these genes as well as their genomic organization. While the broadly expressed enzymes implicated in proteoglycan biosynthesis are located on different chromosomes, the highly tissue specific enzymes GST-3 and 4 are encoded by genes located both in band q23.1--23.2 on chromosome 16. In the mouse, both genes reside in the syntenic region 8E1 on chromosome 8. This cross-species conserved clustering is suggestive of related functional roles for these genes. The human GST4 locus actually contains two highly similar open reading frames (ORF) that are 50 kb apart and encode two highly similar enzyme isoforms termed GST-4 alpha and GST-4 beta. All genes except GST0 (chondroitin 6-O-sulfotransferase) contain intron-less ORFs. With one exception these are fused directly to sequences encoding the 3' untranslated regions (UTR) of the respective mature mRNAs. The 5' UTRs of these mRNAs are usually encoded by a number of short exons 5' of the respective ORF. 5'UTRs of the same enzyme expressed in different cell types are sometimes derived from different exons located upstream of the ORF. The genomic organization of the GSTs resembles that of certain glycosyltransferase gene families.

In vitro and in silico analysis of two genes (A2-1 and G1-1) differentially regulated during dormancy and sprouting in potato tubers

Two cDNAs, corresponding to genes differentially regulated during dormancy and sprouting in potato tubers, cultivar Desiree, were isolated: i) G1-1 corresponded to a gene that was turned off during dormancy and turned on during early phases of sprouting; ii) A2-1 corresponded to a gene activated during dormancy and strongly repressed during the transition from dormancy to sprouting. When induced, both genes were expressed at low level. Full-length cDNAs and genomic clones were isolated and characterized. G1-1 was a short gene, 452 bp long, containing an intronless open reading frame, coding for a putative protein of 64 aminoacids. Sequence analysis showed that G1-1 was homologous to an expressed sequence tag (EST) ofArabidopsis thaliana. A2-1 full-length cDNA was 1577 bp long and contained an open reading frame coding for a putative protein of 383 aminoacids, which contained a Walker box binding domain, common to a multifunctional family of intracellular ATPases.

Genomic Organization of the Leukotriene B4 Receptor Locus of Human Chromosome 14

The genomic region containing the genes encoding the first leukotriene B4 receptor, BLTR, as well as the recently cloned second leukotriene B4-activated receptor, BLTR2, was mapped by (a) sequence analysis of a human bacterial artificial chromosome (BAC) library containing a 15-kb segment corresponding to chromosome 14q11.2-12 where the BLTR/BLTR2 genes were previously shown to be located, together with (b) sequence analysis of 83 expressed sequence tags (ESTs) from this region. The BLTR gene includes four different 5′ untranslated regions (UTRs) and a mutual acceptor site for the exon containing the intronless open reading frame. The BLTR2 gene is intronless and overlapped by a 5′ UTR splice version of BLTR and, on the reverse strand, of the apoptosis-related CIDE-B gene. This indicates a complex posttranscriptional gene regulation. Further adding to the complexity of the region is evidence of a fourth putative and novel gene, most homologous to the rat adenylyl cyclase IV gene.

Human and Mouse XAP-5 and XAP-5-like (X5L) Genes: Identification of an Ancient Functional Retroposon Differentially Expressed in Testis

Although most retroposons that arose by reverse transcription of cellular mRNAs and by reintegration into the genome are nonfunctional, several examples exist in which the retroposon acquired a novel function and became fixed in the genome as a functional gene. We identified another such case: the ubiquitously expressed X-linked XAP-5 gene with unknown function gave rise to its retroposed counterpart, XAP-5-like (X5L), which has an intronless open reading frame and is autosomal in human. Phylogenetic analysis of the human and mouse XAP-5 and X5L genes shows that the retroposition most likely took place before the radiation of eutherian mammals. The XAP-5 and X5L genes are expressed in a wide range of tissues but are differentially expressed in testis. The ancient origin and broad expression of the X5L retroposon indicate that the XAP-5 and X5L genes may have assumed different functions in somatic cells. In addition to this, because of its autosomal location and its high level and particular pattern of expression in spermatogenic cells, the X5L expression in testis may compensate for the X-linked XAP-5 gene, which may be silenced during spermatogenesis.

Molecular Characterization of the First Heat Shock Protein 70 from a Reef Coral

The branching coral Stylophora pistillata, one of the most abundant hermatypic corals along the coasts of the Red Sea, has been used for many years as a model species for coral biological studies. Here we characterize the first coral heat shock protein 70 gene (SP-HSP70), cloned from S. pistillata, to be used as a tool for studying coral stress response. The cloning was carried out by a combination of PCR methods using heterologous, degenerate HSP70-based primers, followed by plaque-lift screening of a genomic library. The sequenced clone (5212 bp), contains a complete 1953 bp, intronless open reading frame, and 5′ and 3′ flanking regions of 1,935 and 1,324 bp, respectively. TATA, CAAT, and ATF boxes as well as 11 putative heat shock elements were identified in the SP-HSP70 5′ flanking region. A polyadenylation site was identified in the 3′ flanking region. SP-HSP70 protein sequence resembles the cytosolic/nuclear HSP70 cluster. RT-PCR studies confirmed SP-HSP70 mRNA expression in corals grown within their normal physiological conditions. Furthermore, SP-HSP70 has been shown to belong to the coral genome and not to its symbiotic algae one, as revealed by SP-HSP70 PCR amplification, using purified algal and coral DNA templates.

Molecular cloning and characterization of the rat P2Y4 receptor.

Degenerate PCR was used to amplify DNAs encoding members of the P2Y receptor family from rat brain RNA. A full-length sequence obtained for one novel clone (R5) contained an intronless open reading frame that encoded a polypeptide of 361 amino acids, sharing 84% sequence identity with the human P2Y4 receptor. When R5 was stably expressed in Jurkat cells, calcium fluxes resulting from stimulation of the receptor showed that UDP, ADP, 2-methylthio-ATP, and diadenosine tetraphosphate were inactive, whereas UTP and ATP were both full agonists with similar potency. At the human receptor, ATP has significantly lower potency than UTP. The R5 transcript was not detected in brain by northern hybridization. Therefore, its tissue distribution was assessed by PCR, and the mRNA was found to be widely distributed at a low abundance, being present in brain, spinal cord, and a variety of peripheral organs. Localization of the receptor transcript in adult rat brain sections by in situ hybridization indicated that it is expressed at highest levels in the pineal gland and ventricular system. It is presumed that R5 is a species orthologue of the human P2Y4 receptor but with this significant difference in agonist pharmacology.

Molecular cloning and characterization of rat P2Y4 nucleotide receptor.

An intronless open reading frame encoding a protein (361aa in length) was isolated from a rat genomic library probed with a DNA fragment from rat heart. This protein showed 83% sequence identity with the human P2Y4 (hP2Y4) receptor and represents a homologue of the human pyrimidinoceptor. However, the rP2Y4 receptor is not selective for uridine nucleotides and, instead, shows an agonist potency order of ITP = ATP = ADP(pure) = UTP = ATPgammaS = 2-MeSATP = Ap4A > UDP(pure). ADP, ATPgammaS, 2-MeSATP and UDP are partial agonists. Thus, in terms of agonist profile, rP2Y4 is more like the P2U receptor subtype. The rP2Y4 receptor was reversibly antagonized by Reactive blue 2 but not by suramin which, otherwise, inhibits the hP2Y2 receptor (a known P2U receptor). Thus, rP2Y4 and the P2Y2 subtype appear to be structurally distinct forms of the P2U receptor (where ATP and UTP are equi-active) but can be distinguished as suramin-insensitive and suramin-sensitive P2U receptors, respectively.