Genesis of Kirsten murine sarcoma virus: sequence analysis reveals recombination points and potential leukaemogenic determinant on parental leukaemia virus genome.

The genome of Kirsten murine sarcoma virus was formed by recombination between Kirsten murine leukaemia virus sequences, and rat sequences derived from a retrovirus-like '30S' (VL30) genetic element encompassing the Kras oncogene. Using cloned DNAs we have determined the nucleotide sequences of the long terminal repeats and adjacent regions, extending across the points of recombination on the sarcoma and leukaemia virus genomes. Our results suggest that discrete regions of homology and other cryptic sequence features, may have constituted recombinational hot-spots involved in the genesis of the Kirsten murine sarcoma virus genome. We have also compared the sequence of the Kirsten murine leukaemia virus p15 env and adjacent long terminal repeat with the corresponding regions of the AKV and Gross A murine leukaemia virus genomes. This comparison has identified a leukaemogenic determinant in the U3 domain of the long terminal repeat, possibly within a enhancer-like sequence element.     

Structure of a Moloney murine leukemia virus-virus-like 30 recombinant: implications for transduction of the c-Ha-ras proto-oncogene.

Tumor progression locus 2 (Tpl-2) encodes a novel serine-threonine protein kinase which is activated by provirus integration in the late stages of oncogenesis in Moloney leukemia virus (MoMuLV) induced rat T-cell lymphomas. In this report, we present evidence that the provirus integrated in the Tpl-2 locus in 1 of 10 T-cell lymphomas harboring a Tpl-2 rearrangement (2779) is a recombinant between MoMuLV and virus-like 30 (VL30) sequences (Mo-VL30). Recombination between MoMuLV and VL30 may contribute to the transduction of ras, as suggested by the finding that VL30 flanks the ras oncogene in all of the ras transducing viruses isolated from rats to date. The Mo-VL30 recombinant described here represents evidence that recombination between MoMuLV and VL30 can be uncoupled from the transduction of ras, and it may precede the transduction. Sequence comparison between clones of Mo-VL30, Harvey sarcoma virus (Ha-MSV), and genomic c-Ha-ras revealed that all three share a 124-bp region of 87.3% homology. This region was detected at nucleotide positions -1845 to -1720 of c-Ha-ras and 20 bp 5' of the recombination breakpoint between VL30 and ras in Ha-MSV. On the basis of the sequence comparison between VL30, Ha-MSV, and c-Ha-ras, we are proposing a model which explains how VL30 may have facilitated the transduction of c-Ha-ras and perhaps the other ras proto-oncogenes. According to this model, the sequence homology between VL30 and c-Ha-ras targets this gene for transduction by promoting the integration of the provirus in this locus through homologous recombination.     

Harvey sarcoma virus genome contains no extensive sequences unrelated to those of other retroviruses except ras.

The Harvey murine sarcoma virus genome contains two rat-derived sets of genetic information recombined with the Moloney mouse leukemia virus. The rat sequences represent a ras oncogene and a rat VL30 element. The VL30 sequences have several discrete regions of similarity with retroviral sequences which were detected by searching a protein database for similarities with predicted polypeptide sequences from the VL30 regions. On the 5' side, the most similar sequences were those of feline sarcoma viruses; on the 3' side, murine leukemia viruses were the most similar. Some of the regions of similarity could also be detected directly by searching a nucleic acid sequence database with the viral DNA sequences. The most extensive region of similarity was that which corresponded to the endonuclease in the pol gene of a murine leukemia virus. The majority of the rat-derived sequences present in the Harvey sarcoma virus genome can now be attributed exclusively to ras or retrovirus- or retrotransposon-related sequences.     

Studies on the Nucleic Acid Sequences of Kirsten Sarcoma Virus: a Model for Formation of a Mammalian RNA-Containing Sarcoma Virus

The genetic information contained in the Kirsten and Moloney strains of mammalian RNA-containing sarcoma viruses has been analyzed by RNA . (3)H-DNA hybridization. Kirsten sarcoma virus has been found to possess two distinct sets of nucleic acid sequences. One set of sequences is contained in murine type C helper virus, and the other set is contained in rat type C helper virus. Moloney sarcoma virus contains sequences of murine type C helper virus but not of rat type C helper virus. The results indicate that Kirsten sarcoma virus arose through a process of recombination between Kirsten murine leukemia virus and nucleic acid sequences found in rat cells. A model is suggested for the formation of transforming type C viruses involving the transduction of oncogenic information.     

An internal ribosomal entry signal in the rat VL30 region of the Harvey murine sarcoma virus leader and its use in dicistronic retroviral vectors.

The genetic organization of the 5' genomic RNA domain of the highly oncogenic Harvey murine sarcoma virus appears to be unusual in that a multifunctional untranslated leader precedes the v-ras oncogene. This 5' leader is 1,076 nucleotides in length and is formed of independent regions involved in key steps of the viral life cycle: (i) the Moloney murine leukemia virus 5' repeat, untranslated 5' region, and primer binding site sequences necessary for the first steps of proviral DNA synthesis, (ii) the virus-like 30S (VL30)-derived sequence containing a functional dimerization-packaging signal (E/DLS) directing viral RNA dimerization and packaging into MLV virions, and (iii) an Alu-like sequence preceding the 5' untranslated sequence of v-rasH which contains the initiation codon of the p21ras oncoprotein. These functional features, the unusual length of this leader (1,076 nucleotides), and the presence of stable secondary structures between the cap and the v-ras initiation codon might well cause a premature stop of the scanning ribosomes and thus inhibit v-ras translation. In order to understand how Harvey murine sarcoma virus achieves a high level of expression of the ras oncogene, we asked whether the rat VL30 sequence, 5' to v-ras, could contribute to an efficient synthesis of the ras oncoprotein. The implications of the VL30 sequence in the translation initiation of Ha-ras were investigated in the rabbit reticulocyte lysate system and in murine cells. Results show that the rat VL30 sequence allows a cap-independent translation of a downstream reporter gene both in vitro and in murine cells. Additional experiments performed with dicistronic neo.VL30.lacZ mRNAs indicate that the 5' VL30 sequence (positions 380 to 794) contains an internal ribosomal entry signal. This finding led us to construct a new dicistronic retroviral vector with which the rat VL30 sequence was able to direct the efficient expression of a 3' cistron and packaging of recombinant dicistronic RNA into murine leukemia virus virions.     

Apparent recombinants between virus-liKE (VL30) and murine leukemia virus-related sequences in mouse DNA.

VL30 elements are a dispersed multigene family that is ubiquitous in all murine cells. Despite not sharing nucleic acid sequence homology with natural retroviruses (exogenous or endogenous), VL30 elements are distinguished by several retrovirus-like features. By screening a mouse embryonic library, we have cloned DNA units that contain VL30 sequences linked to MuLV-related sequences. Using blot hybridization with the aid of specific subgenomic probes and heteroduplex analyses, we have established that the DNA element is composed of two VL30 long terminal repeat (LTR) units, a limited subset of VL30 information adjacent to both 5' and 3' LTRs, and an enclosure of MuLV-related information that shares homology primarily with MuLV gag and pol determinants (but lacks MuLV-related LTRs). This sequence arrangement is reciprocal in nature to the recombinations between MuLV and rat VL30 that generated the genomes of the Harvey and Kirsten strains of mouse sarcoma virus and most likely is the consequence of recombination between VL30 and MuLV-related elements and the subsequent deposition of the putative recombinant DNA in the mouse genome.     

Heteroduplex Analysis of the Sequence Relationships Between the Genomes of Kirsten and Harvey Sarcoma Viruses, Their Respective Parental Murine Leukemia Viruses, and the Rat Endogenous 30S RNA

The sequence relations between Kirsten murine sarcoma virus (Ki-SV), Harvey murine sarcoma virus (Ha-SV), and a rat endogenous 30S RNA were studied by electron microscope heteroduplex analysis. The sequence relationships between the sarcoma viruses and their respective parental murine leukemia viruses (Kirsten and Moloney murine leukemia viruses), as well as between the two murine leukemia viruses, were also studied. The only observed nonhomology feature of the Kirsten murine leukemia virus/Moloney murine leukemia virus heteroduplexes was a substitution loop with two arms of equal length extending from 1.80 +/- 0.18 kilobases (kb) to 2.65 +/- 0.27 kb from the 3' end of the RNA. It is believed that this feature lies in the env gene region of the viral genomes. The Ha-SV and Moloney murine leukemia virus genomes (respective lengths, 6.0 and 9.0 kb) were homologous in a 1.0 +/- 0.05-kb region at the 3' end and possibly over a 200-nucleotide region at the 5' ends; otherwise, they were nonhomologous. Ha-SV and Ki-SV (length, 7.5 kb) were homologous in the first 4.36 +/- 0.37-kb region from the 3' end and in a 0.70 +/- 0.15-kb region at the 5' end. In between, there was a nonhomology region, possibly containing a short (0.23-kb) region of partial or total homology. The heteroduplex analysis between rat endogenous 30S RNA and Ki-SV shows that there are mixed regions of sequence homology and nonhomology at both the 5' and 3' ends. However, there is a large (4-kb) region of homology between Ki-SV and the rat 30S RNA in the center of the genomes, with only a small nonhomology hairpin feature. These studies help to define the regions of homology between the Ha-SV and Ki-SV genomes with each other and with the rat endogenous 30S RNA. These regions may be related to the sarcoma genicity of the viruses. In particular, the 0.7-kb region of homology of Ha-SV with Ki-SV at the 5' ends may be related to the formation of a 21,000-dalton phosphoprotein in cells transformed by either virus.     

Modulation of homo- and heterodimerization of Harvey sarcoma virus RNA by GACG tetraloops and point mutations in palindromic sequences

Retroviruses harbour a diploid genome of two plus-strand RNAs linked non-covalently at the dimer linkage structure. Co-packaging of two parental RNAs is a prerequisite for recombination in retroviruses, but formation of heterodimers has not been demonstrated directly in vivo. Here, we explore elements in Harvey sarcoma virus (HaSV) RNA involved in homodimerization and heterodimerization with RNA of Moloney (Mo) and Akv murine leukemia viruses (MLV).By an in vitro assay, we found that HaSV dimerization specificity could be modulated by mutations in a decanucleotide palindrome (Pal) probably folded into a kissing-loop. Autocomplementary and non-autocomplementary sequences introduced into the putative loop directed the specificity towards formation of homodimers and heterodimers, respectively. Two stem-loop (SL) structures, both exposing a GACG tetraloop, enhanced the formation of stable HaSV dimers.A similar decanucleotide palindrome has been implicated in homodimerization of MLVs. Heterodimers between HaSV RNA and Mo- or Akv MLV were unstable, but could be stabilized by introduction of two point mutations in the putative HaSV kissing-loop, creating exact complementarity with Mo/Akv MLV palindromes. Moreover, such changes increased the HaSV RNA affinity for the two MLV RNAs. Similar to HaSV RNA homodimers, formation of heterodimers with Mo- or Akv MLV RNAs was induced by the presence of GACG loops.On the basis of these results, we propose that palindromic sequences act as variable determinants of specificity and GACG tetraloops as conserved determinants in the formation of homodimers and heterodimers of gamma-retrovirus retroviral RNAs in vivo. The complementarity of loop sequences in the packaging signal upstream of the GACG tetraloops might therefore determine homo- and heterodimerization specificity and recombination activity of these viruses.     

Rat sequences of the Kirsten and Harvey murine sarcoma virus genomes: nature, origin, and expression in rat tumor RNA.

Two murine sarcoma viruses, the Kirsten and the Harvey, were isolated by passage of mouse type C leukemia viruses through rats. These sarcoma viruses have genomes containing portions of their parental type C mouse leukemia virus genomes, in stable association with specific rat cellular sequences that we find to be quite likely not those of a rat type C leukemia virus. To determine if these murine sarcoma viruses provide a model relevant to the events occurring in spontaneous tumors, we have hybridized DNA and RNA prepared from rat tumors and normal rat tissues to [3H]DNA prepared from the Kirsten murine sarcoma virus. We have also hybridized these rat tissue nucleic acids to [3H]DNA prepared from a respresentative endogenous rat type C leukemia virus, the WFU (Wistar-Furth). Sarcoma-viral rat cellular sequences and endogenous rat leukemia viral sequences were detected in the DNA of both tumor and normal tissues, with no evidence of either gene amplification or additional sequences being present in tumor DNA. Sarcoma-viral rat cellular sequences and endogenous rat leukemia viral sequences were detected at elevated concentrations in the RNA of many rat tumors and in specific groups of normal tissues.     

Physical map of the Kirsten sarcoma virus genome as determined by fingerprinting RNase T1-resistant oligonucleotides.

From analysis of the large RNase T1-resistant oligonucleotides of Kirsten sarcoma virus (Ki-SV), a physical map of the virus genome was deduced. Kirsten murine leukemia virus (Ki-MuLV) sequences were detected in T1 oligonucleotides closest to the 3' end of the viral RNA and extended approximately 1,000 nucleotides into the genome. The rat genetic sequences started at this point and extended all the way to the very 5' end of the RNA molecules, where a small stretch of Ki-MuLV sequence was detected. By comparison of the fingerprints of Ki-SV RNA and the RNA of the endogenous rat src genetic sequences, it was found that more than 50% of the T1 oligonucleotides were similar between Ki-SV and the endogenous rat src RNA, suggesting an identical primary nucleotide sequence in over 50% of the viral genomes. The results indicate that Ki-SV arose by recombination between the 5' and 3' ends of Ki-MuLV and a large portion of the homologous sequences of the endogenous rat src RNA.     

Virus-Like 30S RNA in Mouse Cells

Uninfected JLS-V9 mouse cells are known to express high levels of viral sequences that hybridize to complementary DNA made by the BrdU-induced virus of JLS-V9 cells. The genome in the BrdU-induced virus has been found to consist mainly of an RNA species that migrates as 30S RNA material during electrophoresis through agarose gels. This virus-like 30S RNA, designated VL30 RNA, apparently represents a new class of endogenous defective retroviruses that are not generally evident because of their defectiveness and lack of biological function. Fingerprint analysis and hybridization studies show that VL30 RNA does not have homology with the standard nondefective murine leukemia viruses. Upon superinfection with a nondefective murine leukemia virus, or upon induction of endogenous virus with BrdU, VL30 RNA is rescued into virions by phenotypic mixing. When VL30 RNA is rescued by BrdU induction, the VL30 RNA is mainly organized as a 50S complex, but when VL30 is rescued by superinfection, VL30 is also found in 70S RNA. Rescued VL30 RNA sequences can be reverse transcribed by the virion-associated DNA polymerase in an endogenous reaction. Many mouse cells express the sequences, whereas heterologous cells such as rat or rabbit cells do not contain them. By using hybridization of a complementary DNA probe to cellular RNA immobilized on paper, no subgenomic RNA related to the VL30 RNA could be found in cells expressing the VL30 sequences. From 20 to 50 copies of these sequences were found to be contained in the mouse genome. VL30 RNA is probably present in most stocks of leukemia and sarcoma viruses made in mouse cells.     

A small and efficient dimerization/packaging signal of rat VL30 RNA and its use in murine leukemia virus-VL30-derived vectors for gene transfer.

Retroviral genomes consist of two identical RNA molecules associated at their 5' ends by the dimer linkage structure located in the packaging element (Psi or E) necessary for RNA dimerization in vitro and packaging in vivo. In murine leukemia virus (MLV)-derived vectors designed for gene transfer, the Psi + sequence of 600 nucleotides directs the packaging of recombinant RNAs into MLV virions produced by helper cells. By using in vitro RNA dimerization as a screening system, a sequence of rat VL30 RNA located next to the 5' end of the Harvey mouse sarcoma virus genome and as small as 67 nucleotides was found to form stable dimeric RNA. In addition, a purine-rich sequence located at the 5' end of this VL30 RNA seems to be critical for RNA dimerization. When this VL30 element was extended by 107 nucleotides at its 3' end and inserted into an MLV-derived vector lacking MLV Psi +, it directed the efficient encapsidation of recombinant RNAs into MLV virions. Because this VL30 packaging signal is smaller and more efficient in packaging recombinant RNAs than the MLV Psi + and does not contain gag or glyco-gag coding sequences, its use in MLV-derived vectors should render even more unlikely recombinations which could generate replication-competent viruses. Therefore, utilization of the rat VL30 packaging sequence should improve the biological safety of MLV vectors for human gene transfer.     

Size of virus-specific RNA in B-34, a hamster tumor cell producing nucleic acids of type C viruses from three species.

B-34 is the designation of a hamster tumor-derived cell line induced by the Harvey sarcoma virus. This cell line produces virions which contain structural proteins common to edogenous hamster viruses and nucleic acid sequences of hamster, mouse, and rat origin. The sedimentation characteristics of the intracellular virus-specific RNA was determined in sucrose gradients after treatment with dimethylsulfoxide by molecular hybridization using complementary DNA of strict virus specificity. Hamster virus-specific RNA sedimented at 35S (major peak) as is characteristic of productive infection by type C leukemia viruses of other species. Rat virus-specific RNA sedimented at 30S which is characteristic of the sarcoma virus-related genome found in nonproducer cells transformed by Kirsten sarcoma virus. Both Harvey and Kirsten sarcoma viruses contain a related but not necessarily identical 30S rat-specific component which is also found in normal cultured rat cells. Mouse cells producing Harvey sarcoma virus also contain a rat-specific 30S RNA. Mouse virus-derived sequences also sedimented at 30S in B-34 cells and in a similar size range in Harvey virus-infected mouse cells. The possibility that the mouse and rat-derived sequences are present on a single 30S RNA species which would then be related to sarcomagenic potential is one attractive hypothesis suggested by these data.     

Structure and expression of mouse VL30 genes.

DNA sequencing and blot hybridization analyses have been used to study the structure of a mouse VL30 gene and the molecular nature of VL30-related RNA which is induced upon the stimulation of cultured AKR mouse embryo cells with defined peptide growth factors. An integrated mouse VL30 gene was found to contain identical 601-base-pair long terminal repeats (LTRs) which were themselves terminated in short inverted repeats. The entire VL30 gene was flanked by a 4-base-pair direct repeat of cellular DNA. Thus, VL30 genes are structurally analogous to integrated forms of retrovirus proviruses and certain other classes of mobile genetic elements. The LTR sequence was found to contain putative promoter and polyadenylation signals and generally exhibited little sequence homology to murine leukemia virus proviral LTRs. Certain short regions of sequence conservation, however, were evident, including the inverted terminal repeat, LTR-adjacent regions corresponding to origins of murine leukemia virus proviral DNA synthesis, and a 36-base-pair direct repeat bearing homology to the 72-base-pair direct repeat (enhancer sequence) of the murine leukemia virus-related Moloney sarcoma virus. Upon mitogenic stimulation of quiescent cells with epidermal growth factor and insulin, a major 5.5-kilobase VL30-specific RNA complementary to both LTR and non-LTR sequences was rapidly induced. We conclude that a complete VL30 gene(s) is highly regulated by peptide growth factor binding to specific membrane receptors in these cells.     

Characterizatiion of rat genetic sequences of Kirsten sarcoma virus: distinct class of endogenous rat type C viral sequences.

The nucleic acid sequences found in DNA and RNA from rat cells which are homologous to Kirsten sarcoma virus have been characterized. The homologous sequences are present in multiple copies per diploid rat cellular genome in a variety of different rat cellular dna's. In certain cells that constitutively express only low levels of sequences homologous to Kirsten sarcoma virus, bromodeoxyuridine treatment leads to the expression of high levels of these sequences in RNA. Supernatants from cell lines producing the sequences homologous to Kirsten sarcoma virus contain high levels of these sequences which are purified to the same degree as the previously known rat type C viral nucleic acid sequences by type C particles being released from such cells. The results indicate that the sequences in rat cells homologous to Kisten sarcoma virus have three characteristics of known mammalian type C viruses, and suggest that at least part of Kirsten sarcoma virus rat-derived sequences represent a distinct class of endogenous rat type C virus that has no detectable homology to the other known class of endogenous rat type C virus.     

Discrete regions of sequence homology between cloned rodent VL30 genetic elements and AKV-related MuLV provirus genomes

Southern blot analyses using reduced stringency hybridization conditions have been employed to search for sequence homologies between rodent VL30 genes and murine leukemia virus (MuLV) proviruses. These constitute two classes of transposon-like elements previously believed to be genetically unrelated. Our results demonstrate that cloned representatives of both ecotropic and xenotropic-like proviruses share discrete regions of sequence homology with VL30 genes of both rat and mouse origin. These regions of homology exist in both 3' and 5' halves of the MuLV genome but do not include extensive portions of the long terminal repeat (LTR) or a 0.4 Kbp segment of the env gene specific for recently acquired ecotropic-type MuLV proviruses. DNA sequencing, however, revealed that the short inverted terminal repeat sequence of MuLV proviral LTRs is almost perfectly conserved at the terminus of an integrated mouse VL30 gene. These results suggest that recombination events with rodent VL30-type sequences occurred during early MuLV evolution. The strong conservation of the inverted terminal repeat sequence may reflect a common integration mechanism for VL30 elements and MuLV proviruses.