FTIR microscopy detection of cells infected with viruses.

Fourier-transform infrared (FTIR) microscopy is considered a comprehensive and sensitive method for detection of molecular changes in cells. The advantage of FTIR microspectroscopy over conventional FTIR spectroscopy is that it facilitates inspection of restricted regions of a cell culture or a tissue. We have shown that it is possible to apply FTIR microscopy as a sensitive and effective assay for the detection of cells infected with various members of the herpes family of viruses and retroviruses. Detectable and significant spectral differences between normal and infected cells were evident at early stages of the infection. Impressive changes in several spectroscopic parameters were seen in infected compared with uninfected cells. It seems that the change in spectral behavior is specific to the infecting virus, because cells infected with herpesviruses showed different spectral changes compared with cells infected with retroviruses.

Functional analysis of the murine sarcoma virus RNA packaging sequence.

We investigated the features of the Moloney murine sarcoma virus leader sequence necessary for RNA packaging function by using a deletion analysis approach. We found that sequences that extend beyond those characterized genetically in previous reports are important for optimal packaging efficiency. A fragment covering a minimum of four potential stem-loop structures is required for the shortest packaging element compatible with gene transfer. Our results reveal the extent to which each of the segments of the packaging sequence contribute to packaging efficiency.

Decreased susceptibility to calpains of v-FosFBR but not of v-FosFBJ or v-JunASV17 retroviral proteins compared with their cellular counterparts.

The c-Fos and c-Jun transcription factors are rapidly turned over in vivo. One of the multiple pathways responsible for their breakdown is probably initiated by calpains, which are cytoplasmic calcium-dependent cysteine proteases. The c-fos gene has been transduced by two murine oncogenic retroviruses called Finkel-Biskis-Jenkins murine sarcoma virus (FBJ-MSV) and Finkel-Biskis-Reilly murine sarcoma virus (FBR-MSV); c-jun has been transduced by the chicken avian sarcoma virus 17 (ASV17) retrovirus. Using an in vitro degradation assay, we show that the mutated v-FosFBR, but not v-FosFBJ or v-JunASV17, is resistant to calpains. This property raises the interesting possibility that decreased sensitivity to calpains might contribute to the tumorigenic potential of FBR-MSV by allowing greater accumulation of the protein that it encodes in infected cells. It has also been demonstrated that resistance to cleavage by calpains does not result from mutations that have accumulated in the Fos moiety of the viral protein but rather from the addition of atypical peptide motifs at its both ends. This observation raises the interesting possibility that homologous regions in viral and cellular Fos either display slightly different conformations or are differentially accessible to interacting proteins.

Enzymatic detection systems for non-isotopic in situ hybridization using biotinylated cDNA probes.

The feasibility of various non-isotopic enzymatic detection systems was tested for in situ hybridization using biotin-labelled, nick-translated cDNA probes. For this purpose, we isolated and prepared cDNA restriction fragments encoding the proteolytic cysteine proteinase cathepsin L and analysed Kirsten murine sarcoma virus-transformed BALB/3T3 cells, which have been shown to express high amounts of cytoplasmic RNA of this ras oncogene-induced proteinase. When compared on a semiquantitative basis, colorimetric non-isotopic detection of cDNA hybrids with avidin-biotin-peroxidase conjugates visualized by silver intensification of the nickel-diaminobenzidine end-product was superior to that obtained with avidin-biotin-alkaline phosphatase using different substrates for development. When the peroxidase staining technique was applied for RNA detection, it was found that overnight incubation in methanol containing hydrogen peroxide followed by deproteination with HCl was the most effective method for inhibition of endogenous peroxidase activity. For DNA detection, non-specific nucleic staining was completely abolished when heat treatment (100 degrees C) of the cell specimens was performed prior to hybridization.

Differential effects of oncogenic transformation on N-linked oligosaccharide processing at individual glycosylation sites of viral glycoproteins.

Hamster sarcoma virus (HSV) transformation of Nil-8 fibroblasts is associated with an increase in the average size of N-acetyllactosamine (complex) type N-linked glycans due to an increase in both the average number of branches/chain and in the fraction of N-linked glycans containing poly(GlcNAc(beta 1,3) Gal-(beta 1,4)) (polylactosaminylglycan) chains. Analysis of glycopeptides from the envelope glycoproteins of Sindbis virus and vesicular stomatitis virus (VSV) grown in Nil-8 and Nil/HSV cells indicated that the transformation-associated shift to larger N-linked oligosaccharides selectively affects some glycosylation sites far more than others. Glycosylation of the Sindbis virus glycoproteins and of Asn-179 of VSV G was similar in Nil-8 and Nil/HSV cells; oligosaccharide processing generally did not proceed beyond the biantennary complex stage. In contrast, Asn-336 of VSV G carried primarily biantennary complex glycans in Nil-8-grown virus (ratio, triantennary, and larger to biantennary complex glycans (tri+/bi) = 0.5) but more highly branched structures in Nil/HSV-grown virus (tri+/bi = 8.1). All of the triantennary or larger oligosaccharides from Asn-336 of Nil/HSV-grown VSV G bound to leukoagglutinating phytohemagglutinin-agarose, indicating the presence of a branch attached to the Man3GlcNAc2 core via a beta 1,6-linked GlcNAc residue and suggesting that increased UDP-GlcNAc:alpha-D-mannoside beta 1,6-N-acetylglucosaminyl transferase V (GlcNAc transferase V) activity accompanied transformation. At least 20% of these leukoagglutinating phytohemagglutinin-binding oligosaccharides were sensitive to an enzyme specific for polylactosaminylglycan chains, Escherichia freundii endo-beta-galactosidase.

The effect of cerulenin on the synthesis of the precursor gag polyprotein in defective murine leukemia and sarcoma virus producing cell lines.

The effect of cerulenin, an inhibitor of de novo fatty acid (and cholesterol) biosynthesis, on the synthesis of the precursor gag polyprotein, Pr65gag in a defective murine leukemia virus (334C) producing murine cell line (3JE) and a defective murine sarcoma virus (Gazdar) producing hamster cell line (HTG-2) was examined. In contrast to Moloney murine leukemia virus (M-MuLV) producing cell lines (MJD-54, clone 2) the amount of the Pr65gag remaining in the presence of cerulenin (20 micrograms/ml) was greatly reduced in both defective virus-infected cells. This effect appears specific for the Pr65gag polyprotein, since the env precursor polyprotein Pr80env was normally synthesized and remained undegraded in cerulenin-treated 3JE-infected cells. Thin-section electron micrographs showed an increased accumulation of virion particles in vesicles of treated HTG-2 cells.

Moloney murine sarcoma virus encoded p37mos expressed in yeast has protein kinase activity.

We describe the expression of the Moloney murine sarcoma virus env-mos protein (p37mos) in yeast under the control of the yeast GAL1 promoter. Consistent with our previous results concerning the p37mos protein kinase made in virus infected mouse cells, p37mos produced in yeast possesses autophosphorylation activity in an immune complex kinase assay using anti-mos (37-35) serum.

Expression of the v-mos gene alters a Mr 55,000 protein during acute infection by Moloney murine sarcoma virus.

Infection of the rat myoblast cell line, L6E9, with Moloney murine sarcoma virus (Mo-MuSV) clone 124, altered a cellular protein of Mr 55,000 (P55) within 2 days of infection. The alteration of P55 was observed as a reduction in its steady-state level in cell extracts. The reduction of P55 correlated with the appearance of p37mos in infected cells. Except for P55 and one other protein, no change was detected in the total protein pattern of infected cells compared to uninfected cells, as judged by either immunoblots of one-dimensional NaDodSO4 gels or direct two-dimensional gel analysis. P55 levels were unchanged when L6E9 cells were infected with Moloney murine leukemia virus or several different transforming retroviruses. To determine the specificity of this v-mos-induced effect on P55, L6E9 cells were acutely infected with a temperature-sensitive variant (ts110) of Mo-MuSV. When these cells were shifted from 39 degrees C to 33 degrees C, which activates the gag-mos gene product, the P55 level dropped by greater than 50% within 2-3 hr. Conversely, with a shift in temperature from 33 degrees C to 39 degrees C, the cells' P55 level returned to normal within 5 hr, starting at 30 min after shift. These results clearly show that v-mos expression in acutely infected L6E9 cells alters the cellular protein, P55.

Detection of the myristylated gag-raf transforming protein with raf-specific antipeptide sera.

The post-translational modifications of the gag-raf fusion proteins of the 3611 murine sarcoma virus (MSV) have been examined by inhibiting glycosylation with tunicamycin and by in vivo labeling with [3H]myristic acid. The results show that P75gag-raf is myristylated but not glycosylated and that P90gag-raf is glycosylated but not myristylated (and is now termed gP90gag-raf). gP90gag-raf expression appeared to become lost during passage of the transformed cells, and consequently does not appear to be necessary for the maintenance of transformation. raf-specific sera for detecting gag-raf fusion proteins have been obtained from synthetic peptides made from different regions of the predicted v-raf sequence. Immunoprecipitation of P75gag-raf with raf-specific sera directly confirmed the deduced v-raf sequence. The fact that P75gag-raf is both myristylated and precipitated by antiserum to a predicted carboxyl-terminal peptide of the v-raf gene established that the mature protein represents the entire coding region. The gP90gag-raf thus appears to be a glycosylated form of P75gag-raf specified by the gag sequences of the fusion protein, in analogy with Pr65gag and gPr80gag of murine leukemia viruses. Antiserum to the carboxyl-terminal P75gag-raf peptide was the most efficient in immunoprecipitation, and will be useful for detecting the product of the c-raf gene.

Synthesis of proviral DNA in inbred mouse-derived clones of cells expressing different Fv-1 phenotypes.

Formation of proviral DNAs by B-tropic murine leukaemia viruses (MLVs) was examined in N-type and dually permissive mutant cells derived from two inbred mouse strains, DDD and G, both of which are N-type. In the N-type cells, formation of circular proviral DNA was strongly suppressed relative to that of linear DNA. Mutation resulting in loss of the N-type Fv-1 restriction resulted in efficient formation of circular DNA by the previously restricted B-tropic MLV. This showed that Fv-1 restriction and inhibition of closed circular DNA formation were controlled by the same gene. The efficiency of formation of circular proviral DNA by the defective Kirsten murine sarcoma virus was determined by the tropism of the helper virus.

Neoplastic transformation of human epidermal keratinocytes by AD12-SV40 and Kirsten sarcoma viruses.

Recent investigations have begun to dissect the number and nature of genetic alterations associated with cancer cells. In the present study, primary human epidermal keratinocytes acquired indefinite life-span in culture but did not undergo malignant conversion in response to infection with a hybrid of adenovirus 12 and simian virus 40. Addition of Kirsten murine sarcoma virus, which contains a K-ras oncogene, to these cells induced morphological alterations associated with the acquisition of neoplastic properties. These findings demonstrate the malignant transformation of human primary epithelial cells in culture and support a multiple-step process for neoplastic conversion.

Incorporation of lipids into variants of Moloney sarcoma virus which produce gag-mos fusion proteins.

Several transforming gene products of mammalian retroviruses undergo post-translational addition of fatty acids. This report demonstrates that gag-mos fusion proteins from variant strains of murine sarcoma viruses incorporate both myristate and palmitate. However, the inefficiency of palmitate incorporation, as well as incorporation of that fatty acid into gag proteins, suggest that palmitate is metabolized to myristate before becoming bound to virus proteins. Furthermore, no detectable post-translational processing event is apparently required for addition of myristate, suggesting that such an event is unnecessary for association of gag-mos proteins with cell membranes.

Inhibition of retrovirus DNA supercoiling in interferon-treated cells.

The effect of interferon (IFN) on the cytoplasmic synthesis of murine sarcoma virus DNA, its transport to the host nucleus, and its integration into the cellular genome were investigated. For this purpose, at various intervals after infection. DNA was extracted from the cytoplasmic fraction, nuclear Hirt supernatant, and chromosomal DNA pellet. The relative amount of viral DNA was estimated by C0t kinetics analysis of hybridization to murine sarcoma virus-specific [3H]cDNA. IFN was found to delay viral DNA synthesis by about 2.5 h, but the amount of viral DNA eventually formed in IFN-treated cells was comparable to that of the control. The transport of this DNA to the nucleus was delayed by IFN for 6 to 18 h, but once again, all the cytoplasmic viral DNA formed in IFN-treated cells was eventually transferred to their nucleus. However, although the main part of the viral DNA formed in control cells was finally integrated into the host genome, no significant integration was observed in IFN-treated cells. Alkaline sucrose gradient analysis revealed that IFN inhibited the accumulation of supercoiled viral DNA in the nucleus. Since supercoiled viral DNA is considered a precursor to integrated provirus, this observation may suggest that IFN inhibits viral DNA integration by blocking its supercoiling.

Microfilaments and intermediate filaments in epithelial cells transformed by murine sarcoma or leukemia viruses.

The murine epithelial cell line MMC-E was used to study changes in the cytoskeletal organization associated with viral transformation of epithelial cells by two different viruses. The cells were transformed with Moloney mouse sarcoma virus (MSV) or murine leukemia virus (MuLV). The expression of actin, myosin and of intermediate filament proteins in the cells was then studied. In MMC-E cells actin and myosin were organized as belt-like structures at the edges of the border cells of the cell islands and also circumferentially in the cells inside the islands. The major change after transformation was the decrease of the actomyosin containing belt extending from cell to cell at the borders of the cell islands. Both MMC-E cells and the MSV-transformed cells contained keratin as a juxtanuclear granular aggregate whereas the MuLV-transformed cells showed bright fibrillar arrays of keratin. Both virus-transformed cell lines showed enhanced vimentin-specific fluorescence and analysis of their cytoskeletal polypeptides confirmed the result. Similar molecular forms of keratin polypeptides were seen in all cells by immunoblotting. Viral transformation of MMC-E epithelial cells thus leads to different changes in their cytoskeletal organization depending on the transforming viral or cellular gene.

Gag-mos Polyproteins encoded by variants of the Moloney strain of mouse sarcoma virus.

Two revertants of ts110 Moloney murine sarcoma virus (MuSV) with wild-type MuSV phenotype were examined for the presence of mos gene products, ts110 MuSV has a temperature-sensitive defect in a function required to maintain the transformed phenotype. The nonproducer 6m2 cell clone transformed by ts110 produces an 85,000-Da gag-mos protein (P85gag-mos) and a 58,000-Da gag protein (P58gag). A spontaneous revertant (clone 54-5A4) of the 6m2 cell clone produces a 100,000-Da protein (P100) recognized by antisera raised against murine leukemia virus p15, p12, and p30 but lacks determinants of p10, reverse transcriptase, and gp70. P100 was specifically recognized by antisera (anti-C3) prepared against a synthetic peptide representing the predicted C-terminal 12 amino acids of Moloney MuSV v-mos gene. Normal sera or anti-C3 blocked with excess synthetic peptide did not recognize P100. Thus, P100 is a product of the gag and mos genes. P100 was found to be phosphorylated. A second wild-type revertant (clone 204-3) was obtained by superinfection of ts110 nonproducer cells with Simian sarcoma associated virus (SSAV); it was also found to contain a phosphorylated P100gag-mos protein. The 204-3 cell clone also contained two gag polyproteins (Pr60gag and Pr55gag) of the size and antigenic properties of those found in SSAV-infected cells. These results provide two examples of P100 gag-mos proteins both derived from the P85gag-mos producing 6m2 cell clone. The P100 gag-mos polyproteins are made in amounts that are easily detected by radiolabeling experiments using [3H]leucine. The intracellular viral RNAs present in 6m2 cells and the two revertant clones were also examined. All three cell clones contained a 4.0 kb RNA hybridizing to v-mos sequences but only the 6m2 clone contained a 3.5 kb mos-containing RNA. Our findings indicate that the 3.5 kb RNA codes for P85gag-mos in cell-free translation experiments (Junghans et al., 1982, J. Mol. Biol. 161, 229). These findings as they relate to the mechanism that produces P100gag-mos instead of P85gag-mos are discussed.

Interferon-mediated inhibition of production of Gazdar murine sarcoma virus, a retrovirus lacking env proteins and containing an uncleaved gag precursor.

HTG2 cells are murine sarcoma virus-transformed hamster cells. These cells continuously produce Gazdar sarcoma virus particles which are devoid of viral envelope proteins and which contain the uncleaved gag precursor polyprotein, Pr65, as their major protein constituent. Human interferon-alpha elicited an antiviral response in these cells as shown by the inhibition of replication of vesicular stomatitis virus in interferon-treated cells. Extracellular production of the retroviral particles by these cells was also inhibited by interferon in a dose-dependent manner and this inhibition was abolished by a specific antiserum to interferon. The intracellular level of Pr65 was not lowered in the interferon-treated cells, indicating that inhibition of viral protein synthesis was not responsible for inhibition of virus production. The present study suggests that interferon-mediated inhibition of retrovirus production, in general, is not a consequence of either a defective interaction between viral nucleoprotein cores and viral envelope proteins or a defect in the proteolytic processing of the gag polyprotein, since neither of these processes occurs during the morphogenesis of Gazdar particles and their production is nonetheless inhibited by interferon.

Detection of a transforming gene product in cells transformed by Moloney murine sarcoma virus.

We identified, in cells transformed by Moloney murine sarcoma virus (M-MuSV clone 124), a protein encoded by the M-MuSV transforming gene, v-mos. An antiserum against a synthetic peptide corresponding to the C terminus of a protein predicted from the v-mos nucleotide sequence specifically recognizes a protein doublet of approximately 37,000 daltons from 35S-methionine-labeled M-MuSV 124-transformed producer cells. By peptide mapping, this protein is almost identical to the 37 kd in vitro translation product from the M-MuSV v-mos gene. Immunoprecipitates from 32P-labeled cells contain a single v-mos-specific phosphoprotein, which has at least six sites of phosphorylation containing phosphoserine. Pulse-chase experiments show that the lower band in the 35S-methionine-labeled doublet is the primary translation product, which is modified, probably by phosphorylation, to yield the upper band. A similar mos protein is immunoprecipitated from HT1-MuSV-transformed cells, but not from uninfected NIH/3T3 cells. These mos proteins are present at very low levels in transformed cell lines. Cells acutely infected with M-MuSV 124, however, transiently contain much higher levels of the mos protein. These high levels coincide with extensive cell mortality.

Identification of a precursor in the biosynthesis of the p21 transforming protein of harvey murine sarcoma virus.

The p21 transforming protein coded for by the v-ras gene of Harvey murine sarcoma virus (Ha-MuSV) migrates as a doublet band between 21,000 and 23,000 daltons during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The lower band of the doublet is designated p21, and the upper band is designated pp21 since it comigrates with the phosphorylated form of p21. By pulse-labeling with [35S] methionine, we detected a p21 precursor, pro-p21, which migrated as if it was approximately 1,000 daltons larger than p21. The precursor-product relationship was established by pulse-chase experiments with [25S] methionine in the presence of 100 micrograms of cycloheximide per ml, which inhibited all de novo protein biosynthesis. Within 4 h, pro-p21 was completely chased into p21, and during the next 24 h pp21 accumulated. Thus, formation of pp21 from p21 did not require de novo protein synthesis. By subcellular fractionation into cytosol amd membrane fractions, we found that pro-p21 was synthesized in a non-membrane-bound state and that shortly after its complete synthesis, the p21 product was associated with the membrane fraction. By selective cleavage of p21 at a unique aspartic acid-proline residue with 70% formic acid or with Staphylococcus aureus V8 protease, we found that the intramolecular site of pro-p21 processing was located in the C-terminal portion of the pro-p21 molecule. The possibilities that the precursor was involved in the assembly of p21 into the plasma membrane and, alternatively, that the processing was a step in the activation of p21 biochemical activities are discussed.

Complementary DNA copies of leukemia and sarcoma virus RNA contain sequences of deoxycytidylate and deoxyguanylate.

Single-stranded complementary DNA (cDNA) of the RNA of Gazdar murine sarcoma virus, Gz-MSV/MuLV; Moloney murine leukemia virus, M-MuLV; mouse mammary tumor virus, MMTV; and simian sarcoma virus, SSV-1, were synthesized in endogenous reverse transcriptase reaction. Gz-MSV/MuLV cDNA was also synthesized in exogenous in vitro reverse transcriptase reactions. In the endogenous reaction, 30-35S, or 6.0- to 7.9-kilobase-length cDNA transcripts were synthesized in high yield. In comparison, transcripts synthesized in exogenous reactions were 6.7S, or 0.39 kilobases. The complementarity of the transcripts was verified by both RNA/DNA hybridization and protection studies. dG and dC sequences were detected in 50-77% of the cDNA molecules by affinity chromatography, by annealing and masking studies, and by resistance to S1 nuclease. dT and dA sequences were not detected in the transcripts. These findings are discussed in relation to the possible selective blocking of transcription of retrovirus genes without interfering significantly with the transcription of cellular genes.

Structure of and alterations to defective murine sarcoma virus particles lacking envelope proteins and core polyprotein cleavage.

HTG2 hamster cells produce a defective murine sarcoma virus lacking gp70 and, consequently, viral surface projections (knobs), but the lack of knobs appears to have no effect on intramembrane particle distribution. In addition, it has been noted that the core of the virus remains in the "immature" form as a result of the failure of the polyprotein precursor (p65) to undergo cleavage. However, incubation of HTG2 virus with avian myoblastosis virus was found to yield specific cleavage products of p65.