Analysis of a 5' leader sequence on murine leukemia virus 21S RNA: heteroduplex mapping with long reverse transcriptase products

Mobile dispersed genetic elements and their possible relation to carcinogenesis

In this paper, a hypothesis is described according to which mobile dispersed genetic elements are related to endogenous viral genomes and may be involved in oncogenic transformation by uptaking cellular genes important for cellular growth. It is also possible that, in certain cases, they can switch off the genes involved in the control of differentiation.

Mobile dispersed genetic element MDG1 of Drosophila melanogaster: transcription pattern

Virtually the whole region of the mobile dispersed genetic element mdg1 including the direct repeats that frame mdg1 /1/ is transcribed. The end of the transcriptional unit is located within the direct repeat. Although the transcription of mdg1 is symmetric, one direction is transcribed preferentially and is a full-length transcript represented by approximately 29S poly(A)+RNA. Besides it, approximately 15S poly(A)+RNA is present in the cytoplasm of culture cells which corresponds to the 3'-part of 29S RNA and possibly to a small region near the 5'-end of the latter. The major fraction of mdg1 transcripts is present in the fraction of free cytoplasmic RNP particles while only 10-20% are recovered in polysomes. In this respect, mdg1 is similar to mdg3 and quite different from two single-copy genes transcripts of which are almost completely recovered in polysomes. The relationship between mobile dispersed genetic elements and endogeneous viral genomes is discussed.

Characterization of a unique defective type C virus associated with a Moloney leukemia virus-induced splenic T-cell lymphoma cell line

Moloney leukemia virus (MoLV) induces lymphomas in BALB/c mice which either involve an immature thymic T-cell subpopulation or a splenic mature T-cell subpopulation. To investigate further the possible virological and immunological differences in these lymphomas, several lymphoma cell lines were derived. Although the majority of these cell lines expressed only the parental MoLV, one lymphoma cell line (5F4) was found which expressed only a defective virus. 5F4 virions lacked detectable reverse transcriptase activity and by immunoprecipitation lacked a serologically detectable reverse transcriptase. The lack of reverse transcriptase did not appear to be due to a deletion in the viral genome. Intracellularly 5F4 cells synthesized normal gag gene precursors but had little, if any, detectable Pr180gag-pol or an altered precursor. These results suggest that the defect of the 5F4 virus is associated with the inability to translate the appropriate precursor for reverse transcriptase. The possible origin of the detective 5F4 virus was also examined by competition radioimmunoassays. These results demonstrate that the type-specific proteins, gp71 and p12, are serologically identical to those of the endogenous ecotropic virus and distinct from the MoLV proteins. Competition assays of 5F4 cell extracts further demonstrated the lack of any detectable MoLV type-specific proteins, although the tumor was presumably induced by MoLV. The significance of these observations to leukemogenesis is discussed.

Correlation of RNA binding affinity of avian oncornavirus p19 proteins with the extent of processing of virus genome RNA in cells

We purified the p19 proteins from the Prague C strain of Rous sarcoma virus, avian myeloblastosis virus, B77 sarcoma virus, myeloblastosis-associated virus-2(0), and PR-E 95-C virus and measured their binding affinities for 60S viral RNA by the nitrocellulose filter binding technique. The apparent association constants of the p19 proteins from Rous sarcoma virus Prague C, avian myeloblastosis virus, and B77 sarcoma virus for homologous and heterologous 60S RNAs were similar (1.5 x 10(11) to 2.6 x 10(11) liters/mol), whereas those of myeloblastosis-associated virus-2(0) and PR-E 95-C virus were 10-fold lower. The sizes and relative amounts of the virus-specific polyadenylic acid-containing RNAs in the cytoplasms of cells infected with Rous sarcoma virus Prague C, myeloblastosis-associated virus-2(0), and PR-E 95-C virus were determined by fractionating the RNAs on agarose gels containing methylmercury hydroxide, transferring them to diazobenzyloxymethyl paper and hybridizing them to a 70-nucleotide complementary DNA probe. In cells infected with Rous sarcoma virus Prague C we detected 3.4 x 10(6)-, 1.9 x 10(6)-, and 1.1 x 10(6)-dalton RNAs, in PR-E 95-C virus-infected cells we detected 3.4 x 10(6)-, 1.9 x 10(6)- and 0.7 x 10(6)-dalton RNAs, and in cells infected with myeloblastosis-associated virus-2(0) we detected 3 x 10(6)- and 1.3 x 10(6)-dalton RNAs. Each of these RNA species contained RNA sequences derived from the 5' terminus of genome-length RNA, as evidenced by hybridization with the 5' 70-nucleotide complementary DNA. The ratios of subgenomic mRNA's to genome-length RNAs in cells infected with myeloblastosis-associated virus-2(0) and PR-E 95-C virus were three- to five-fold higher than the ratio in cells infected with Rous sarcoma virus Prague C. These results suggest that more processing of viral RNA in infected cells is correlated with lower binding affinities of the p19 protein for viral RNA, and they are consistent with the hypothesis that the p19 protein controls processing of viral RNA in cells.

Nucleotide sequence analysis of the transforming region and large terminal redundancies of Moloney murine sarcoma virus

The sequence of the transforming region of the Moloney murine sarcoma virus genome has been determined by using molecularly cloned viral DNA. This region, 3.6 to 5.8 kilobase pairs from the left end of the molecule, contains the entire cellular insertion (src) sequence as well as helper viral sequences including the large terminal repeat (LTR). On the viral RNA strand, a long (1224 bases) open reading frame commenced to the left of the src-helper virus junction and terminated at a point 58 nucleotides into helper viral sequences to the right of src. Possible promoter and acceptor splice signals were detected in helper viral sequences upstream from this open reading frame. On the antiviral RNA strand, several promoter-like sequences, including one within the src region itself, were identified. However, no open reading frame downstream from these promoters was detected in the antiviral RNA strand. The LTR was found to contain promoter-like sequences as well as LTR was found to contain promoter-like sequences as well as mRNA capping and polyadenylylation signals. In addition, it possessed an 11-base inverted terminal repeat at each end. Thus, the structure of the Moloney murine sarcoma virus genome with an LTR at each end resembles that of prokaryotic transposable elements.

Suppression of murine retrovirus polypeptide termination: effect of amber suppressor tRNA on the cell-free translation of Rauscher murine leukemia virus, Moloney murine leukemia virus, and Moloney murine sarcoma virus 124 RNA

The effect of suppressor tRNA's on the cell-free translation of several leukemia and sarcoma virus RNAs was examined. Yeast amber suppressor tRNA (amber tRNA) enhanced the synthesis of the Rauscher murine leukemia virus and clone 1 Moloney murine leukemia virus Pr200(gag-pol) polypeptides by 10- to 45-fold, but at the same time depressed the synthesis of Rauscher murine leukemia virus Pr65(gag) and Moloney murine leukemia virus Pr63(gag). Under suppressor-minus conditions, Moloney murine leukemia virus Pr70(gag) was present as a closely spaced doublet. Amber tRNA stimulated the synthesis of the "upper" Moloney murine leukemia virus Pr70(gag) polypeptide. Yeast ochre suppressor tRNA appeared to be ineffective. Quantitative analyses of the kinetics of viral precursor polypeptide accumulation in the presence of amber tRNA showed that during linear protein synthesis, the increase in accumulated Moloney murine leukemia virus Pr200(gag-pol) coincided closely with the molar loss of Pr63(gag). Enhancement of Pr200(gag-pol) and Pr70(gag) by amber tRNA persisted in the presence of pactamycin, a drug which blocks the initiation of protein synthesis, thus arguing for the addition of amino acids to the C terminus of Pr63(gag) as the mechanism behind the amber tRNA effect. Moloney murine sarcoma virus 124 30S RNA was translated into four major polypeptides, Pr63(gag), P42, P38, and P23. In the presence of amber tRNA, a new polypeptide, Pr67(gag), appeared, whereas Pr63(gag) synthesis was decreased. Quantitative estimates indicated that for every 1 mol of Pr67(gag) which appeared, 1 mol of Pr63(gag) was lost.

Molecular cloning of Snyder-Theilen feline leukemia and sarcoma viruses: comparative studies of feline sarcoma virus with its natural helper virus and with Moloney murine sarcoma virus

Extrachromosomal DNA obtained from mink cells acutely infected with the Snyder-Theilen (ST) strain of feline sarcoma virus (feline leukemia virus) [FeSV(FeLV)] was fractionated electrophoretically, and samples enriched for FeLV and FeSV linear intermediates were digested with EcoRI and cloned in lambda phage. Hybrid phages were isolated containing either FeSV or FeLV DNA "inserts" and were characterized by restriction enzyme analysis, R-looping with purified 26 to 32S viral RNA, and heteroduplex formation. The recombinant phages (designated lambda FeSV and lambda FeLV) contain all of the genetic information represented in FeSV and FeLV RNA genomes but lack one extended terminally redundant sequence of 750 bases which appears once at each end of parental linear DNA intermediates. Restriction enzyme and heteroduplex analyses confirmed that sequences unique to FeSV (src sequences) are located at the center of the FeSV genome and are approximately 1.5 kilobase pairs in length. With respect to the 5'-3' orientation of genes in viral RNA, the order of genes in the FeSV genome is 5'-gag-src-env-c region-3'; only 0.9 kilobase pairs of gag and 0.6 kilobase pairs of env-derived FeLV sequences are represented in ST FeSV. Heteroduplex analyses between lambda FeSV or lambda FeLV DNA and Moloney murine sarcoma virus DNA (strain m1) were performed under conditions of reduced stringency to demonstrate limited regions of base pair homology. Two such regions were identified: the first occurs at the extreme 5' end of the leukemia and both sarcoma viral genomes, whereas the second corresponds to a 5' segment of leukemia virus "env" sequences conserved in both sarcoma viruses. The latter sequences are localized at the 3' end of FeSV src and at the 5' end of murine sarcoma virus src and could possibly correspond to regions of helper virus genomes that are required for retroviral transforming functions.

Structure of murine sarcoma virus DNA replicative intermediates synthesized in vitro

Moloney murine sarcoma virions synthesize discrete DNA products in vitro which closely resemble those found in vivo shortly after infection. These in vitro products have been isolated by electrophoresis and mapped with restriction endonucleases. In addition to the full-genome-length 6-kilobase pair linear DNA, a 5.4-kilobase pair circular DNA molecule, an incomplete linear DNA molecule, and a 600-base pair molecule were detected. The 6-kilobase pair DNA contained a 600-base pair direct terminal repeat which was missing from the circular form and was partially represented on the incomplete linear DNA molecule. The 600-base pair DNA contained sequences which were present in the 600-base pair direct repeat on the 6-kilobase pair DNA. The order of synthesis and the structure of these molecules detected in the in vitro reaction suggest that they are crucial intermediates in the formation of the final product of in vitro reverse transcription. A model which accounts for the synthesis of all of these molecules during the initial stages of viral replication is suggested.

Genome organization of retroviruses. V. In vitro-synthesized Moloney murine leukemia viral DNA has long terminal redundancy

Purified virions of Moloney murine leukemia virus can synthesize genome-length double-stranded DNA in vitro. Two predominant species of long DNA transcripts, with average sizes of 9.1 and 8.5 kilobases (kb) can be identified. Both species of DNA contain the negative (complementary to viral RNA) and positive (same polarity as viral RNA) strands. However, only the negative strand of the 8.5-kb species can be identified if the synthesis of DNA is carried out in the presence of the drug actinomycin D. The 9.1-kb species appears to be slightly larger than the genomic RNA. If the linear double-stranded 9.1-kb species is treated with Escherichia coli exonuclease III and allowed to anneal, circular DNA molecules can be observed. Furthermore, polyadenylate-containing short genomic RNA fragments (0.5 to 1.0 kb) can anneal to both the 5' and the 3' termini of 9.1-kb complementary DNA. The polyadenylate moiety of the RNA fragments can be identified by tagging it with circular polyoma DNA containing polydeoxybromouridylic acid tails. Thus, the 9.1-kb complementary DNA transcript with two circular polyoma DNA molecules at its termini can be observed. However, when similar annealings are performed with 8.5-kb complementary DNA species, only one end of the resulting molecule has circular polyoma DNA. We conclude that the 9.1-kb complementary DNA species has a large terminal redundancy. The sequences involved in terminal redundancy appear to be derived from the 3' end of the genomic RNA.

Glucocorticoid regulation of mouse mammary tumor virus gene expression

Glucocorticoid hormones act rapidly and specifically to stimulate the synthesis of mouse mammary tumor virus RNA in a variety of mouse mammary tumor cells and infected heterologous cells. The increase in viral RNA production appears to be mediated by receptor proteins and requires the presence of basal levels of viral RNA. Infection of heterologous cells with MMTV may alter host cell responses to glucocorticoids; in addition, production of unintegrated viral DNA in these cells has provided reagents required for studying the structure and function of the viral DNA itself. The advent of new techniques for genetic manipulation of eukaryotic cells and for isolation of large amounts of specific DNA sequences should now permit detailed analyses of steroid hormone action in this system.

Structure of the Abelson murine leukemia virus genome

Virions produced from cells transformed by A-MuLV contain a 30S, 5.6 kb RNA that can be translated in a cell-free system to form the characteristic A-MuLV protein. This RNA was mapped by heteroduplex methods using DNA probes from M-MuLV, the presumed parent of A-MuLV. The overall organization of the RNA was determined by using full-length M-MuLV reverse transcribed DNA and visualizing the heteroduplexes in the electron microscope. This showed that A-MuLV and M-MuLV have homologous sequences at both ends of their RNAs but that the central portion of the A-MuLV genome is not homologous to sequences in M-MuLV RNA. A precise measure of the lengths of the shared regions was obtained by using S1 nuclease to digest hybrids between 32P-labeled M-MuLV DNA and A-MuLV RNA; the resulting fragments were analyzed for their length by electrophoresis. The regions of homology were shown to be 1320 nucleotides long at the 5' end and 730 nucleotides long at the 3' end. Thus approximately 6200 nucleotides of the approximately 8300 in M-MuLV RNA were deleted when the A-MuLV genome was formed, but an insert of 3600 nucleotides, presumably derived from the normal murine genome, was inserted in place of the deleted region.

The transforming gene of Moloney murine sarcoma virus

A cleavage map of the Moloney murine sarcoma viral DNA was constructed and compared with that of a spontaneously occurring deletion mutant. By restriction enzyme analysis, it was shown that a region encompassing over 40% of the viral information was not essential for transformation or rescue of the deletion mutant. The transforming region was further localised by analysis of the transforming activity in tissue culture of isolated restriction fragments of linear duoble-stranded sarcoma viral DNA. In each case, DNA fragments that retained transforming activity preserved the cell-derived insertion sequences of the viral genome. Moreover, such transformants invariably expressed RNA specific to this region. By these two approaches, it was possible to demonstrate that the transforming region of the viral genome begins very near or within the cell-derived insertion sequences. Thus, the transforming gene of this mammalian sarcoma virus originates from within the mouse cell genome.

A detailed model of reverse transcription and tests of crucial aspects

A model of reverse transcription has been devised by which the detailed architecture of ten molecular structures is predicted. The model includes a number of novel features for which experimental evidence is presented. First, growing minus DNA strand is copied from the viral RNA only up to a position about 150 nucleotides from the 5' end of the RNA. Second, plus-strand DNA, after being copied from approximately 600 nucleotides at the 5' end of the minus-strand DNA, then transcribes the first approximately 20 nucleotides of the tRNApro primer (which is covalently attaced to the 5' end of the minus DNA strand). The 3' ends of the minus and plus DNA probably form a hybrid through the homology conferred by the primer binding site sequences. Third, the minus and plus DNA strands are elongated in a continuous fashion resulting in a linear double-stranded DNA molecule containing a 600 nucleotide direct repeat at both ends. The most of the features of the model have experimental support, and it appears to provide a credible description of reverse transcription.

Enrichment of C-type virus mRNA from immunochemically separated polyribosomes

A method for the isolation of mRNA from a c-type virus-positive cell (JLS-V6) has been developed. This method consisted of (i) specific immunochemical precipitation of polyribosomes synthesizing viral proteins, (ii) extraction of the mRNA from the polyribosome/antigen/antibody complex, and (iii) separation of poly-A containing RNA by affinity chromatography on oligo-d(T)-cellulose. Three size classes of virus specific poly-A containing mRNA are identified and they are 35S, 20S-25S, and 10S-15S.

On pre-messenger RNA and transcriptions. A review

From the present review integrating old and new data emerge a few principles of gene expression in eukaryotes, and an infinite variety of possible mechanistic details generating the overal pattern. The few principles, most of which are not fundamentally new, may thus be summarized. 1) The eukaryotic genome is subdivided into transcriptional units: into transcriptons which are subject to individual activation controlled at DNA level. 2) Viral genomes may contain one or a few transcriptons, while cells of multicellular organisms contain from 3 x 10(3) in diptera up to an estimated 2 x 10(5) in birds and mammals. 3) Transcriptons may include one or several coding sequences. 4) Transcriptons vary considerably in size: in mammals and birds their size spectrum falls into the 2,000 to 20,000 bp range. 5) Units of coding information constituting one message (genes) and, possibly, units of regulative information are frequently broken up and stored within the transcripton in sub-genic blocks (of so far unknown significance) in general located at a certain distance from the 5' and 3' transcript terminals which are determined by the promotor and terminator signals. 6) The gene, in its specific definition as the functional unit underlying the phenotype, is in general constituted posttranscriptionally by the processing mechanisms from the mosaic of its genomic subunits in the transcripton; segments of coding, service and regulative sequences are recombined within themselves and with each other, polygenic transcripts separate into their unit messages. 7) Activated transcriptons produce pre-mRNA; these primary transcripts are colinear with the DNA of the transcriptional unit. 8) Primary pre-mRNA is processed into secondary pre-mRNA's by extragenic cleavage and intragenic ("splicing") processing, giving rise stepwise to functional mRNA. During this process chemical modifications as methylation, 5'-terminal capping and 3'-terminal polyadenylation take place. 9) Translation yields either potentially functional polypeptides or polycistronic polyproteins subject to further processing. 10) Processing is a regulated process; it involves many of the possible phases and mechanisms of post-transcriptional regulation (cf. 39, 40).

An MSV-specific subgenomic mRNA in MSV-transformed G8-124 cells

An intracellular subgenomic RNA species from MSV-transformed G8-124 cells was characterized by electron microscopy of RNA:cDNA heteroduplexes using long cDNAs both MSV and MuLV. This subgenomic RNA, 3.1 kb long, consisted of 5'-derived sequences of about 0.4 kb joined to 2.7 kb of RNA derived from the 3' end of the RNA genome. The 3'-derived sequences included the residual sequences from the MuLV pol region and the acquired cellular sequences of MSV. The genome of MSV was shown to retain approximately 0.13 kb from the 5' end of the MuLV env region, including sequences which span the point in the MuLV env mRNA. No subgenomic MSV RNA could be detected, however, which consisted of a 5'-derived leader sequence spliced to the retained env region sequences. Nor could a subgenomic MSV RNA be detected in which a 5'-derived leader sequence was joined directly to the acquired cellular sequences. Although its translation products are unknown, the subgenomic MSV RNA was present in preparations of poly(A)+ polysomal RNA, consistent with this RNA functioning as a messenger. The structure of this 3.1 kb MSV subgenomic RNA suggests a possible role in the expression of 3'-encoded MSV information, possibly including transformation-specific sequences.

In vitro synthesis of a 9 kbp terminally redundant DNA carrying the infectivity of Moloney murine leukemia virus

Detergent-disrupted virions of Moloney murine leukemia virus synthesize a 9 kbp double-stranded infectious DNA. It contains mainly full-length, single-stranded DNA, and its infectivity and size are insensitive to digestion by the single-strand-specific S1 nuclease. Analysis of fragmentation of the DNA using restriction endonucleases has shown that it is indistinguishable from the linear double-stranded DNA synthesized in infected cells. On the basis of the positions of the cleavage sites for a number of enzymes, the 9 kbp DNA has a 575 base direct terminal repetition. It is longer than the viral RNA at both ends, evidently due to repetitive copying of segments of the RNA. Virions also synthesize an 8.4 kbp double-stranded circular DNA that lacks one copy of the terminal repetition, as well as viral DNA longer than 9 kbp. The enzymatic machinery in the virions of retroviruses therefore appears to be responsible for all the steps involved in making fully double-stranded linear and one form of circular DNA.

At least 104 nucleotides are transposed from the 5' terminus of the avian sarcoma virus genome to the 5' termini of smaller viral mRNAs

Cells producing avian sarcoma virus (ASV) contain at least three virus-specific mRNAs, two of which are encoded within the 3' half of the viral genome. Each of these viral RNAs can hybridize with single-stranded DNA(cDNA5') that is complementary to a sequence of 101 nucleotides found at the 5' terminus of the ASV genome, but not within the 3' half of the genome. We proposed previously (Weiss, Varmus and Bishop, 1977) that this nucleotide sequence may be transposed to the 5' termini of viral mRNAs during the genesis of these RNAs. We now substantiate this proposal by reporting the isolation and chemical characterization of the nucleotide sequences complementary to cDNA5' in the genome and mRNAs of the Prague B strain of ASV. We isolated the three identified classes of ASVmRNA (38, 28 and 21S) by molecular hybridization; each class of RNA contained a "capped" oligonucleotide identical to that found at the 5' terminus of the ASV genome. When hybridized with cDNA5', each class of RNA gave rise to RNAase-resistant duplex hybrids that probably encompassed the full extent of cDNA5'. The molar yields of duplex conformed approximately to the number of virus-specific RNA molecules in the initial samples; hence most if not all of the molecules of virus-specific RNA could give rise to the duplexes. The duplexes prepared from the various RNAs all contained the capped oligonucleotide found at the 5' terminus of the viral genome and had identical "fingerprints" when analyzed by two-dimensional fractionation following hydrolysis with RNAase T1. In contrast, RNA representing the 3' half of the ASV genome did not form hybrids with cDNA5'. We conclude that a sequence of more than 100 nucleotides is transposed from the 5' end of the ASV genome to the 5' termini of smaller viral RNAs during the genesis of these RNAs. Transposition of nucleotide sequences during the production of mRNA has now been described for three families of animal viruses and may be a common feature of mRNA biogenesis in eucaryotic cells. The mechanism of transposition, however, and the function of the transposed sequences are not known.

Electron microscopic evidence for splicing of Moloney murine leukemia virus RNAs

Poly (A) containing RNA extracted from Moloney murine leukemia virus infected mouse cells was hybridized with long single-stranded complementary DNA, prepared in detergent disrupted virions. Visualization of the hybrids in the electron microscope revealed among the structures, circles and circles with tails. Measurements performed on the circular molecules revealed two major species with circumferences corresponding to 3 and 8.2 kilobases. The latter structures had identical size to circles obtained after annealing of cDNA with the viral genome, 35S RNA. Circularization of a small viral RNA (3 kb) from infected cells in the RNA-cDNA hybrids is a direct evidence that like the 35S RNA it shares similar nucleotide sequences at both the 5' and 3' ends. The presence of 5' end sequences common to the two RNA species indicates the existence of a spliced viral RNA. Furthermore, based on the circularization of viral RNA in the hybrids, we suggest a new way to quantitate and determine the lengths of spliced RNA in retrovirus infected cells.

Heteroduplex analysis of the nonhomology region between Moloney MuLV and the dual host range derivative HIX virus

The dual host range virus HIX has been previously characterized as an envelope gene recombinant between Moloney murine leukemia virus (Mo-MuLV) and an unidentified xenotropic murine leukemia virus. Using long reverse transcripts of Mo-MuLV, a region of nonhomology has been mapped by electron microscopic analysis of heteroduplexes formed with HIX 35S virion RNA. In this nonhomology region, the Mo-MuLV cDNA strand measured approximately 900 nucleotides, mapping between 1.6 and 2.5 kilobases from the 3' end. In a previous study, hybridization of Mo-MuLV 21S RNA with Mo-MuLV cDNA resulted in the formation of different heteroduplex structures diagnostic of a noncontiguously coded leader sequence at the 5' end of the 21S RNA. Following hybridization of poly(A)+ HIX 21S RAN with 8.2 kb Mo-MuLV cDNA, analogous heteroduplex structures were observed exhibiting the Mo-MuLV:HIX substitution loop in the DNA:RNA segment of the molecules. This analysis permitted more precise mapping of the nonhomology region with respect to the splice point in the 21S presumptive glycoprotein mRNA. The mapping of this nonhomology region in HIX virus provides an internal visual marker for the 3' end of the genome which may prove useful in future analyses of other deletion or substitution derivatives of Mo-MuLV.

High frequency of aberrant expression of Moloney murine leukemia virus in clonal infections

Clones of cells were isolated from single virus-single cell infections of NIH/3T3 cells with Moloney murine leukemia virus. Approximately one third of such clones aberrantly expressed viral gene functions. One clone produced virus with altered plaque morphology, while others failed to produce particles able to make plaques on XC cells. In addition, clones that made particles lacking reverse transcriptase were found, and these did not synthesize the reverse transcriptase precursor Pr180 gag-pol. One clone (M23) lacked any detectable glycoprotein or reverse transcriptase. Despite these defects, each clone released particles of type C morphology, suggesting that gag gene function alone may be sufficient for particle production. All the particles contained viral RNA of 60-70S that was composed of the normal 35S size subunits except for M23, which had a deletion in the viral genome of approximately 1000-1500 nucleotides. A variety of defective clones were also isolated following infection of rat cells with Moloney virus. It is apparent that the murine leukemia virus genome is ofter mutated by spontaneous processes generating a wide range of phenotypes.