Development of avian sarcoma and leukosis virus-based vector-packaging cell lines.

We have constructed an avian leukosis virus derivative with a 5' deletion extending from within the tRNA primer binding site to a SacI site in the leader region. Our aim was to remove cis-acting replicative and/or encapsidation sequences and to use this derivative, RAV-1 psi-, to develop vector-packaging cell lines. We show that RAV-1 psi- can be stably expressed in the quail cell line QT6 and chicken embryo fibroblasts and that it is completely replication deficient in both cell types. Moreover, we have demonstrated that QT6-derived lines expressing RAV-1 psi- can efficiently package four structurally different replication-defective v-src expression vectors into infectious virus, with very low or undetectable helper virus release. These RAV-1 psi--expressing cell lines comprise the first prototype avian sarcoma and leukosis virus-based vector-packaging system. The construction of our vectors has also shown us that a sequence present within gag, thought to facilitate virus packaging, is not necessary for efficient vector expression and high virus production. We show that quantitation and characterization of replication-defective viruses can be achieved with a sensitive immunocytochemical procedure, presenting an alternative to internal selectable vector markers.     

Inhibitory activity of the equine infectious anemia virus major 5' splice site in the absence of Rev.

The major 5' splice site of equine infectious anemia virus (EIAV) conforms to the consensus 5' splice site in eight consecutive positions and is located immediately upstream of the gag AUG. Our results show that the presence of this 5' splice site on the EIAV gag mRNA decreases Gag production 30- to 60-fold. This is caused by inefficient nuclear mRNA export and inefficient mRNA utilization. Inhibition could be overcome by providing human immunodeficiency virus type 1 Rev/Rev-responsive element, human T-cell leukemia virus type 1 Rex/Rex-responsive element, or simian retrovirus type 1 constitutive transport element. In addition, inhibition could be abolished by introducing single point mutations in the 5' splice site or by moving the 5' splice site away from its natural position immediately upstream of the gag AUG. This demonstrates that both maintenance of a perfect consensus 5' splice site and its proper location on the mRNA are important for inhibitory activity of the EIAV major 5' splice site.     

Sequence of the Long Terminal Repeat and Adjacent Segments of the Endogenous Avian Virus Rous-Associated Virus 0

Rous-associated virus 0 (RAV-0), an endogenous chicken virus, does not cause disease when inoculated into susceptible domestic chickens. An infectious unintegrated circular RAV-0 DNA was molecularly cloned, and the sequence of the long terminal repeat (LTR) and adjacent segments was determined. The sequence of the LTR was found to be very similar to that of replication-defective endogenous virus EV-1. Like the EV-1 LTR, the RAV-0 LTR is smaller (278 base pairs instead of 330) than the LTRs of the oncogenic members of the avian sarcoma virus-avian leukosis virus group. There is, however, significant homology. The most striking differences are in the U(3) region of the LTR, and in this region there are a series of small segments present in the oncogenic viruses which are absent in RAV-0. These differences in the U(3) region of the LTR could account for the differences in the oncogenic potential of RAV-0 and the avian leukosis viruses. I also compared the regions adjacent to the RAV-0 LTR with the available avian sarcoma virus sequences. A segment of approximately 200 bases to the right of the LTR (toward gag) is almost identical in RAV-0 and the Prague C strain of Rous sarcoma virus. The segment of RAV-0 which lies between the end of the env gene and U(3) is approximately 190 bases in length. Essentially this entire segment is present between env and src in the Schmidt-Ruppin A strain of Rous sarcoma virus. Most of this segment is also present between env and src in Prague C; however, in Prague C there is an apparent deletion of 40 bases in the region adjacent to env. In Schmidt-Ruppin A, but not in Prague C, about half of this segment is also present between src and the LTR. This arrangement has implications for the mechanism by which src was acquired. The region which encoded the gp37 portion of env appears to be very similar in RAV-0 and the Rous sarcoma viruses. However, differences at the very end of env imply that the carboxy termini of RAV-0, Schmidt-Ruppin A, and Prague C gp37s are significantly different. The implications of these observations are considered.     

Generation of a recombinant Moloney murine leukemia virus carrying the v-src gene of avian sarcoma virus: transformation in vitro and pathogenesis in vivo.

A Moloney murine leukemia virus (M-MuLV) recombinant carrying the v-src gene of avian sarcoma virus was generated by the introduction of a cloned portion of v-src from Schmidt-Ruppin A avian sarcoma virus into a molecular clone of M-MuLV provirus at the recombinant DNA level. The v-src sequences (lacking a portion of the 5' end of v-src) were inserted into the p30 region of the M-MulV gag gene so that M-MuLV gag and v-src were in the same reading frame. Transfection of this chimeric clone, pMLV(src), into NIH 3T3 cells which were constitutively producing M-MuLV gag and pol protein resulted in the formation of foci of transformed cells. Infectious and transforming virus could be recovered from the transformed cells. This virus was designated M-MuLV(src). M-MuLV(src)-transformed cells contained two novel proteins of 78 and 90 kilodaltons. The 78-kilodalton protein, p78gag-src, contained both gag and src determinants, exhibited kinase activity in an immune kinase assay, and is probably a fusion of Pr65gag and src. The 90-kilodalton protein, which is of the appropriate size to be the gPr80gag fused to src, contained gag determinants as well as a V8 protease cleavage fragment typical of the carboxy terminus of avian sarcoma virus pp60src. However, it could not be immunoprecipitated with an anti-v-src serum. M-MuLV(src)-transformed cells showed elevated levels of intracellular phosphotyrosine in proteins, although the elevation was intermediate compared with cells transformed with wild-type v-src. M-MuLV and amphotropic murine leukemia virus pseudotypes of M-MuLV(src) were inoculated into newborn NIH Swiss mice. Inoculated mice developed solid tumors at the site of inoculation after 3 to 6 weeks, with most animals dying by 14 weeks. Histopathological analysis indicated that the solid tumors were mesenchymally derived fibrosarcomas that were both invasive and metastatic.     

全基因组SHIV-KB9克隆的构建及其在人、猴外周血单核细胞中的复制

将分别携带SHIV-KB9 (SIV/HIV-1 KB9) 基因组的3′端和5′端的两个半长克隆,体外连接成SHIV-KB9全基因组克隆.含有全长基因的质粒培养时易发生同源重组和缺失,采用JM109作为宿主菌以及30℃、低转速的培养条件,可保持质粒的稳定性.通过PCR , RT-PCR 和猴免疫缺陷病毒(SIV) gag p27 核心抗原滴度检测表明感染性克隆SHIV-KB9可有效在人、恒河猴及食蟹猴的外周血单核细胞中复制.     

Molecular and biological properties of c-mil transducing retroviruses generated during passage of Rous-associated virus type 1 in chicken neuroretina cells.

IC1, IC2, and IC3 are novel c-mil transducing retroviruses generated during serial passaging of Rous-associated virus type 1 (RAV-1) in chicken embryo neuroretina cells. They were isolated by their ability to induce proliferation of these nondividing cells. IC2 and IC3 were generated during early passages of RAV-1 in neuroretina cells, whereas IC1 was isolated after six consecutive passages of virus supernatants. We sequenced the transduced genes and the mil-RAV-1 junctions of the three viruses. The 5' RAV-1-mil junction of IC2 and IC3 was formed by a splicing process between the RAV-1 leader sequence and exon 8 of the c-mil gene. The 5' end of IC1 resulted from homologous recombination between gag and mil sequences. Reconstitution experiments showed that serial passaging of IC2 in neuroretina cells also led to the formation of a gag-mil-containing retrovirus. Therefore, constitution of a U5-leader-delta c-mil-delta RAV-1-U3 virus represents early steps in c-mil transduction by RAV-1. This virus further recombined with RAV-1 to generate a gag-mil-containing virus. The three IC viruses transduced the serine/threonine kinase domain of the cellular gene. Hence, amino-terminal truncation is sufficient to activate the mitogenic property of c-mil. Comparison of the transforming properties of IC2 and IC1 showed that the transduced mil gene, expressed as a unique protein independent of gag sequences, was weakly transforming in avian cells. Acquisition of gag sequences by IC1 not only increased the rate of virus replication but also enhanced the transforming capacity of the virus.     

Transforming viruses spontaneously arise from nontransforming reticuloendotheliosis virus strain T-derived viruses as a result of increased accumulation of spliced viral RNA.

The highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (Rev-T) contains a substitution of the oncogene v-rel for much of env and a deletion of gag and pol relative to the helper virus Rev-A. Replacement of gag and pol sequences in Rev-T suppresses transformation by reducing the accumulation of spliced viral mRNA and v-rel protein in infected cells (C. K. Miller and H. M. Temin, J. Virol 58:75-80, 1986). After infection of spleen cells with viruses containing gag and pol sequences, revertant viruses that are strongly transforming were found. Approximately three-fourths of the revertant viruses appeared structurally the same as the parental virus, and approximately one-fourth of the revertant viruses had large deletions (similar in size and location to the deletion in Rev-T). Two revertant viruses that appeared structurally the same as the parental virus were molecularly cloned. The regions sufficient to change the parental virus to a strongly transforming virus were determined by construction of recombinant viruses. In one revertant virus, the region sufficient for transformation contained a 327-base-pair insertion 5' of the 3' splice site used by Rev-T. In the other revertant virus, the region sufficient for transformation contained a 1-base-pair transition and a deletion of one copy of a 9-base-pair direct repeat, both 3' of the 3' splice site used by Rev-T. These differences resulted in the accumulation of increased levels of subgenomic v-rel mRNA and protein, ultimately leading to transformation.     

Mutations at alternative 5' splice sites of M1 mRNA negatively affect influenza A virus viability and growth rate

Different amino acid sequences of influenza virus proteins contribute to different viral phenotypes. However, the diversity of the sequences and its impact on noncoding regions or splice sites have not been intensively studied. This study focuses on the sequences at alternative 5' splice sites on M1 mRNA. Six different mutations at the splice sites were introduced, and viral growth characteristics for those mutants generated by reverse genetics with 12 plasmids were examined, for which G12C (the G-to-C mutation at the first nucleotide of the intron for the mRNA3 5' splice site), C51G (at the 3' end of the exon of the M2 mRNA 5' splice site), and G146C (for the first nucleotide of the intron for mRNA4) are lethal mutations. On the other hand, mutants with the mutation G11C (at the 3' end of exon of the mRNA3 5' splice site), G52C (for the first nucleotide of the intron for M2 mRNA), or G145A (at the 3' end of the exon of mRNA4) were rescued, although they had significantly attenuated growth rates. Notably, these mutations did not change any amino acids in M1 or M2 proteins. The levels of precursor (M1 mRNA) and spliced products (M2 mRNA, mRNA3, and mRNA4) from the recombinant mutant virus-infected cells were further analyzed. The production levels of mRNA3 in cells infected with G11C, G52C, and G145A mutant viruses were reduced in comparison with that in wild-type recombinant virus-infected ones. More M2 mRNA was produced in G11C mutant virus-infected cells than in wild-type-virus-infected cells, and there was little M2 mRNA and none at all in G145A and G52C mutant virus-infected ones, respectively. Results obtained here suggest that introducing these mutations into the alternative 5' splice sites disturbed M1 mRNA splicing, which may attenuate viral growth rates.