Analysis of chicken ribosomal RNA genes and construction of lambda hybrids containing gene fragments.

The ribosomal RNA genes (ribosomal DNA) of chicken are present in approximately 200 copies and are cleaved into two fragments of molecular weight 5 X 10(6) and 12 to 14 X 10(6) by restriction endonuclease Eco RI. Recombinant phages have been constructed in vitro by joining the smaller fragment of ribosomal DNA and the outer arms of DNA from the vector lambdagtWES-lambdaC. In one of the recombinants, the coding strand of the cloned fragment is in the proper orientation for transcription with lambda "early" genes; in the other two the orientation is reversed, with the coding strand in the proper position for transcription with lambda "late" genes.

A role for DNA-PK in retroviral DNA integration.

Retroviral DNA integration is catalyzed by the viral protein integrase. Here, it is shown that DNA-dependent protein kinase (DNA-PK), a host cell protein, also participates in the reaction. DNA-PK-deficient murine scid cells infected with three different retroviruses showed a substantial reduction in retroviral DNA integration and died by apoptosis. Scid cell killing was not observed after infection with an integrase-defective virus, suggesting that abortive integration is the trigger for death in these DNA repair-deficient cells. These results suggest that the initial events in retroviral integration are detected as DNA damage by the host cell and that completion of the integration process requires the DNA-PK-mediated repair pathway.

Molecular modeling of the HIV-1 protease and its substrate binding site.

The human immunodeficiency virus (HIV-1) encodes a protease that is essential for viral replication and is a member of the aspartic protease family. The recently determined three-dimensional structure of the related protease from Rous sarcoma virus has been used to model the smaller HIV-1 dimer. The active site has been analyzed by comparison to the structure of the aspartic protease, rhizopuspepsin, complexed with a peptide inhibitor. The HIV-1 protease is predicted to interact with seven residues of the protein substrate. This information can be used to design protease inhibitors and possible antiviral drugs.

HTLV-III gag protein is processed in yeast cells by the virus pol-protease.

The gag-pol gene of HTLV-III (human T-lymphotropic virus), the virus linked to AIDS (acquired immune deficiency syndrome), was expressed in yeast, and processing of the gag precursor into proteins of the same size as those in the virion was observed. Processing of the gag gene in yeast cells mimics the process that naturally occurs in mammalian cells during maturation of virions. Therefore it was possible to perform mutational analysis of the virus genome to localize the gene that codes for the protease function to the amino terminal coding region of the pol gene. Since this region overlaps the gag gene, it is likely that ribosomal frameshifting occurs from gag to pol. Antibodies in all of the AIDS patients' sera tested recognized the yeast synthesized gag proteins, although the sera showed differences in relative reactivity to the individual gag proteins and the precursor. This yeast system should be valuable not only for production of viral proteins for diagnostic or vaccine purposes but also for analysis of the genetics and biochemistry of viral gene functions--parameters that are difficult to study otherwise with this virus.

Control of retroviral RNA splicing through maintenance of suboptimal processing signals.

The full-length retroviral transcript serves as genomic RNA for progeny virions, as an mRNA for structural proteins and enzymes, and as a pre-mRNA substrate for splicing that yields subgenomic mRNAs that encode other essential proteins. Thus, RNA splicing to form subgenomic mRNAs must be incomplete or regulated in order to preserve some of the full-length transcripts. We have used the avian sarcoma virus system to delineate the viral functions that are required in the regulation of the splicing event that forms the envelope glycoprotein (env) subgenomic mRNA. We observed previously that a specific insertion mutation just 5' of the env splice acceptor site resulted in nearly complete splicing to form env mRNA and a concomitant replication defect which is presumably due to a deficit of the full-length transcript. Replication-competent pseudorevertants contained second-site mutations that restored splicing control, and these mapped either just upstream or downstream of the env splice acceptor site. In this report, we show that splicing control at this site does not require expression of any known viral replication protein(s), nor does it appear to require the viral splice donor site. From these results and analysis of additional splicing mutations obtained by in vivo selection, we conclude that splicing is controlled through the maintenance of suboptimal cis-acting signals in the viral RNA that alter the efficiency of recognition by the cellular splicing machinery.

Role of the avian retrovirus mRNA leader in expression: evidence for novel translational control.

Avian retroviral mRNAs contain a long 5' untranslated leader of approximately 380 nucleotides. The leader includes sequences required for viral replication and three AUG codons which precede the AUG codon used for translational initiation of the gag and env genes. We have used sensitive, quantitative assays of viral gene transcription and translation to analyze the role of this mRNA leader in viral gene expression. By substituting segments from related viruses, we had previously shown that the endogenous avian provirus ev-1 contained a defective leader segment (B. R. Cullen, A. M. Skalka, and G. Ju, Proc. Natl. Acad. Sci. USA 80:2946-2950, 1983). The sequence analysis presented here, followed by comparison with the nondefective ev-2 endogenous provirus segment, identified the critical changes at nucleotides 4 and 7 upstream of the initiator AUG. These differences do not alter the most conserved nucleotides within the consensus sequence which precedes eucaryotic initiation codons, but lie within a nine-nucleotide region that is otherwise highly conserved among avian retrovirus strains. Analysis of a series of deletion mutants indicated that other sequences within the leader are also required for efficient expression. Characterization of the altered transcripts demonstrated that the presence of the defective ev-1 segment or the deletion of a ca. 200-nucleotide leader segment did not affect the steady-state level or splicing efficiency of these mRNAs. Thus, we conclude that the reduced expression of these mRNAs is due to a translational deficiency. These results indicate that specific leader sequences, other than the previously identified consensus nucleotides which precede eucaryotic AUG initiator codons, can influence eucaryotic gene translation.

v-src inhibits differentiation via an extracellular intermediate(s).

Murine 3T3L1 preadipocytes transformed by avian sarcoma virus were unable to differentiate in response to insulin or dexamethasone plus 1-methyl-3-isobutylxanthine, both potent inducers of differentiation of the nontransformed 3T3L1 parental line. Conditioned medium from transformed cells contained a relatively heat-stable factor(s) which inhibited the differentiation of untransformed parental 3T3L1 cells but did not induce any changes in their morphology. A protease-sensitive mitogen was also detected in the medium. The relationship between the two activities remains to be elucidated.

Genetic selection for balanced retroviral splicing: novel regulation involving the second step can be mediated by transitions in the polypyrimidine tract.

Incomplete splicing is essential for retroviral replication; and in simple retroviruses, splicing regulation appears to occur entirely in cis. Our previous studies, using avian sarcoma virus, indicated that weak splicing signals allow transcripts to escape the splicing pathway. We also isolated a series of avian sarcoma virus mutants in which env mRNA splicing was regulated by mechanisms distinct from those of the wild-type virus. In vitro splicing experiments with one such mutant (insertion suppressor 1 [IS1]) revealed that exon 1 and lariat-exon 2 intermediates were produced (step 1) but the exons were not efficiently ligated (step 2). In this work, we have studied the mechanism of this second-step block as well as its biological relevance. Our results show that the second-step block can be overcome by extending the polypyrimidine tract, and this causes an oversplicing defect in vivo. The requirement for regulated splicing was exploited to isolate new suppressor mutations that restored viral growth by down-regulating splicing. One suppressor consisted of a single U-to-C transition in the polypyrimidine tract; a second included this same change as well as an additional U-to-C transition within a uridine stretch in the polypyrimidine tract. These suppressor mutations affected primarily the second step of splicing in vitro. These results support a specific role for the polypyrimidine tract in the second step of splicing and confirm that, in a biological system, uridines and cytosines are not functionally equivalent within the polypyrimidine tract. Unlike the wild-type virus, the second-step mutants displayed significant levels of lariat-exon 2 in vivo, suggesting a role for splicing intermediates in regulation. Our results indicate that splicing regulation can involve wither the first or second step.

Comparison between the viral transforming gene (src) of recovered avian sarcoma virus and its cellular homolog.

Recovered avian sarcoma viruses are recombinants between transformation-defective mutants of Rous sarcoma virus and the chicken cellular gene homologous to the src gene of Rous sarcoma virus. We have constructed and analyzed molecular clones of viral deoxyribonucleic acid from recovered avian sarcoma virus and its transformation-competent progenitor, the Schmidt-Ruppin A strain of Rous sarcoma virus. A 2.0-megadalton EcoRI fragment containing the entire src gene from each of these clones was subcloned and characterized. These fragments were also used as probes to isolate recombinant phage clones containing the cellular counterpart of the viral src gene, termed cellular src, from a lambda library of chicken deoxyribonucleic acid. The structure of cellular src was analyzed by restriction endonuclease mapping and electron microscopy. Restriction endonuclease mapping revealed extensive similarity between the src regions of Rous sarcoma virus and recovered avian sarcoma virus, but striking differences between the viral src's and cellular src. Electron microscopic analysis of heteroduplexes between recovered virus src and cellular src revealed a 1.8-kilobase region of homology. In the cellular gene, the homologous region was interrupted by seven nonhomologous regions which we interpret to be intervening sequences. We estimate the minimum length of cellular src to be about 7.2 kilobases. These findings have implications concerning the mechanism of formation of recovered virus src and possibly other cell-derived retrovirus transforming genes.

Regulation of the human c-myc gene: 5' noncoding sequences do not affect translation.

The influence of untranslated 5' sequences on c-myc expression was compared by measuring the translational efficiencies of mRNAs which contain leaders derived from exon 1 or intron 1 of the human c-myc gene. Expression plasmids were constructed and introduced into COS cells, and the levels of c-myc mRNA and protein were examined. Our results show that mRNAs transcribed from constructs containing exon 1 or intron 1, which have different folding potential, are translated with approximately equal efficiencies. This suggests that the translation of c-myc mRNA is not controlled by secondary structure alone. In addition, we observed that transcripts in which exon 1 was deleted are not translated more efficiently, but are present at a higher steady-state level. Thus, this example provides evidence for possible control at the transcriptional level. Finally, since the c-myc product was produced in each of our test systems, the results suggest that this protein does not regulate its own transcription or translation via a specific interaction with c-myc exon 1 alone.

Residues critical for retroviral integrative recombination in a region that is highly conserved among retroviral/retrotransposon integrases and bacterial insertion sequence transposases.

Our comparison of deduced amino acid sequences for retroviral/retrotransposon integrase (IN) proteins of several organisms, including Drosophila melanogaster and Schizosaccharomyces pombe, reveals strong conservation of a constellation of amino acids characterized by two invariant aspartate (D) residues and a glutamate (E) residue, which we refer to as the D,D(35)E region. The same constellation is found in the transposases of a number of bacterial insertion sequences. The conservation of this region suggests that the component residues are involved in DNA recognition, cutting, and joining, since these properties are shared among these proteins of divergent origin. We introduced amino acid substitutions in invariant residues and selected conserved and nonconserved residues throughout the D,D(35)E region of Rous sarcoma virus IN and in human immunodeficiency virus IN and assessed their effect upon the activities of the purified, mutant proteins in vitro. Changes of the invariant and conserved residues typically produce similar impairment of both viral long terminal repeat (LTR) oligonucleotide cleavage referred to as the processing reaction and the subsequent joining of the processed LTR-based oligonucleotides to DNA targets. The severity of the defects depended upon the site and the nature of the amino acid substitution(s). All substitutions of the invariant acidic D and E residues in both Rous sarcoma virus and human immunodeficiency virus IN dramatically reduced LTR oligonucleotide processing and joining to a few percent or less of wild type, suggesting that they are essential components of the active site for both reactions.(ABSTRACT TRUNCATED AT 250 WORDS)

Wortmannin potentiates integrase-mediated killing of lymphocytes and reduces the efficiency of stable transduction by retroviruses.

Retroviral infection induces integrase-dependent apoptosis in DNA-PK-deficient murine scid lymphocytes. Furthermore, the efficiency of stable transduction of reporter genes is reduced in adherent cell lines that are deficient in cellular DNA-repair proteins known to mediate nonhomologous end joining (NHEJ), such as DNA-PK and XRCC4 (R. Daniel, R. A. Katz, and A. M. Skalka, Science 284:644-647, 1999). Here we report that wortmannin, an irreversible inhibitor of phosphatidylinositol 3-kinase (PI-3K)-related PKs, including the catalytic subunit of DNA-dependent protein kinase (DNA-PK(CS)) and ATM, sensitizes normal murine lymphocytes to retrovirus-mediated cell killing. We also show that the efficiency of stable transduction of reporter genes in human (HeLa) cells, mediated by either an avian sarcoma virus or a human immune deficiency virus type 1 vector, is reduced in the presence of wortmannin. The dose dependence of such reduction correlates with that for inhibition of PI-3K-related protein kinase activity in these cells. Results from wortmannin treatment of a panel of cell lines confirms that formation and/or survival of transductants is dependent on components of the NHEJ pathway. However, stable transduction is virtually abolished by wortmannin treatment of cells that lack ATM. These results suggest that ATM activity is required for the residual transduction observed in the NHEJ-deficient cells. Our studies support the hypothesis that DNA repair proteins of the NHEJ pathway and, in their absence, ATM are required to avoid integrase-mediated killing [corrected] and allow stable retroviral DNA transduction. The studies also suggest that cells can be sensitized to such killing and stable retroviral DNA integration blocked by drugs that inhibit cellular DNA repair pathways.

Sequence comparison in the crossover region of an oncogenic avian retrovirus recombinant and its nononcogenic parent: genetic regions that control growth rate and oncogenic potential.

NTRE 7 is an avian retrovirus recombinant of the endogenous nononcogenic Rous-associated virus-0 (RAV-0) and the oncogenic, exogenous, transformation-defective (td) Prague strain of Rous sarcoma virus B (td-PrRSV-B). Oligonucleotide mapping had shown that the recombinant virus is indistinguishable from its RAV-0 parent except for the 3'-end sequences, which were derived from td-PrRSV-B. However, the virus exhibits properties which are typical of an exogenous virus: it grows to high titers in tissue culture, and it is oncogenic in vivo. To accurately define the genetic region responsible for these properties, we determined the nucleotide sequences of the recombinant and its RAV-0 parent by using molecular clones of their DNA. These were compared with sequences already available for PrRSV-C, a virus closely related to the exogenous parent td-PrRSV-B. The results suggested that the crossover event which generated NTRE 7 took place in a region -501 to -401 nucleotides from the 3' end of the td-PrRSV parental genome and that sequences to the right of the recombination region were responsible for its growth properties and oncogenic potential. These sequences included a 148-base-pair exogenous-virus-specific region that was absent from the RAV-0 genome and the U3 region of the long terminal repeat. Since the exogenous-virus-specific sequences are expected to be missing from transformation-defective mutants of the Schmidt-Ruppin strain of RSV, which, like other exogenous viruses, grow to high titers in tissue culture and are oncogenic in vivo, we concluded that the growth properties and oncogenic potential of the exogenous viruses are determined by sequences in the U3 region of the long terminal repeat. However, we propose that the exogenous-virus-specific region may play a role in determining the oncogenic spectrum of a given oncogenic virus.

Retroviral DNA integration and the DNA damage response.

Retroviral DNA integration creates a discontinuity in the host cell chromatin and repair of this damage is required to complete the integration process. As integration and repair are essential for both viral replication and cell survival, it is possible that specific interactions with the host DNA repair systems might provide new cellular targets for human immunodeficiency virus therapy. Various genetic, pharmacological, and biochemical studies have provided strong evidence that postintegration DNA repair depends on components of the nonhomologous end-joining (NHEJ) pathway (DNA-PK (DNA-dependent protein kinase), Ku, Xrcc4, DNA ligase IV) and DNA damage-sensing pathways (Atr (Atm and Rad related), gamma-H2AX). Furthermore, deficiencies in NHEJ components result in susceptibility to apoptotic cell death following retroviral infection. Here, we review these findings and discuss other ways that retroviral DNA intermediates may interact with the host DNA damage signaling and repair pathways.

The catalytic domain of avian sarcoma virus integrase: conformation of the active-site residues in the presence of divalent cations.

BACKGROUND: Members of the structurally-related superfamily of enzymes that includes RNase H, RuvC resolvase, MuA transposase, and retroviral integrase require divalent cations for enzymatic activity. So far, cation positions are reported in the X-ray crystal structures of only two of these proteins, E. coli and human immunodeficiency virus 1 (HIV-1) RNase H. Details of the placement of metal ions in the active site of retroviral integrases are necessary for the understanding of the catalytic mechanism of these enzymes. RESULTS: The structure of the enzymatically active catalytic domain (residues 52-207) of avian sarcoma virus integrase (ASV IN) has been solved in the presence of divalent cations (Mn2+ or Mg2+), at 1.7-2.2 A resolution. A single ion of either type interacts with the carboxylate groups of the active site aspartates and uses four water molecules to complete its octahedral coordination. The placement of the aspartate side chains and metal ions is very similar to that observed in the RNase H members of this superfamily; however, the conformation of the catalytic aspartates in the active site of ASV IN differs significantly from that reported for the analogous residues in HIV-1 IN. CONCLUSIONS: Binding of the required metal ions does not lead to significant structural modifications in the active site of the catalytic domain of ASV IN. This indicates that at least one metal-binding site is preformed in the structure, and suggests that the observed constellation of the acidic residues represents a catalytically competent active site. Only a single divalent cation was observed even at extremely high concentrations of the metals. We conclude that either only one metal ion is needed for catalysis, or that a second metal-binding site can only exist in the presence of substrate and/or other domains of the protein. The unexpected differences between the active sites of ASV IN and HIV-1 IN remain unexplained; they may reflect the effects of crystal contacts on the active site of HIV-1 IN, or a tendency for structural polymorphism.

Detection of transforming ras proteins containing leucine at position 61 by a new mouse monoclonal antibody, ras(53-69)Leu61.

A monoclonal antibody (mAb) was prepared after immunization of mice with a peptide that corresponds to amino acids 53 to 69 of a transforming ras protein. The amino acid sequence in this region is conserved among all members of the ras protooncogene family in rodent, rabbit, and human cells. The peptide used for immunization differs from the normal sequence by a single residue; Leu replaces Gln at a site corresponding to amino acid 61. A bacterial expression vector was constructed to synthesize H-ras transforming protein that contains this change (rasLeu61). In immunoblotting experiments, the affinity purified mAb, ras(53-69)Leu61, reacts specifically with the purified, bacterially produced rasLeu61 protein and does not react with bacterially produced normal H-ras protein. In immunoblotting experiments with cell lysates, the mAb recognizes the transforming protein in NIH3T3 cells transformed by the c-rasHLeu61 oncogene but fails to react with normal H-ras protein in the same cells or cells which produce 100 times more normal protein than NIH3T3. The mAb immunoprecipitates [35S]methionine-labeled H- and N-rasLeu61 proteins from transformed NIH3T3 cells under conditions in which the cells produce basal levels of the transforming protein, equivalent to the low amount of the normal protein ordinarily present in nontransformed NIH3T3 cells. The antibody fails to immunoprecipitate normal H-ras protein, even when present at high levels, or N-ras protein containing Lys as amino acid 61. Affinity purified mAb ras(53-69)Leu61 also recognizes the transforming ras protein specifically in immunohistochemical staining of tissue culture cells, and this staining is abolished by preincubating the antibody with the corresponding peptide. Staining was not observed with control NIH3T3 cells or cells that produce 100 times more normal H-ras protein than NIH3T3. However, in thin sections of normal human or rabbit skin the antibody reacted strongly with an unknown antigen, in cells of the basal layer of the epidermis, that is neither normal nor transforming ras protein. This new immunological reagent should be useful for the selective identification of Leu61 containing H-, K-, and N-ras transforming proteins in in vitro studies and analyses using rodent, rabbit, or human tissue culture cells. Its utility for direct staining of tissues may be limited to situations in which the presence of transforming protein can be verified by another method such as immunoblotting after gel electrophoresis.

Correlation between H-ras p21TLeu61 protein content and tumorigenicity of NIH3T3 cells.

We have prepared a number of NIH3T3 clonal cell lines that contain an H-ras transforming gene with an A----T transversion at the 61st codon. The clonal lines contain 1 to 3 cell equivalents of the transforming oncogene and some lines look more morphologically transformed than others. Using Y13-238, a rat monoclonal antibody that recognizes H-ras p21 but not Ki- or N-ras in rodent cells, we found that the degree of morphological change is correlated with the relative amount of transforming protein in the selected clonal lines. Nude mice were injected with cells from lines containing different amounts of the transforming protein, ranging from approximately 1 to 10 times the level of normal H-ras protein present in NIH3T3 cells. Tumors arose in all mice that received cells containing the transforming protein. Their time of appearance (tumor latency) was correlated with the number of cells injected and the amount of transforming protein present in each clonal line; however, the subsequent rate of growth and ultimate size of the tumors were similar. Thus, it appears that the transforming protein has a significant effect on some early step in tumor development. Our results also show that relatively low amounts of transforming ras protein are sufficient to cause tumorigenicity in NIH3T3 cells and that higher amounts of the transforming protein cause proportionately faster responses.

Antisera to the variable region of ras oncogene proteins, and specific detection of H-ras expression in an experimental model of chemical carcinogenesis.

Antisera were prepared in mice, rats and rabbits by immunization with peptides corresponding to regions of highest variability, located near the C-termini of four ras proteins. Two of these, H-ras (171-189) and K-rasB (171-186), react uniquely with H-ras and K-rasB gene products in immunoblots and immunoprecipitation reactions. Affinity-purified rabbit H-ras (171-189) antibody detects H-ras p21 in tissue culture cells and in tissue sections. Epithelial cells in normal mouse skin and cells in papillomas and carcinomas, in a mouse model system of chemical carcinogenesis in which mutational activation of H-ras occurs with high frequency, express high levels of H-ras p21 protein. These results suggest an hypothesis to explain the mechanism and preferential activation of particular ras loci in certain neoplasia.

Molecular mechanism of retroviral DNA integration.

The integration of retroviral DNA appears to be obligatory for the efficient replication of retroviruses in their respective host cells. During a natural infection, integration takes place in a process that includes biochemically and temporally discrete steps. These are: (1) the removal of two nucleotides from the 3' ends of newly synthesized linear viral DNA in the host cell cytoplasm; (2) transport of the trimmed viral DNA to the nucleus within a viral protein/DNA complex; and (3) insertion of the viral DNA into host cell DNA via a concerted cleavage and ligation reaction. The cleavage of viral DNA and its subsequent joining to host DNA are catalyzed by the retroviral enzyme, integrase (IN). Elucidation of the mechanistic details of these catalytic activities of IN has relied heavily upon the use of relatively simple in vitro assays which recapitulate the in vivo reactions. These assays and the information derived from them should also facilitate the search for potential inhibitors of IN with the ultimate goal of providing a means to halt retroviral infections, such as that which causes the acquired immunodeficiency syndrome (AIDS), effectively.

High-resolution structure of the catalytic domain of avian sarcoma virus integrase.

Retroviral integrase (IN) functions to insert retroviral DNA into the host cell chromosome in a highly coordinated manner. IN catalyzes two biochemically separable reactions: processing of the viral DNA ends and joining of these ends to the host DNA. Previous studies suggested that these two reactions are chemically similar and are carried out by a single active site that is characterized by a highly conserved constellation of carboxylate residues, the D,D(35)E motif. We report here the crystal structure of the isolated catalytic domain of avian sarcoma virus (ASV) IN, solved using multiwavelength anomalous diffraction data for a selenomethionine derivative and refined at 1.7 A resolution. The protein is a crystallographic dimer with each monomer featuring a five-stranded mixed beta-sheet region surrounded by five alpha-helices. Based on the general fold and the arrangement of catalytic carboxylate residues, it is apparent that ASV IN is a member of a superfamily of proteins that also includes two types of nucleases, RuvC and RNase H. The general fold and the dimer interface are similar to those of the analogous domain of HIV-1 IN, whose crystal structure has been determined at 2.5 A resolution. However, the ASV IN structure is more complete in that all three critical carboxylic acids, Asp64, Asp121 and Glu157, are ordered. The ordered active site and the considerably higher resolution of the present structure are all important to an understanding of the mechanism of retroviral DNA integration, as well as for designing antiviral agents that may be effective against HIV.