Chromosome distribution of intracisternal A-particle sequences in the Syrian hamster and mouse

Metaphase chromosomes of Syrian hamster and BALB/c mice were hybridized in situ with radiolabeled probes derived from cloned intracisternal A-particle (IAP) genes of the corresponding species. The DNAs of these species are known to contain about 900 and 1,000 copies, respectively, of the retrovirus-like IAP sequence elements per haploid genome. Multiple IAP sequences were found on all chromosomes of both hamster and mouse. In the hamster, more than half of the IAP sequences were located in regions of non-centromeric constitutive heterochromatin, at an average concentration per unit chromosome length 5 times greater than in the euchromatic regions. The other dispersed sequences showed marked local variations in concentration along the chromosome lengths; both discrete foci and large grain clusters were observed as well as regions apparently lacking IAP sequences. Within the resolution of the techniques, IAP sequences appeared to be more evenly distributed over the mouse chromosomes; however, some prominent variations in concentration were seen. The number of potentially active IAP genes in the Syrian hamster, and by extension in the mouse, may be restricted by the preferential location of IAP sequences in genetically inert regions of the genome.     

5' LTR complete nucleotide sequence of Chinese hamster intracisternal A-particle.

Retrovirus like sequences homologous to mouse IAP are present in Chinese hamster genome (Lueders K.K. and Kuff, E.L., 1981, 1983, Servenay et al., 1990). Murine IAP long terminal repeats (LTRs) can function as effective promoters in different cell types (Horowitz M. et al., 1984, Howe, C.C. et al., 1986). Thus CHO IAP sequences could act as retrotransposons in the cellular genome, and in this way affect the expression of other genes at the target sites. We had sequenced previously a Chinese hamster IAP genomic region corresponding mainly to the gag gene and including 57 nucleotides of U5 5' LTR (Servenay et al., 1988). In this paper, we present the 5' LTR complete nucleotide sequence of the Chinese hamster IAP element and its comparison with those of mouse and Syrian hamster.     

Characterization of amplified intracisternal A-particle elements encoding integrase.

Type IIB intracisternal A-particle (IAP) elements have undergone marked amplification and transposition in the genomic DNA of some mouse myelomas. We have made a cDNA library from one such myeloma, MOPC 315, to determine whether some property of the elements themselves has a role in this process. Sequencing of several type IIB cDNAs and one genomic type IIB IAP element has shown that they are nearly identical (greater than 99%) and contain 2 open reading frames (ORFs). ORF2 is capable of encoding the IAP integrase, an enzyme which catalyzes integration of proviral DNA into the genome. An antiserum to a synthetic peptide based on the IAP integrase gene sequence reacted with ORF2 product expressed in bacteria as a fusion protein, and detected a 47 kDa protein, predicted from the size of ORF2, in myeloma cell fractions by Western blotting.     

Mapping of mouse intracisternal A-particle proviral markers in an interspecific backcross

We present a linkage map of intracisternal A-particle (IAP) proviral loci. The IAP family consists of 2000 endogenous proviral elements that are widely dispersed in the mouse genome. The map was constructed by using an interspecific backcross and markers defined by oligonucleotide probes specific for subclasses of expressed IAP elements. In genomic DNA from C57BL/6J mouse, these probes each detected from 12 to 44 HindIII restriction fragments that represent junctions between proviral and 5-flanking DNA. The fragments have characteristic strain distribution patterns (SDPs) that are particularly polymorphic in the DNAs of C57BL/6J and Mus spretus mice used for the backcross. IAP loci were placed on the map by comparison of their distribution patterns with those of known genetic markers in the backcross. The map includes 51 IAP loci that have not been previously mapped and 23 IAP proviruses that had been previously mapped in recombinant inbred (RI) strains. Comparable map positions were obtained with the IAP markers in the interspecific backcross and the RI strains. The mapped IAP loci were widely dispersed on the X Chromosome (Chr) and all of the autosomes except Chrs 9 and 19, providing useful genetic markers for linkage studies.     

Nucleotide sequence analysis of cellular flanking regions of intracisternal A-particle gene 81

The cellular nucleotide sequences flanking the mouse intracisternal A-particle gene 81 were determined. The results indicated that they were made of many small oligonucleotide repeats both direct and indirect in orientation. These two different kinds of repeating sequences were often found to be overlap. The overall base composition of this region is relatively A + T rich. The most important feature of the sequences determined was that it consists of several repeated dinucleotide tracts containing a (CA)16 repeating cluster in the 5' end flanking region of one strand and another repeating dinucleotide cluster, (GT)16, in the 3' end flanking region of the same strand of this gene. In addition, the existence of two clusters of 9 continuous 5-bp repeat units, GCTTT, was found in the 3' end flanking region. The possible roles of such repeating sequence were discussed.     

Structural analysis of type II variants within the mouse intracisternal A-particle sequence family.

Intracisternal A-particle (IAP) elements are present in multiple copies in the mouse and other rodent genomes. The bulk of this sequence family in Mus musculus consists of 7 Kb long elements, but the majority of IAP sequences involved in known transpositions have been deleted forms. The present study describes a subset of deleted IAP sequences (type II IAP) characterized by insertion of a particular short sequence element (AIIins). AIIins are interspersed and the majority occur as part of the type II IAP elements in the mouse genome. AIIins sequences are absent or in low copy number outside Mus musculus. We have isolated clones containing AIIins from a mouse genomic DNA library and have sequenced three isolates of AIIins and their surrounding IAP sequences to define the detailed structure of type II elements. AIIins are 272, 268 and 264 bp long and 90% homologous in sequence. They are bracketed by 9 bp duplications, suggesting they may be inserted elements. A 75 bp region containing a core enhancer sequence is repeated at the 5' end in type II IAP elements. Insertion into the IAP genome, with potential to encode an integrase function, may have played a role in the amplification of AIIins.     

In vitro methylation inhibits the promotor activity of a cloned intracisternal A-particle LTR.

We studied the relation between LTR methylation and expression of the family of endogenous retrovirus-like elements related to mouse intracisternal A-particles (IAP). Comparative HpaII/MspI and HhaI restriction analysis of genomic DNA's showed that in cells and tissues with a low level of IAP gene expression, HpaII and HhaI sites within the 5' LTR were heavily methylated, while in cells abundantly expressing IAP's 20 to 30% of the 5' LTRs were demethylated at these sites. The effects of methylation on the promoter activity of a cloned IAP 5' LTR was studied directly, using the plasmid pMIA5' L-cat in which this LTR was linked to the chloramphenicol acetyl transferase (CAT) gene. In vitro methylation of three HhaI sites located between -137 and -205 bp from the RNA start site of this LTR completely inactivated the promoter activity of pMIA5' L-cat transfected into COS7 cells. Methylation of a HpaII site located 94 bp downstream from the RNA start site reduced the promoter activity by 75%. The results show that methylation at sites both upstream and downstream from the RNA start site profoundly effects the promoter activity of this LTR and suggest that methylation within the 5' LTR can serve to regulate IAP gene expression in vivo.     

Synthesis and turnover of intracisternal A-particle structural protein in cultured neuroblastoma cells.

Synthesis and turnover of the main structural protein (P73) of intracisternal A-particles were studied in mouse neuroblastoma cells in tissue culture. Triton X-100:EDTA-insoluble pellets containing 95% of the A-particle antigen in the cells were prepared and analyzed by electrophoresis in Na dodecyl-SO4-minus polyacrylamide gels. A 73,000 molecular weight component was prominent in pellets from three lines of neuroblastoma which contain numerous A-particles and this component was identified as the A-particle structural protein P73. It was absent in pellets prepared from cells which do not contain A-particles. Incorporation of labeled amino acids into P73 represented approximately 1.2% of total cell incorporation and this proportion did not change when the cell growth changed from log phase to stationary phase. Label appeared P73 within 2 min after radioactive amino acids were added to the medium. Pulse-chase and inhibitor studies confirmed antigenic measurements in demonstrating that the pool of P73 not assembled into A-particles was small. Turnover studies showed that P73 gained and lost label more rapidly than the average cell protein. In one cell line which was thoroughly characterized, approximately 60% of the main A-particle protein was estimated to turn over in a 24-hour period. Although the cells released approximately 10% of the proteins synthesized into the culture fluid, A-particle protein did not appear to be released. Analysis of culture fluid failed to reveal A-particles, soluble A-particle proteins, or A-particle antigen. It appears, therefore, that the particles are relatively rapidly synthesized and degraded, and that turnover occurs entirely intracellularly.     

Differing populations of intracisternal A-particle genes in myeloma tumors and mouse subspecies.

Intracisternal A-particle genes form a family of endogenous retrovirus-like genetic elements that are transcribed in mouse plasmacytomas (myeloma tumors). Two types of A-particle genes that can be differentiated by a sequence of 0.5 kilobase found in one type but not the other have been identified. Quantitative Southern blot analysis was used to measure the populations of different A-particle genes in DNAs from BALB/c mice, the Japanese subspecies Mus musculus subsp. molossinus, and myeloma tumors. The majority of the genes (715 copies per haploid genome or 76%) were found to be nearly identical except for small changes in conserved restriction enzyme sites. The second type of A-particle gene was much less abundant with 90 copies representing approximately 10%. The A-particle RNA in MOPC104E and MOPC315 was found to be colinear with a small portion of this latter type, comprising only 2% of the endogenous intracisternal A-particle sequences. Myeloma tumor DNA was found to have a two- to fourfold increase in the number of these genes, suggesting that the intracellular viruses have been activated to produce a double-stranded complementary DNA which subsequently integrated into the tumor genome. Analysis of M. musculus subsp. molossinus DNA revealed similar but shifted populations of A-particle genes, when compared with BALB/c DNA, except for the absence of a prominent EcoRI-HindIII band at 3.9 kilobases. This latter band, representing approximately 15% of the A-particle genes in BALB/c DNA, was shown to be a deletion variant of the most abundant gene family.     

Molecular cloning and long terminal repeat sequences of intracisternal A-particle genes in Mus caroli

We isolated DNA clones of intracisternal A-particle (IAP) genes from the genome of an Asian wild mouse, Mus caroli. A typical M. caroli IAP gene was 6.5 kilobase pairs in length and had long terminal repeat (LTR) sequences at both ends. The size of the LTR was 345 base pairs in clone L20, and two LTRs at both ends of this clone were linked to directly repeating cellular sequences of 6 base pairs. Each LTR possessed most of the structural features commonly associated with the retrovirus LTR. The restriction map of the M. caroli IAP gene resembled that of Mus musculus, although the M. caroli IAP gene was 0.4 kilobase pairs shorter than the M. musculus IAP gene in two regions. Sequence homology between the M. caroli and M. musculus IAP LTRs was calculated as about 80%, whereas the LTR sequence of the Syrian hamster IAP gene was about 60% homologous to the M. caroli LTR. The reiteration frequency of the M. caroli IAP genes was estimated as 200 to 400 copies per haploid genome, which is at least 10 times the reported value. These results suggest that the IAP genes observed in the genus Mus are present in multiple copies with structures closely resembling the integrated retrovirus gene.     

Nucleotide sequence of the Syrian hamster intracisternal A-particle gene: close evolutionary relationship of type A particle gene to types B and D oncovirus genes.

We determined the complete nucleotide sequence of the intracisternal A-particle gene, IAP-H18, cloned from the normal Syrian hamster liver DNA. IAP-H18 was 7,951 base pairs in length with two identical long terminal repeats of 376 base pairs at both ends. On the coding strand, imperfect open reading frames corresponding to gag and pol of the retrovirus genome were observed, whereas many stop codons were present in the region corresponding to env. The putative H18 gag gene (809 amino acids) had a sequence homologous to the N-terminal half of the mouse mammary tumor virus gag gene and locally to the Rous sarcoma virus gag gene. The putative H18 pol gene (900 residues) was homologous to the Rous sarcoma virus pol gene almost throughout the entire region. Two conserved regions among the retrovirus pol genes have been reported. One presumably corresponds to the DNA polymerase and the RNase H domain, and the other corresponds to the DNA endonuclease domain of the multifunctional protein pol. By the comparison of the deduced amino acid sequences of the putative endonuclease domain of six representative oncovirus genomes, a phylogenetic tree of the oncovirus genomes was constructed, and the intracisternal A-particle (type A) genome was found to be more closely related to the mouse mammary tumor virus (type B) and squirrel monkey retrovirus (type D) genomes.