Showing papers on "Intron published in 1994"

Organization of the human serotonin transporter gene.

Abstract: The gene encoding the human serotonin transporter (5-HTT) has been isolated and characterized. The human 5-HTT gene is composed of 14 exons spanning approximately 31 kb. The sequence of all exons including adjacent intronic sequences and a tandem repeat DNA polymorphism (VNTR) has been determined and deposited in the EMBL/GenBank data base with the accession numbers X76753 to X76762. The characterization of 5-HTT gene will aid to advance molecular pharmacologic studies of 5-HT uptake regulation and facilitate investigations of its role in psychiatric disorders.

Structure of the human cyclo-oxygenase-2 gene

Abstract: Cyclo-oxygenase (Cox), a rate-limiting enzyme in the synthesis of prostanoids, is encoded by two genes, Cox-1 and Cox-2, which are differentially expressed and regulated. Human Cox-1 and -2 polypeptides share 61% primary sequence identity. While the expression of Cox-1 is maximal in quiescent cells. Cox-2 expression is induced by growth factors and cytokines. We have screened a human genomic library with a probe from the 5'-untranslated region (UTR) of the human Cox-2 (hCox-2) cDNA and isolated two overlapping genomic clones. We have determined the DNA sequence of 0.8 kb upstream of the transcription start site, 6 kb of protein coding region, which includes 10 exons and 9 introns, as well as 2.5 kb of the 3'-UTR. The structures of the hCox-1 and hCox-2 and the murine TIS10 (Cox-2) genes are highly conserved, with a few exceptions. The 3'-UTRs of the Cox-1 and -2 genes are distinct; for example, the largest exon in the Cox-2 gene encodes the entire 3'-UTR, containing 22 copies of the 'AUUUA' RNA instability element. Sequence analysis of the 5'-flanking region has shown several potential transcription regulatory sequences, including a TATA box, a C/EBP motif, two AP-2 sites, three SP1 sites, two NF-kappa B sites, a CRE motif and an Ets-1 site. These efforts serve as a basis for future studies on transcriptional and post-transcriptional mechanisms of Cox-2 gene regulation.

A tRNA-like structure is present in 10Sa RNA, a small stable RNA from Escherichia coli

Abstract: We have determined that 10Sa RNA (one of the small stable RNAs found in Escherichia coli) has an interesting structural feature: the 5' end and the 3' end of 10Sa RNA can be arranged in a structure that is equivalent to a half-molecule (acceptor stem and TFC stem-loop) of alanine tRNA of E. coli. Primer-extension analysis of 10Sa RNA extracted from a bacterial mutant with temperature-sensitive RNase P function revealed that the precursor to 10Sa RNA (pre-10Sa RNA) is folded into a pre-tRNA-like structure in vivo such that it can be cleaved by RNase P to generate the 5' end of the mature 10Sa RNA. The purified 10Sa RNA can be charged with alanine in vitro. Disruption of the gene encoding 10Sa RNA (ssrA) caused a reduction in the rate of cell growth, which was especially apparent at 45 degrees C, and a reduction in motility on semisolid agar. These phenotypic characteristics of the deletion strain (delta ssrA) allowed us to investigate the effects of some mutations in 10Sa RNA in vivo, although the exact function of 10Sa RNA still remains unclear. When the G.U pair (G3.U357) in 10Sa RNA, which may be equivalent to the determinant G.U pair of alanine tRNA, was changed to a G.A or G.C pair, the ability to complement the phenotypic mutations of the delta ssrA strain was lost. Furthermore, this inability to complement the mutant phenotypes that was caused by the substitution of the determinant bases by a G.A pair could be overcome by the introduction of a gene encoding alanyl-tRNA synthetase (alaS) on a multicopy plasmid. The evidence suggests that the proposed structural features of 10Sa RNA are indeed manifested in vivo.

Characterization of the human gene (PTGS2) encoding prostaglandin‐endoperoxide synthase 2

Abstract: The human gene (PTGS2) encoding an inducible isozyme of prostaglandin-endoperoxide synthase (prostaglandin-endoperoxide synthase 2) that is distinct from the well-characterized and constitutive isozyme (prostaglandin-endoperoxide synthase 1), was isolated using a polymerase-chain reaction-generated cDNA fragment probe for human prostaglandin-endoperoxide synthase 2. Nucleotide sequence analysis of the entire human prostaglandin-endoperoxide-synthase-2 gene demonstrated that it is more than 8.3 kb in size and consists of ten exons; this gene is very similar to the murine and chicken prostaglandin-endoperoxide-synthase-2 genes. The structures of exons in the human prostaglandin-endoperoxide-synthase-2 gene were also similar to those of the human prostaglandin-endoperoxide-synthase-1 gene (PTGS1). However, the sizes of introns in the human prostaglandin-endoperoxide-synthase-2 gene were generally smaller than those of the human prostaglandin-endoperoxide-synthase-1 gene. Primer-extension analysis indicated that the transcriptional-start site is 134 bases upstream of the translational-initiation site. The sequence of the 1.69-kb region of nucleotides preceding the transcriptional-start site and the first 0.8-kb intron contained a canonical TATA box and various transcriptional-regulatory elements (CArG box, NF-IL6, PEA-1, myb, GATA-1, xenobiotic-response element, cAMP-response element, NF-kappa B, PEA-3, Sp-1 and 12-O-tetradecanoyl-phorbol-13-acetate-response element). The nucleotide sequence of the 5'-flanking region (275 bp) of the human prostaglandin-endoperoxide-synthase-2 gene showed 63% similarity to the sequence of murine prostaglandin-endoperoxide-synthase-2/TIS10 gene, but essentially no homology to the chicken prostaglandin-endoperoxide-synthase-2 gene, and human and murine prostaglandin-endoperoxide-synthase-1 genes. A fluorescence in situ hybridization study showed that the human genes coding for prostaglandin-endoperoxide synthase 1 (PTGS1) and prostaglandin-endoperoxidase synthase 2 (PTGS2) were mapped to distinct chromosomes 9q32-q33.3 and 1q25.2-q25.3, respectively, indicating that these genes are not genetically linked.

A soluble form of the HLA-G antigen is encoded by a messenger ribonucleic acid containing intron 4.

Abstract: The HLA-G primary transcript is alternatively spliced to yield mRNAs encoding three alternative membrane bound proteins. In addition to these forms, a soluble HLA-G protein has been described which is not encoded directly by any of the three alternative mRNAs. To explain the process which might lead to the expression of a soluble HLA-G Ag, we investigated the potential roles proteolytic processing and additional alternative splicing of HLA-G RNA might play. By generating transfected cells with HLA-G cDNA expression driven by a retroviral promoter, it was possible to rule out proteolytic processing of the membrane-bound HLA-G as a mechanism of generating soluble HLA-G, resulting in our focus on alternative splicing as an explanation. Analysis of PCR-amplified cDNA revealed a relatively abundant transcript present in all samples examined which consisted of the full length HLA-G mRNA sequence interrupted by intron 4 sequence. The open reading frame in this mRNA continues into intron 4 terminating 21 amino acids after the alpha 3 domain, thus excluding the transmembrane encoding region and yielding a protein with a highly charged carboxyl terminus. Transfection of the intron 4 containing cDNA, inserted into a retroviral expression vector, into LCL .221 followed by comparison of the class I protein to native soluble G by two dimensional isoelectric focusing/SDS-PAGE analysis, demonstrated this message encoded the soluble HLA-G protein. In addition, a similar intron containing message derived from the HLA-G2 mRNA was found, suggesting the existence of a soluble form of this alternative HLA-G protein. These findings are discussed in relation to other soluble class I molecules and with regard to potential functions of the soluble HLA-G Ag.

Characterization of the Wilson disease gene encoding a P-type copper transporting ATPase: genomic organization, alternative splicing, and structure/function predictions

Abstract: Wilson disease is an autosomal recessive disorder of copper transport. Disease symptoms develop from the toxic build-up of copper primarily in the liver, and subsequently in the brain, kidney, cornea and other tissues. A candidate gene for WD (ATP7B) has recently been identified based upon apparent disease-specific mutations and a striking amino acid homology to the gene (ATP7A) responsible for another human copper transport disorder, X-linked Menkes disease (MNK). The cloning of WD and MNK genes provides the first opportunity to study copper homeostasis in humans. A preliminary analysis of the WD gene is presented which includes: isolation and characterization of the 5'-end of the gene; construction of a genomic restriction map; identification of all 21 exon/intron boundaries; characterization of extensive alternative splicing in brain; prediction of structure/function features of the WD and MNK proteins which are unique to the subset of heavy metal-transporting P-type ATPases; and comparative analysis of the six metal-binding domains. The analysis indicates that WD and MNK proteins belong to a subset of transporting ATPases with several unique features presumably reflecting their specific regulation and function. It appears that the mechanism of alternative splicing serves to regulate the amount of functional WD protein produced in brain, kidney, placenta, and possibly in liver.

Regulation of mdm2 expression by p53: alternative promoters produce transcripts with nonidentical translation potential.

Abstract: The mdm2 proto-oncogene product binds to the p53 tumor suppressor protein and inhibits its ability to trans-activate target genes. One such target gene is mdm2 itself, which is therefore considered a component of a p53 negative feedback loop. Two tandem p53-binding motifs residing within the first intron of the murine mdm2 gene confer upon it p53-mediated activation. We now report that in murine cells p53 activates an internal mdm2 promoter (P2) located near the 3' end of intron 1, resulting in mRNA whose transcription starts within exon 2. P2 is activated by p53 within artificial constructs, as well as within the context of the chromosomal mdm2 gene. Activation follows either the introduction of overexpressed wild-type p53 into cells or the induction of endogenous wild-type p53 by ionizing radiation. The upstream, constitutive (P1) mdm2 promoter is only mildly affected by p53, if at all. The p53-derived mdm2 transcripts lack exon 1 and a few nucleotides from exon 2. As the first in-frame AUG of mdm2 is located within exon 3, the two types of mdm2 transcripts should possess similar coding potentials. Nevertheless, in vitro conditions, where each of these transcripts yields a distinct translation profile, reflect the differential usage of translation initiation codons. Initiation of translation at internal AUG codons, which occurs also in vivo, gives rise to MDM2 polypeptides incapable of binding to p53. In vitro translation profiles of the various mdm2 transcripts could be manipulated by changing the amounts of input RNA. Thus, p53 can modulate both the amount and the nature of MDM2 polypeptides through activation of the internal P2 promoter.

Herpes simplex virus inhibits host cell splicing, and regulatory protein ICP27 is required for this effect.

Abstract: While the majority of metazoan genes and those of the DNA viruses which infect them contain introns which require RNA splicing, herpes simplex virus type 1 (HSV-1) encodes relatively few spliced products. We previously showed that the HSV-1 immediate-early protein ICP27 decreased the levels of spliced target mRNAs in transfections and spliced cellular mRNAs during infection, suggesting that ICP27 may function in impairing host cell splicing. Here, we show that during infections with the wild type, but not in infections with an ICP27 viral mutant termed 27-LacZ, precursor RNA accumulated for a virus transcript which contained introns. Pre-mRNA accumulation in the nucleus was greater than that in the cytoplasm, indicating that splicing rather than transport was affected. Furthermore, splicing of a beta-globin pre-mRNA substrate was inhibited in nuclear extracts from wild-type-infected cells but not in extracts from cells infected with 27-LacZ. The inhibitory activity in extracts from wild-type-infected cells was able to reduce the splicing efficiency of competent extracts in biochemical complementation assays. ICP27 appeared to be responsible for this decrease, because the splicing activity of an extract from cells infected with an ICP27 ts mutant was significantly reduced after incubation of the extract at the permissive temperature to allow renaturation of the conformationally defective ICP27 protein. These results strongly suggest that HSV-1 infection inhibits host cell splicing through the action of ICP27.

Recombinant binding proteins and peptides

Abstract: DNA constructs comprise a first exon sequence of nucleotides encoding a first peptide or polypeptide, a second exon sequence of nucleotides encoding a second peptide or polypeptide and a third sequence of nucleotides between the first and second sequences encoding a heterologous intron, for example that of Tetrahymena thermophila nuclear pre-rRNA, between RNA splice sites and a site-specific recombination sequence, such as loxP, within the intron, the exons together encoding a product peptide or polypeptide. Such constructs are of use in methods of production of peptides or polypeptides, transcription leading to splicing out of the intron enabling translation of a single chain product peptide or polypeptide. Isolated nucleic acid constructs consisting essentially of a sequence of nucleotides encoding a self-splicing intron with a site-specific recombination sequence within the intron, for use in creation of constructs for expression of peptides or polypeptides, are also provided.

Ribozyme-mediated repair of defective mRNA by targeted trans -splicing

Abstract: Ribozymes can be targeted to cleave specific RNAs, which has led to much interest in their potential as gene inhibitors. Such trans-cleaving ribozymes join a growing list of agents that stop the flow of genetic information. Here we describe a different application of ribozymes for which they may be uniquely suited. By targeted trans-splicing, a ribozyme can replace a defective portion of RNA with a functional sequence. The self-splicing intron from Tetrahymena thermophila was previously shown to mediate trans-splicing of oligonucleotides in vitro. As a model system for messenger RNA repair, this group I intron was re-engineered to regenerate the proper coding capacity of short, truncated lacZ transcripts. Trans-splicing was efficient in vitro and proceeded in Escherichia coli to generate translatable lacZ messages. Targeted trans-splicing represents a general means of altering the sequence of specified transcripts and may provide a new approach to the treatment of many genetic diseases.

Interactions of a small RNA with antibiotic and RNA ligands of the 30S subunit

Abstract: IT is now generally accepted that 16S and 23S ribosomal RNA play important roles in the decoding and peptidyl transferase activities of ribosomes1,2. Despite their complex structures and numerous associated proteins it is possible that small domains of these rRNAs can fold and function autonomously, particularly those that appear devoid of protein interactions3. One candidate for such a domain is the decoding region, located near the 3′ end of 16S rRNA (Fig. la, b). Consistent with this hypothesis, aminoglycoside antibiotics that interact with the decoding region in 30S subunits interact with other RNAs in the absence of proteins4–7. In addition, certain activities of self-splicing introns, at least superficially, resemble translational decoding8,9. We report here that an oligo-ribonucleotide analogue of the decoding region interacts with both antibiotic and RNA ligands of the 30S subunit in a manner that correlates with normal subunit function. The activities of the decoding region analogue suggest that the intimidating structural complexity of the ribosome can be, to some degree, circumvented.

Translation of 15-lipoxygenase mRNA is inhibited by a protein that binds to a repeated sequence in the 3' untranslated region.

Abstract: During red blood cell differentiation, the mRNA encoding rabbit erythroid 15-lipoxygenase (LOX) is synthesized in the early stages of erythropoiesis, but is only activated for translation in peripheral reticulocytes. Erythroid LOX, which like other lipoxygenases catalyses the degradation of lipids, is unique in its ability to attack intact phospholipids and is the main factor responsible for the degradation of mitochondria during reticulocyte maturation. Strikingly, rabbit erythroid LOX mRNA has 10 tandem repeats of a slightly varied, pyrimidine-rich 19 nt motif in its 3'-untranslated region (3'-UTR). In this study we demonstrate, using gel retardation and UV-crosslinking assays, that this 3'-UTR segment specifically binds a 48 kDa reticulocyte protein. Furthermore, the interaction between the 3'-UTR LOX repeat motif and the 48 kDa protein, purified to homogeneity by specific RNA chromatography, is shown to be necessary and sufficient for specific translational repression of LOX as well as reporter mRNAs in vitro. To our knowledge this is the first case in which translation, presumably at the initiation step, is regulated by a defined protein-RNA interaction in the 3'-UTR.

Human natural resistance-associated macrophage protein: cDNA cloning, chromosomal mapping, genomic organization, and tissue-specific expression.

Abstract: Natural resistance to infection with unrelated intracellular parasites such as Mycobacteria, Salmonella, and Leishmania is controlled in the mouse by a single gene on chromosome 1, designated Bcg, Ity, or Lsh. A candidate gene for Bcg, designated natural resistance-associated macrophage protein (Nramp), has been isolated and shown to encode a novel macrophage-specific membrane protein, which is altered in susceptible animals. We have cloned and characterized cDNA clones corresponding to the human NRAMP gene. Nucleotide and predicted amino acid sequence analyses indicate that the human NRAMP polypeptide encodes a 550-amino acid residue membrane protein with 10-12 putative transmembrane domains, two N-linked glycosylation sites, and an evolutionary conserved consensus transport motif. Identification of genomic clones corresponding to human NRAMP indicates that the gene maps to chromosome 2q35 within a group of syntenic loci conserved with proximal mouse 1. The gene is composed of at least 15 exons, with several exons encoding discrete predicted structural domains of the protein. These studies have also identified an alternatively spliced exon encoded by an Alu element present within intron 4. Although this novel exon was found expressed in vivo, it would introduce a termination codon in the downstream exon V, resulting in a severely truncated protein. Northern blot analyses indicate that NRAMP mRNA expression is tightly controlled in a tissue-specific fashion, with the highest sites of expression being peripheral blood leukocytes, lungs, and spleen. Additional RNA expression studies in cultured cells identified the macrophage as a site of expression of human NRAMP and indicated that increased expression was correlated with an advanced state of differentiation of this lineage.

Polypurine sequences within a downstream exon function as a splicing enhancer.

Abstract: We have previously shown that a purine-rich sequence located within exon M2 of the mouse immunoglobulin mu gene functions as a splicing enhancer, as judged by its ability to stimulate splicing of a distant upstream intron. This sequence element has been designated ERS (exon recognition sequence). In this study, we investigated the stimulatory effects of various ERS-like sequences, using the in vitro splicing system with HeLa cell nuclear extracts. Here, we show that purine-rich sequences of several natural exons that have previously been shown to be required for splicing function as a splicing enhancer like the ERS of the immunoglobulin mu gene. Moreover, even synthetic polypurine sequences had stimulatory effects on the upstream splicing. Evaluation of the data obtained from the analyses of both natural and synthetic purine-rich sequences shows that (i) alternating purine sequences can stimulate splicing, while poly(A) or poly(G) sequences cannot, and (ii) the presence of U residues within the polypurine sequence greatly reduces the level of stimulation. Competition experiments strongly suggest that the stimulatory effects of various purine-rich sequences are mediated by the same trans-acting factor(s). We conclude from these results that the purine-rich sequences that we examined in this study also represent examples of ERS. Thus, ERS is considered a general splicing element that is present in various exons and plays an important role in splice site selection.

Evidence that HIV-1 Rev directly promotes the nuclear export of unspliced RNA

Abstract: The Rev trans-activator of human immunodeficiency virus type 1 (HIV-1) is a protein that regulates the simultaneous appearance in the cytoplasm of both spliced and unspliced forms of viral mRNAs from the same viral transcripts by way of recognition of a target sequence termed the Rev-responsive element (RRE). Whether Rev acts directly on RNA export or by inhibition of splicing, or both, is still a matter of debate. We have addressed this issue in Xenopus laevis oocytes by microinjecting RNA molecules containing RRE along with purified recombinant Rev protein into the oocyte nuclei. Adenovirus pre-mRNA containing an RRE in the intron was spliced equally well in the absence and presence of Rev protein. Only in the presence of Rev was non-spliced pre-mRNA exported from the nucleus; more surprisingly, the excised intron lariat (containing RRE) was also exported. Furthermore, an RRE-containing mRNA molecule that lacked intron sequences was also efficiently exported from the nucleus in a Rev-dependent manner. Therefore our results demonstrate that Rev can act directly at the level of nuclear export, independent of any inhibitory effect that it may exert on the splicing of pre-mRNA. Finally, our finding that the Rev mutant M10, shown previously to be inactive in human lymphoid cells, was also unable to export RRE-containing RNA molecules from oocyte nuclei suggests that one or more cellular factors, evolutionarily conserved between humans and Xenopus, interact with Rev in both cell systems to promote nuclear RNA export.

Dopamine D4 receptor repeat: analysis of different native and mutant forms of the human and rat genes.

Abstract: Recent molecular characterization of the human D4 gene has revealed the existence of various polymorphic forms of this receptor. These variations are found in the putative third cytoplasmic loop region and encode a variable number of repeats of 16 amino acids in length. In the present study we have compared the pharmacological binding profiles of seven different polymorphic variants of the human D4 receptor, the rat D4 receptor, and two different human D4 receptor mutants that were deleted in the repeat sequence. For this purpose we cloned the rat D4 receptor gene and compared its gene structure and its pharmacological binding profile with those of the D4.4 and D4.7 genes. The rat and human D4 genes display a high degree of sequence similarity, especially in the coding regions. An Alu repeat sequence was identified in the first intron of the human D4 gene but is not present in the rat D4 gene. Furthermore, using the polymerase chain reaction we cloned 3-, 5-, 6-, and 9-fold repeat sequences. These cloned repeat sequences were used for the reconstruction of full length cDNAs encoding D4.3, D4.5, D4.6, and D4.9, respectively. These novel forms of the human D4 receptor, as well as the previously cloned D4.2, D4.4, and D4.7 forms, were transiently expressed in COS-7 cells. All of the different forms of the human and rat D4 receptors and repeat deletion mutants displayed similar binding profiles for all ligands tested, although small differences were observed. The affinity for dopamine could be decreased by guanosine-5'-(beta, gamma-imido)triphosphate with the different forms of the D4 receptor, including the two receptor mutants that were deleted in the repeat sequence. These data suggest that the polymorphic repeat sequence has little influence on D4 binding profiles and might not be essential for G protein interaction.

Physical isolation of nascent RNA chains transcribed by RNA polymerase II: evidence for cotranscriptional splicing.

Abstract: In order to examine whether splicing can occur cotranscriptionally in mammalian nuclei, we mapped exon-intron boundaries on nascent RNA chains transcribed by RNA polymerase II. A procedure that allows fractionation of nuclei into a chromatin pellet containing DNA, histones, and ternary transcription complexes and a supernatant containing the bulk of the nonhistone proteins and RNAs that are released from their DNA templates was developed. The transcripts of the genes encoding DBP, a transcriptional activator protein, and HMG coenzyme A reductase recovered from the chromatin pellet and the supernatant were analyzed by S1 nuclease mapping. The large majority of the RNA molecules from the pellet appeared to be nascent transcripts, since, in contrast to the transcripts present in the supernatant, they were not cleaved at the polyadenylation site but rather contained heterogeneous 3' termini encompassing this site. Splicing intermediates could be detected among nascent and released transcripts, suggesting that splicing occurs both cotranscriptionally and posttranscriptionally. Our results also indicate that polyadenylation is not required for the splicing of the last DBP intron. In addition to allowing detailed structural analysis of nascent RNA chains, the physical isolation of nascent transcripts also yields reliable measurements of relative transcription rates.

cloning and chromosomal localization of the human thrombopoietin gene

Abstract: The complete gene for human thrombopoietin ('I'PO) has been cloned by screening a human genomic library using human TPO cDNA as a probe. This gene is 6.2 kb in length and contains six exons and five introns. It is shown that the human genome contains a single copy of the human TPO gene according to Southern blotting analysis. The transcription initiation site was determined by Sl nuclease mapping. The human TPO gene expressed TFQ activity when transfected into COS-1 cells. The human TPO gene has been mapped to chromosome 3q27 by in situ hybridization using a biotin-labeled probe.