Genomic organization of low copy number sequences that are associated with deca-satellite DNA in the monkey genome.
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A previously described segment of African green monkey DNA (cloned in phage lambda MkA) contains deca-satellite linked to DNA sequences that are estimated to occur once per genome. Sequences homologous to the low copy number sequences in lambda MkA are also associated with species-specific satellite DNAs in the human and mouse genomes. A second clone, lambda Mk8, contains a monkey DNA region that is colinear and homologous to a portion of the low copy number sequences in lambda MkA, but no satellite sequences. The two cloned segments are markedly different starting at a point proximal to the satellite DNA region in lambda MkA. DNA-blotting experiments indicate that lambda Mk8 but not lambda MkA represents the typical genomic organization and that the low copy number segments occur only once per haploid genome. The data suggest that rearrangements such as deletions or inversions occurring in monkey cells account in part for the structure of lambda MkA. Additional rearrangements may have occurred during cloning in E. coli. This unique chromosomal region may be particularly susceptible to recombination. (+info)
Development of adult T-cell leukemia-like disease in African green monkey associated with clonal integration of simian T-cell leukemia virus type I.
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Proviral integration of a simian retrovirus highly homologous to human T-cell leukemia virus type I was examined in cellular DNAs extracted from primary peripheral blood lymphocytes of 31 adult African green monkeys (Cercopithecus aethiops) that were seropositive for simian T-cell leukemia virus type I (STLV-I). Among these monkeys, one case with overt leukemia, showing pleomorphic leukemia cells similar to those in human adult T-cell leukemia (ATL), and five cases in a preleukemic state of ATL-like disease were found. Judging from the integration site of the provirus genome, primary lymphocytes of these leukemic or preleukemic cases contained monoclonally proliferated STLV-I-infected cells, whereas lymphocytes of other seropositive monkeys without hematological abnormalities were polyclonal, and those of seronegative monkeys did not contain the provirus. The restriction patterns with PstI ans SstI of most STLV-I proviruses were identical to those of the previous isolate from this species, but in three monkeys there was a deletion of one PstI site. From the correlation of the development of simian ATL-like disease with the monoclonal integration of the STLV-I provirus genome, it should be indicated that STLV-I has similar leukemogenicity to human T-cell leukemia virus type I, and so STLV-I infection in African green monkeys will be useful as an animal model of human ATL. (+info)
Transcription factor Sp1 recognizes promoter sequences from the monkey genome that are simian virus 40 promoter.
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A 440-base-pair fragment of African green monkey genomic DNA shares homology with the transcriptional regulatory region of simian virus 40 (SV40) and has been reported to direct transcription in vivo. We find that two regions within this fragment bind the promoter-specific cellular transcription factor Sp1 and are protected in DNase protection ("footprinting") experiments. As in SV40, binding occurs in regions containing multiple copies of the sequence GGGCGG. These regions, when fused to the proximal, or "TATA box," element of the herpes simplex virus thymidine kinase promoter, are able to direct Sp1-dependent transcription in vitro. The finding that Sp1 is capable of productive interaction with sequences taken from a cellular promoter supports the idea that Sp1 may play a role in modulating transcription of cellular genes. (+info)
Discrete size classes of monkey extrachromosomal circular DNA containing the L1 family of long interspersed nucleotide sequences are produced by a general non-sequence specific mechanism.
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The L1 family of long interspersed nucleotide sequences (LINES) has recently been identified and characterized in the small polydisperse circular DNA (spc-DNA) populations of monkey (1), human (2) and mouse (3) cells. In monkey spc-DNA, the L1 (also known as Kpn I) family is present in discrete size classes (ranging from 300 to 6000 base pairs (bp)) which appear to be generated by non homologous recombination events within chromosomal elements. In this communication it is shown that different regions of the consensus L1 family are present at different frequencies in monkey spc-DNA (as they are in chromosomal DNA), that all regions of the family are present in extrachromosomal DNA, and that each region appears to be represented in an identical discrete spc-DNA size distribution. This size distribution reflects a non-sequence specific mechanism that generates spc-DNA size classes by chromosomal DNA recombination events that are in some way constrained to occur between sites separated by relatively defined lengths. (+info)
alpha DNA in African green monkey cells is organized into extremely long tandem arrays.
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We have determined the size of arrays formed by tandemly repeated monomers of alpha DNA in African green monkey cells. DNA fragments containing intact alpha DNA arrays were generated by digestion of genomic DNA with restriction endonuclease that do not have sites in the alpha DNA consensus sequence. Their size was determined by Southern analysis and by sedimentation through neutral sucrose gradients followed by probing of each fraction for alpha sequences. The restriction fragments varied in size with the most frequent being 78 kilobase pairs long. We have also shown that they contain very little non-alpha DNA sequences. This suggests a minimum array of 450 tandemly repeated alpha DNA monomers, which is more than an order of magnitude larger than previously supposed. (+info)
Analysis of LINE-1 family sequences on a single monkey chromosome.
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The structure of LINE-1 (L1Ca) family members present on African green monkey chromosome CAE-19 is compared with that of the entire set of L1Ca sequences present in the monkey genome. The analysis involved annealing of cloned subsegments of monkey L1 family members to DNA-blots containing restriction endonuclease digests of either total monkey liver DNA or DNA isolated from a monkey/mouse somatic cell hybrid carrying the single monkey chromosome. In addition, L1Ca segments cloned from hybrid cell DNA were characterized by restriction endonuclease mapping and hybridization. The data indicate that, taken as a whole, the set of L1Ca sequences on CAE-19 tends to differ in characteristic ways from the set present in the total monkey genome. (+info)
Simian immunodeficiency virus from African green monkeys.
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Simian immunodeficiency virus (SIV) was isolated from the total peripheral blood mononuclear cell population and the monocyte-macrophage adherent cell population of three seropositive green monkeys originating from Kenya. SIV from these African green monkeys (SIVagm) was isolated and continuously produced with the MOLT-4 clone 8 (M4C18) cell line but not with a variety of other cells including HUT-78, H9, CEM, MT-4, U937, and uncloned MOLT-4 cells. Once isolated, these SIVagm isolates were found to replicate efficiently in M4C18, SupT1, MT-4, U937, and Jurkat-T cells but much less efficiently if at all in HUT-78, H9, CEM, and MOLT-4 cells. The range of CD4+ cells fully permissive for replication of these SIVagm isolates thus differs markedly from that of previous SIV isolates from macaques (SIVmac). These SIVagm isolates had a morphogenesis and morphology like that of human immunodeficiency virus (HIV) and other SIV isolates. Antigens of SIVagm and SIVmac cross-reacted by comparative enzyme-linked immunosorbent assay only with reduced efficiency, and optimal results were obtained when homologous antibody and antigen were used. Western blotting (immunoblotting) of purified preparations of SIVagm isolate 385 (SIVagm385) revealed major viral proteins of 120, 27, and 16 kilodaltons (kDa). The presumed major core protein of 27 kDa cross-reacted antigenically with the corresponding proteins of SIVmac (28 kDa) and HIV-1 (24 kDa) by Western blotting. Hirt supernatant replicative-intermediate DNA prepared from cells freshly infected with SIVagm hybridized to SIVmac and HIV-2 DNA probes. Detection of cross-hybridizing DNA sequences, however, required very low stringency, and the restriction endonuclease fragmentation patterns of SIVagm were not similar to those of SIVmac and HIV-2. The nucleotide sequence of a portion of the pol gene of SIVagm385 revealed amino acid identities of 65% with SIVmac142, 64% with HIV-2ROD, and 56% with HIV-1BRU; SIVagm385 is thus related to but distinct from previously described primate lentiviruses SIVmac, HIV-1, and HIV-2. Precise information on the genetic makeup of these and other SIV isolates will possibly lead to better understanding of the history and evolution of these viruses and may provide insight into the origin of viruses that cause acquired immunodeficiency syndrome in humans. (+info)
Cross-reactivity to human T-lymphotropic virus type III/lymphadenopathy-associated virus and molecular cloning of simian T-cell lymphotropic virus type III from African green monkeys.
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Simian T-lymphotropic retroviruses with structural, antigenic, and cytopathic features similar to the etiologic agent of human acquired immunodeficiency syndrome, human T-lymphotropic virus type III/lymphadenopathy-associated virus (HTLV-III/LAV), have been isolated from a variety of primate species including African green monkeys (STLV-IIIAGM). This report describes nucleic acid cross-reactivity between STLV-IIIAGM and HTLV-III/LAV, molecular cloning of the STLV-IIIAGM genome, and evaluation of its structure and genetic relationship to other retroviruses. Overlapping clones from a cell line infected with virus from a single animal were found to encompass the entire STLV-IIIAGM genome and exhibit a limited degree of restriction-site variability. Specific hybridizing fragments were detected in DNA from this and other STLV-IIIAGM-infected cell lines. A fraction of viral DNA present in at least two STLV-IIIAGM lines persists as unintegrated viral DNA, a characteristic of infection with cytopathic retroviruses. Strongest cross-reactivity was detected between HTLV-III/LAV pol- and gag- genes and STLV-IIIAGM, whereas no cross-reactivity was detected between STLV-IIIAGM and molecular clones of human T-lymphotropic virus types I and II (HTLV-I and -II), visna virus, bovine leukemia virus, or feline leukemia virus. (+info)