Isolation and analysis of a rat genomic clone containing a long terminal repeat with high similarity to the oncomodulin mRNA leader sequence

The structure of a novel long terminal repeat (LTR) from an intracisternal A particle (IAP) DNA element in the rat (Sprague-Dawley) genome was determined. This LTR has a total length of 313 base pairs (bp). Several structural features typical for retroviral LTR promoters were identified, including a "CCAAT" box, a "TATA" box, a polyadenylation signal, and a polyadenylation site. The LTR is flanked by 3-bp inverted repeats, and it consists of the three typical LTR regions, U3, R, and U5. U3 contains 213 bp, R 46 bp, and U5 54 bp, which is within the usual size range of IAP LTRs. A sequence of 60 bp in the U3 region reveals considerable similarity to a murine IAP LTR U3 element, which is known to interact with nuclear proteins. A sequence of 69 bp in the U5 and R regions has 83 and 93% similarities to an endogenous retroviral LTR from Syrian hamster and to the cDNA leader sequence of (Buffalo) rat oncomodulin, respectively. Oncomodulin is an "EF-hand" Ca2+-binding protein and appears in many human and rodent tumors and in cells with tumor-like properties but not in normal tissues. We postulate that in the rat the tumor-specific expression of oncomodulin is controlled by a retroviral LTR promoter.     

Characterization of a Novel Class of Interspersed LTR Elements in Primate Genomes: Structure, Genomic Distribution, and Evolution

Retrovirus-like sequences and their solitary (solo) long terminal repeats (LTRs) are common repetitive elements in eukaryotic genomes. We reported previously that the tandemly arrayed genes encoding U2 snRNA (the RNU2 locus) in humans and apes contain a solo LTR (U2-LTR) which was presumably generated by homologous recombination between the two LTRs of an ancestral provirus that is retained in the orthologous baboon RNU2 locus. We have now sequenced the orthologous U2-LTRs in human, chimpanzee, gorilla, orangutan, and baboon and examined numerous homologs of the U2-LTR that are dispersed throughout the human genome. Although these U2-LTR homologs have been collectively referred to as LTR13 in the literature, they do not display sequence similarity to any known retroviral LTRs; however, the structure of LTR13 closely resembles that of other retroviral LTRs with a putative promoter, polyadenylation signal, and a tandemly repeated 53-bp enhancer-like element. Genomic blotting indicates that LTR13 is primate-specific; based on sequence analysis, we estimate there are about 2,500 LTR13 elements in the human genome. Comparison of the primate U2-LTR sequences suggests that the homologous recombination event that gave rise to the solo U2-LTR occurred soon after insertion of the ancestral provirus into the ancestral U2 tandem array. Phylogenetic analysis of the LTR13 family confirms that it is diverse, but the orthologous U2-LTRs form a coherent group in which chimpanzee is closest to the humans; orangutan is a clear outgroup of human, chimpanzee, and gorilla; and baboon is a distant relative of human, chimpanzee, gorilla, and orangutan. We compare the LTR13 family with other known LTRs and consider whether these LTRs might play a role in concerted evolution of the primate RNU2 locus. Received: 29 September 1997 / Accepted: 16 January 1998     

Avian retroviral long terminal repeats bind CCAAT/enhancer-binding protein.

DNA-protein interactions involving enhancer and promoter sequences within the U3 regions of several avian retroviral long terminal repeats (LTRs) were studied by DNase I footprinting. The rat CCAAT/enhancer-binding protein, C/EBP, bound to all four viral LTRs examined. The Rous sarcoma virus binding site corresponded closely to the 5' limit of the LTR enhancer; nucleotides -225 to -188 were protected as a pair of adjacent binding domains. The Fujinami sarcoma virus LTR bound C/EBP at a single site at nucleotides -213 to -195. C/EBP also bound to the promoter region of the enhancerless Rous-associated virus-0 LTR at nucleotides -77 to -57. The avian myeloblastosis virus LTR bound C/EBP at three sites: nucleotides -262 to -246, -154 to -134, and -55 to -39. We have previously observed binding of C/EBP to an enhancer in the gag gene of avian retroviruses. A heat-treated nuclear extract from chicken liver bound to all of the same retroviral sequences as did C/EBP. Alignment of the avian retroviral binding sequences with the published binding sites for C/EBP in two CCAAT boxes and in the simian virus 40, polyoma, and murine sarcoma virus enhancers suggested TTGNNGCTAATG as a consensus sequence for binding of C/EBP. When two bases of this consensus sequence were altered by site-specific mutagenesis of the Rous sarcoma virus LTR, binding of the heat-stable chicken protein was eliminated.     

ART-CH, a new chicken retroviruslike element.

A 3' region of a previously unknown retroviruslike element named ART-CH (avian retrotransposon from chicken genome) was obtained in the course of polymerase chain reaction-mediated cloning of avian leukosis virus long terminal repeats (LTRs) from DNAs of infected chicken cells. About 50 copies of ART-CH are present in the genome of chickens of different breeds. ART-CH is not found in DNA of quails, ducks, turkeys, or several other birds tested. The ART-CH element is about 3 kb in size, including 388 bp LTRs. The major class of ART-CH-specific RNA, also 3 kb in size, is detected in various organs of chickens. An ART-CH polypurine tract, a tRNA(Trp)-binding site, regions around the TATA box and polyadenylation signal, and the beginning of the putative gag gene strongly resemble the corresponding regions of avian leukosis viruses and EAV, the two described classes of chicken retroviruses. An open reading frame capable of encoding a polypeptide with a putative transmembrane domain is located upstream of the right ART-CH LTR. This sequence, as well as the U3 and U5 regions of the ART-CH LTR, has no obvious similarities with the corresponding parts of other known vertebrate retroviruses and retrotransposons. A short sequence upstream of the right LTR of ART-CH is very similar to sequences which flank the 3' ends of the oncogenes v-src, v-myc, v-fps, and v-crk in four different recombinant avian retroviruses and which are absent from the genomes of other studied avian retroviruses. Thus, ART-CH is a new endogenous chicken provirus that may participate in the formation of recombinant oncogenic retroviruses.     

Circles with two tandem long terminal repeats are specifically cleaved by pol gene-associated endonuclease from avian sarcoma and leukosis viruses: nucleotide sequences required for site-specific cleavage.

The avian retroviral pol gene-encoded DNA endonuclease (pol-endo) has been shown to selectively cleave the viral long terminal repeat sequences (LTRs) in single-stranded DNA substrates in a region known to be joined to host DNA during integration (G. Duyk, J. Leis, M. Longiaru, and A.M. Skalka, Proc. Natl. Acad. Sci. USA 80:6745-6749, 1983). The preferred sites of cleavage were mapped to the unique U5/U3 junctions found only in covalently closed circular DNA molecules containing two tandem LTRs. The cuts occurred three nucleotides 5' to the axis of symmetry of the 12-of-15-base-pair nearly perfect inverted repeat which marks the LTR junction. Experiments with double-stranded supercoiled DNA substrates revealed a similar specificity for nicking. Also, the endonuclease associated with the pol cleavage product, pp32, has the same specificity as the alpha beta form. The limits of sequence required for site-selective cleavage near the U5/U3 junction were established with single-stranded DNA substrates. A domain no larger than 44 base pairs allowed site-selective cleavage in each strand in vitro. Recognition of either strand appeared to be independent of the other, and in each case, the critical sequence was asymmetrically distributed with respect to the U5/U3 junction. The predominant contribution was from the U5 domain; this is consistent with its conservation in the LTR sequences of a number of avian sarcoma and leukosis viruses.     

Nucleotide sequence analysis of avian retroviruses: structural similarities with transposable elements

Integrated retroviral genomes are flanked by direct repeats of sequences derived from the termini of the viral RNA genome. These sequences are designated long terminal repeats (LTRs). We have determined and analyzed the nucleotide sequence of the LTRs from several exogenous and endogenous avian retroviruses. These LTRs possess several structural similarities with eukaryotic and prokaryotic transposable elements: 1) inverted complementary repeats at the termini, 2) deletions of sequences adjacent to the LTR, 3) small duplications of host sequences flanking the integrated provirus, and 4) sequence homologies with transposable and other genetic elements. These observations suggest that LTRs function in the integration and perhaps transposition of retrovirus genomes. Evidence exists for the presence of a strong promoter sequence within the LTR. The retroviral LTR also contains a "Hogness box" up-stream of the capping site and a poly(A) signal. These features suggest an additional role for the LTR in the regulation of gene expression.     

Avian Retrovirus pp32 DNA-Binding Protein I. Recognition of Specific Sequences on Retrovirus DNA Terminal Repeats

The avian retrovirus pp32 protein possesses a DNA-nicking activity which prefers supercoiled DNA as substrate. We have investigated the binding of pp32 to avian retrovirus long terminal repeat (LTR) DNA present in both supercoiled and linear forms. The cloned viral DNA was derived from unintegrated Schmidt-Ruppin A (SRA) DNA. A subclone of the viral DNA in pBR322 (termed pPvuII-DG) contains some src sequences, tandem copies of LTR sequences, and partial gag sequences in the order src-U(3) U(5):U(3) U(5)-gag. Binding of pp32 to supercoiled pPvuII-DG DNA followed by digestion of this complex with a multicut restriction enzyme (28 fragments total) permitted pp32 to preferentially retain on nitrocellulose filters two viral DNA fragments containing only LTR DNA sequences. In addition, pp32 also preferentially retained four plasmid DNA fragments containing either potential promoters or Tn3 "left-end" inverted repeat sequences. Mapping of the pp32 binding sites on viral LTR DNA was accomplished by using the DNase I footprinting technique. The pp32 protein, but not the avian retrovirus alphabeta DNA polymerase, is able to form a unique protein-DNA complex with selected regions of either SRA or Prague A LTR DNAs. Partial DNase I digestion of a 275-base pair SRA DNA fragment complexed with pp32 gives upon electrophoresis in denaturing gels a unique ladder pattern, with regions of diminished DNase I susceptibility from 6 to 10 nucleotides in length, in comparison with control digests in the absence of protein. The binding of pp32 to this fragment also yields enhanced DNase I-susceptible sites that are spaced between the areas protected from DNase I digestion. The protected region of this unique complex was a stretch of 170 +/- 10 nucleotides that encompasses the presumed viral promoter site in U(3), which is adjacent to the src region, extends through U(5), and proceeds past the joint into U(3) for about 34 base pairs. No specific protection or DNase I enhancement by pp32 was observed in experiments with a 435-base pair SRA DNA fragment derived from a part of U(3) and the adjacent src region or a 55-base pair DNA fragment derived from another part of U(3). The DNA sequence of Prague A DNA at the fused LTRs differs from that of SRA DNA. The alteration in the sequence at the juncture of the LTRs prevented pp32 from forming a stable complex in this region of the LTR. Our results are relevant to two aspects of the interaction between pp32 and LTR DNA. First, the pp32 protein in the presence of selected viral DNA restriction fragments possibly forms a higher order oligomer analogous to Escherichia coli DNA gyrase-DNA complexes or eucaryotic nucleosome structures. Second, the specificity of the binding suggests a role for pp32 and the protected DNA sequences in the retrovirus life cycle. The preferred sequences to which pp32 binds include two adjacent 15-base pair inverted terminal repeats at the joint between U(5) and U(3) in SRA DNA. This region is involved in circularization of linear DNA and is perhaps the site that directs integration into cellular DNA.     

Molecular cloning of viral DNA from leukemogenic Gross passage A murine leukemia virus and nucleotide sequence of its long terminal repeat.

The viral DNA genome of the leukemogenic Gross passage A virus was cloned in phage Charon 21A as an infectious molecule. The virus recovered by transfection with this infectious DNA was ecotropic, N-tropic, fibrotropic, and XC+. It was leukemogenic when reinjected into newborn SIM mice, indicating that ecotropic murine leukemia virus (MuLV) from an AKR mouse thymoma can harbor leukemogenic sequences. Its restriction map was similar to that of nonleukemogenic AKR MuLV, its putative parent, but differed at the 3' end and in the long terminal repeat (LTR). The nucleotide sequence of the Gross A virus LTR was identical to the AKR MuLV LTR sequence (Van Beveren et al., J. Virol. 41:542-556, 1982) in U5, R, and part of U3. All differences between both LTRs were found in U3. Only one copy of the U3 tandem direct repeat was conserved in the Gross A virus LTR, and it was rearranged by the insertion of a 36-base-pair sequence and by five point mutations. Only one additional point mutation common to several oncogenic MuLVs was present in U3. These structural changes in the U3 LTR and at the 3' end of the genome may be related to the leukemogenicity of this virus.     

A novel retroviruslike family in mouse DNA.

In the course of structural analysis of VL30 DNA elements, a recombinant retroviruslike element was encountered that contained non-VL30 long terminal repeats (LTRs) flanking internal VL30 sequences. With the aid of this novel LTR sequence probe, we cloned several DNA elements that were apparently members of a new retroviruslike family. A particular DNA element representative of this family (designated GLN) was characterized. It was approximately 8 kilobase pairs long and contained LTRs that are 430 base pairs long. It possessed an unusual primer-binding site sequence that corresponds to tRNAGln and a polypurine tract primer that is adjacent to the 3' LTR. The nucleotide sequences of the LTRs and their adjacent regions (which together housed all cis-acting retroviral functions) were different from those of known retroviruses and retroviruslike families. The comparison of three different GLN LTR sequences revealed a marked heterogeneity of U3 sequences relative to the homogeneity of R and U5 sequences. We estimate that approximately 20 to 50 copies of GLN elements are dispersed in all species of mice. GLN-related LTRs, however, are present in a much higher copy number (1,000 to 1,500 per genome). Nucleotide sequences that are more distantly related to GLN DNA are present in multiple copies in DNAs of other rodents but not in nonrodent genomes.     

不同病变型J亚群禽白血病病毒LTR启动子序列分析及活性比较

从ALV-J中国地方分离株SCAU-HN06株(血管瘤病变型)、NX0101株和JS-nt株(骨髓瘤病变型)病毒的细胞培养物提取前病毒DNA,通过PCR扩增各毒株的LTR并克隆,随后进行测序分析。与国内外ALV-J参考毒株LTR序列比较发现:国内地方分离株与英国ALV-J原型株HPRS-103和美国ALV-J原型株ADOL-7501的LTR核苷酸序列相似性为88.0%~97.2%;LTR中的U5区及R区具有较高的保守性,而U3区内存在较大差异。将不同病变型ALV-J的LTR片段分别插入pCAT-basic载体CAT报告基因5'端。用所得的重组报告基因表达质粒转染DF-1细胞,48h后通过测定转染细胞中的CAT表达量来评价LTR启动子的活性。结果表明,SCAU-HN06株与骨髓瘤病变型ALV-J(JS-nt株,NX0101株)LTR启动子活性差异不显著。