Provirus of M7 baboon endogenous virus: nucleotide sequence of the gag-pol region

Generalizing RNA velocity to transient cell states through dynamical modeling

RNA velocity has opened up new ways of studying cellular differentiation in single-cell RNA-sequencing data. It describes the rate of gene expression change for an individual gene at a given time point based on the ratio of its spliced and unspliced messenger RNA (mRNA). However, errors in velocity estimates arise if the central assumptions of a common splicing rate and the observation of the full splicing dynamics with steady-state mRNA levels are violated. Here we present scVelo, a method that overcomes these limitations by solving the full transcriptional dynamics of splicing kinetics using a likelihood-based dynamical model. This generalizes RNA velocity to systems with transient cell states, which are common in development and in response to perturbations. We apply scVelo to disentangling subpopulation kinetics in neurogenesis and pancreatic endocrinogenesis. We infer gene-specific rates of transcription, splicing and degradation, recover each cell's position in the underlying differentiation processes and detect putative driver genes. scVelo will facilitate the study of lineage decisions and gene regulation.

Retrovirus-like particles released from the human breast cancer cell line T47-D display type B- and C-related endogenous retroviral sequences

The human mammary carcinoma cell line T47-D releases retrovirus-like particles of type B morphology in a steroid-dependent manner (I. Keydar, T. Ohno, R. Nayak, R. Sweet, F. Simoni, F. Weiss, S. Karby, R. Mesa-Tejada, and S. Spiegelman, Proc. Natl. Acad. Sci. USA 81:4188-4192, 1984). Furthermore, reverse transcriptase (RT) activity is found to be associated with particle preparations. Using a set of degenerate primers derived from a conserved region of retroviral pol genes, we repeatedly amplified three different retroviral sequences (MLN, FRD, and FTD) from purified T47-D particles in several RT-PCR experiments. Screening of a human genomic library and Southern blot analysis revealed that these sequences are of endogenous origin. ERV-MLN represents a multicopy family of human endogenous retroviral elements (HERVs) with two closely related copies and up to 20 more distantly related members. In contrast, ERV-FRD and ERV-FTD comprise only one copy and five to seven related elements per haploid human genome. DNA sequence analysis of the proviral pol region of ERV-MLN revealed an uninterrupted stretch of 241 amino acids that shows 65% identity with the RT of the type B-related HERV designated HERV-K10. ERV-FRD and ERV-FTD are defective type C-related HERVs. The pol gene of ERV-FRD displays a nucleotide homology of 54% to the gibbon ape leukemia virus, and the pol gene of ERV-FTD is about 67% homologous to members of the RTVL-I family of HERVs. Our results thus indicate that the retroviral particles released by the breast cancer cell line T47-D are probably generated by complementation of several endogenous proviruses and can package retroviral transcripts of different origins.

Genetic analysis of the major homology region of the Rous sarcoma virus Gag protein

The mature cores of all retroviruses contain a major structural protein known as the CA (capsid) protein. Although it appears to form a shell around the ribonucleoprotein complex that contains the viral RNA, its function in viral replication is largely unknown. Little sequence similarity exists between the CA proteins of different retroviruses, except for a region of about 20 amino acids termed the major homology region (MHR). To examine the role of the CA protein in particle assembly and release, mutants of Rous sarcoma virus were created in which segments of CA were deleted or single conserved residues in the MHR were altered. The ability of the deletion mutants to release particles at rates similar to the wild-type protein demonstrated that the CA domain of Gag is not an essential component of the minimal budding machinery. Certain point mutations in the MHR region did block assembly and release in certain cell types, presumably by perturbing the global structure of the Gag precursor. Another group of MHR substitutions produced noninfectious or poorly infectious particles that were normal in their content of gag and pol gene products and viral RNA. The mutants were capable of initiating reverse transcription in vitro; however, the association of CA protein with the core was compromised, as indicated by its sensitivity to extraction with nonionic detergent. Prominent blebs on the virion envelope also indicated a disturbance at the membrane. Finally, an anti-peptide serum directed against MHR was found to react with the uncleaved Gag protein but not with mature CA, suggesting that MHR undergoes a dynamic rearrangement upon liberation from the polyprotein. We conclude that the MHR is involved in the very late steps in maturation of the virion (i.e., ones that occur after budding is initiated) and is essential for proper function of the core upon entry into a new host cell.

Evolution and biological significance of human retroelements

Retroelements comprise a substantial portion of the human genome. Their large number and ubiquitous distribution has led scientists to speculate about their evolutionary origin and their biological functions. Human endogenous retroviruses and their retrotransposon relatives represent a reservoir of possibly pathogenic retroviral genes that may be activated spontaneously or by environmental conditions. They can act as insertion mutagens and activate or inactivate cellular genes, or may be involved in chromosome aberrations by recombination of related elements on different chromosomal locations. Retroviral gene products themselves may also be pathogenic and, for example, could be implicated in the development of tumors and autoimmune diseases. On the other hand, endogenous retroviral elements and nonviral retroposons are thought to have played an important role in shaping the genomes of vertebrates by intracellular transposition events and by generating hot spots of recombination. In the course of time, some of these elements have acquired cellular functions, such as, for instance, in the regulation of gene expression. Therefore, the role of human endogenous retroviruses and retroposons in biological processes is currently a subject of great interest.

Increased antiretroviral antibody reactivity in sera from a defined population of patients with systemic lupus erythematosus. Correlation with autoantibodies and clinical manifestations

OBJECTIVE

The implied role of retroviruses in the pathogenesis of murine systemic lupus erythematosus (SLE) led us to study antiretroviral antibodies in a population-based SLE cohort.

METHODS

Immunoassays using whole virus and synthetic peptides were performed on sera from 72 patients with SLE and 88 control subjects.

RESULTS

Reactions with whole baboon endogenous virus occurred more frequently in patients with SLE, and correlated with the presence of anti-RNP and anti-Sm. Some retroviral env and gag peptides, several of which were similar to U1 small nuclear RNP, reacted more strongly in patients with SLE, and their presence was correlated with discoid rash, hematologic disorder, and other symptoms.

CONCLUSION

These results provide circumstantial evidence for involvement of retroviruses in the pathogenesis of human SLE; further studies should be carried out using other techniques for measurement of retroviral expression.

Translational suppression in retroviral gene expression

This chapter summarizes the present state of knowledge concerning translational suppression in retroviruses. Other viruses, using similar mechanisms, are mentioned only briefly and tangentially. Retroviruses are a unique class of viruses that have been found in all classes of vertebrates but not in other organisms. Perhaps, their most distinctive properties are the flow of information from RNA to DNA early in the infectious process, and the subsequent integration of the viral DNA into the chromosomal DNA of the host cell. Retroviruses are the causative agents of acquired immunodeficiency syndrome (AIDS) and of a variety of neoplastic diseases in man and domestic animals. Elements with striking similarities to retroviruses, termed retrotransposons, occur in yeast and many other eukaryotes; elements sharing some characteristics with retroviruses have also recently been observed in prokaryotes. Because of the apparent relationship between retroviruses and retrotransposons, this chapter discusses of retrotransposons as well as retroviruses. Though all retroviruses utilize translational suppression in pol-protein synthesis, different groups of retroviruses use two completely distinct types of translational suppression. One of these is in-frame or readthrough suppression and the other is ribosomal frameshifting.

Adeno-associated viruses having nonsense mutations in the capsid genes: growth in mammalian cells containing an inducible amber suppressor

When an adeno-associated virus (AAV) genome contained in a recombinant plasmid is transfected into adenovirus-infected cells, infectious AAV particles are efficiently generated. We previously described the construction of a conditional lethal mutant of AAV having an amber termination codon inserted in the rep gene. This mutant was propagated on a monkey kidney cell line (SupD12) having an inducible amber suppressor tRNAser. We now describe the construction and propagation of two additional conditional lethal mutants of AAV having amber codons affecting all three capsid proteins (AAV Capam) or only the VP1 capsid protein (AAV VP1am). Suppression of the amber mutations in the capsid proteins was demonstrated directly by immunoblot analysis. The efficiency of amber suppression on the SupD12 cell was about 6 to 10% for AAV VP1am and 4 to 5% for AAV Capam. The reversion frequency of either mutant was apparently less than 10(-5). On nonsuppressing cells AAV VP1am exhibited an Lip (Inf) phenotype, whereas AAV Capam exhibited a Cap phenotype.

RNA pseudoknots: translational frameshifting and readthrough on viral RNAs

Ribosomal frameshifting on retroviral RNAs has been proposed to be mediated by slippage of two adjacent tRNAs into the -1 direction at a specific heptanucleotide sequence. Here we report a computer-aided analysis of the structure around the established or putative frameshift sites in a number of retroviral, coronaviral, toroviral, and luteoviral RNAs and two dsRNA yeast viruses. In almost all cases a stable hairpin was predicted four to nine nucleotides downstream of the shifty heptanucleotide. More than half of the resulting hairpin loops give rise to potential pseudoknotting with sequences downstream of this hairpin. Especially in the case of the shifty heptanucleotides U UUA AAC and G GGA AAC, stable downstream pseudoknots are present. Indications were also found for the presence of pseudoknots downstream of amber stop condons at readthrough sites in some retroviral RNAs.

A retroviral Cys-Xaa2-Cys-Xaa4-His-Xaa4-Cys peptide binds metal ions: spectroscopic studies and a proposed three-dimensional structure

Retroviral gag gene-encoded core nucleic acid binding proteins contain either one or two sequences of the form Cys-Xaa2-Cys-Xaa4-His-Xaa4-Cys. Previously, one of us has proposed that these sequences form metal-binding domains in analogy with the "zinc finger" domains first observed in transcription factor IIIA. We report that an 18-amino acid peptide derived from the core nucleic acid binding protein from Rauscher murine leukemia virus binds metal ions such as Co2+ and Zn2+. The absorption spectrum of the peptide-Co2+ complex is highly suggestive of tetrahedral coordination involving three cysteinates and one histidine. Titration experiments indicate that the dissociation constant for the peptide-Co2+ complex is 1.0 microM and that Zn2+ binds more tightly than Co2+. A detailed three-dimensional structure for this domain based on conserved substructures in other crystallographically characterized metalloproteins and on a detailed analysis of the Cys-Xaa2-Cys-Xaa4-His-Xaa4-Cys sequences from retroviruses and other related sources is proposed.

Retroviral gag gene amber codon suppression is caused by an intrinsic cis-acting component of the viral mRNA

In some type C retroviruses, translation of the pol gene appears to require translational suppression of the proximal gag amber codon. To identify the region of the viral nucleic acid responsible for synthesis of the pol gene products, a 300-base-pair DNA fragment containing the stop codon from a type C murine virus (AK virus) was inserted into the Escherichia coli lacZ gene such that the translational reading frame was maintained. Introduction of the resulting fusion gene into cells resulted in the suppression of the viral stop codon. As measured by beta-galactosidase production, suppression occurred at a frequency of approximately 10%. Suppression could occur in at least several vertebrate cell types and was not augmented by virus replication or the expression of viral gene products. This indicates that gag amber codon suppression does not require augmented levels of suppressor tRNA species.

Human endogenous retroviruslike genome with type C pol sequences and gag sequences related to human T-cell lymphotropic viruses

We have cloned several prototypic members of the family of human endogenous retroviruslike elements having a histidine tRNA primer-binding site (RTVL-H) and have determined the nucleotide sequence of one of these clones (RTVL-H2). The RTVL-H2 sequence is 5,813 nucleotides long, with long terminal repeats of 450 nucleotides. Although this particular sequence contains no long open reading frames, computer searches have revealed several segments of amino acid homology with known retroviral gene products. In the gag region of RTVL-H2, there is a segment with significant homology to a region of the gag protein p30 of type C baboon endogenous virus. In the pol region of RTVL-H2, three segments similar to the Moloney leukemia virus (MLV) pol polyprotein were detected. These correspond to parts of the protease, reverse transcriptase, and endonuclease domains of the MLV pol gene. Interestingly, the last two pol domains are equidistant in RTVL-H2 and the type C murine retroviruslike DNA sequence (MuRRS), both having deletions of equal sizes relative to the MLV pol gene. One other segment similar to a retroviral gene product was identified in the RTVL-H2 gag region. This segment has 55 to 60% amino acid homology to a 50-amino-acid region of the gag nucleic acid-binding proteins encoded by human T-cell lymphotropic viruses types I and II and bovine leukemia virus. Thus, the RTVL-H2 genome harbors sequences related to evolutionarily distant retroviruses.

Capsid protein VP4 of poliovirus is N-myristoylated

Poliovirus was labeled in vivo with [3H]myristic acid. Analysis of the capsid polypeptides revealed that the [3H]myristic acid residues copurified with VP4, the smallest and internal capsid protein of the virion. Evidence is presented showing unambiguously that the N-terminal glycine residue of VP4 is N-myristoylated. A previous analysis of the tryptic peptides of VP4 [Dorner, A. J., Dorner, L. F., Larsen, G. R., Wimmer, E. & Anderson, C. W. (1982) J. Virol. 42, 1017-1028] had shown that the N-terminal blocking group exists on all VP4 molecules as well as on VP0 and P1, two precursor polypeptides to VP4 in poliovirus. The possible function of the myristic acid residue in VP4 and in its precursor in poliovirus proliferation is discussed.

A structural model for the retroviral proteases

In many retroviruses the 5' end of the pol gene codes for a protease vital for the processing of the gag polyprotein into the separate core proteins. In some viruses this protease is encoded at the 3' end of the gag gene, or between the gag and pol genes in a different reading frame to either. A sequence, Asp-Thr-Gly, which is conserved in retroviral proteases is also conserved in the active sites of aspartic proteases, an observation which has led to the suggestion that the retroviral proteases could belong to this family. We have examined the sequences of the aspartic and retroviral protease families, using pattern-recognition, structure prediction and molecular modelling techniques, and conclude that the viral protease sequences probably correspond to a single domain of an aspartic protease and may function in a dimeric form. We have constructed a model of the pol-protease of human immunodeficiency virus 1 (HIV-1) to test this hypothesis.

Common evolutionary origin of hepatitis B virus and retroviruses

Hepatitis B virus (HBV), although classified as a double-stranded DNA virus, has been shown recently to replicate by reverse transcription of an RNA intermediate. Also, the putative viral polymerase has been found to share amino acid homology with reverse transcriptase of retroviruses. Using computer-assisted DNA and protein sequence analyses, we examined the genomes of 13 hepadnavirus isolates (nine human, two duck, one woodchuck, and one ground squirrel) and found that other conserved regions of the hepadnavirus genome share homology to corresponding regions of the genomes of type C retroviruses and retrovirus-like endogenous human DNA elements. Specifically, the most highly conserved sequence of the HBV genome, positioned at or near the initiation site for first-strand HBV DNA synthesis, is homologous over 67 nucleotides to the U5 region, a comparable region in retrovirus long terminal repeats. Within a highly conserved (i.e., 90%) 16-nucleotide sequence a heptanucleotide sequence CCTTGGG is 97% homologous between 27 virus isolates. Also, we found that the highly conserved HBV core, or nucleocapsid, protein shares 41% homology over 98 amino acids with the carboxyl-terminal region of the p30 gag nucleocapsid protein of type C retroviruses. In both cases, as with the previously reported polymerase homology, HBV is most homologous to the murine leukemia/sarcoma retroviruses. Further analysis revealed additional similarities between hepadnavirus and retroviral genomes. Taken together, our results suggest that HBV and retroviruses have a common evolutionary origin, with HBV arising through a process of deletion from a retrovirus, or retrovirus-like, progenitor.

Amino acid sequence homology in gag region of reverse transcribing elements and the coat protein gene of cauliflower mosaic virus

A nucleic acid binding protein (NBP) derived from the gag gene of retroviruses that is thought to interact with genomic RNA in virion cores, contains a highly conserved arrangement of cysteine residues. A search of available nucleic acid and protein sequences has revealed that the motif CysX2CysX4HisX4Cys (NBPcys) is invarient in all replication competent retroviruses, a Syrian hamster intracisternal A-particle gene, the Drosophila retrotransposon copia and in cauliflower mosaic virus (CaMV). In each case, NBPcys is located in that part of the 'gag-pol' region just preceding a conserved protease amino acid sequence. This is of special significance for CaMV as NBPcys is in the coat protein gene (ORF IV) upstream of the putative reverse transcriptase gene (ORF V) and demonstrates that the gag-pol arrangement of reverse transcribing elements is preserved in CaMV. Moreover, CaMV differs from all other known NBPcys-containing elements in that it packages a DNA genome in virions.

Purification and N-terminal amino acid sequence comparisons of structural proteins from retrovirus-D/Washington and Mason-Pfizer monkey virus

A new D-type retrovirus originally designated SAIDS-D/Washington and here referred to as retrovirus-D/Washington (R-D/W) was recently isolated at the University of Washington Primate Center, Seattle, Wash., from a rhesus monkey with an acquired immunodeficiency syndrome and retroperitoneal fibromatosis. To better establish the relationship of this new D-type virus to the prototype D-type virus, Mason-Pfizer monkey virus (MPMV), we have purified and compared six structural proteins from each virus. The proteins purified from each D-type retrovirus include p4, p10, p12, p14, p27, and a phosphoprotein designated pp18 for MPMV and pp20 for R-D/W. Amino acid analysis and N-terminal amino acid sequence analysis show that the p4, p12, p14, and p27 proteins of R-D/W are distinct from the homologous proteins of MPMV but that these proteins from the two different viruses share a high degree of amino acid sequence homology. The p10 proteins from the two viruses have similar amino acid compositions, and both are blocked to N-terminal Edman degradation. The phosphoproteins from the two viruses each contain phosphoserine but are different from each other in amino acid composition, molecular weight, and N-terminal amino acid sequence. The data thus show that each of the R-D/W proteins examined is distinguishable from its MPMV homolog and that a major difference between these two D-type retroviruses is found in the viral phosphoproteins. The N-terminal amino acid sequences of D-type retroviral proteins were used to search for sequence homologies between D-type and other retroviral amino acid sequences. An unexpected amino acid sequence homology was found between R-D/W pp20 (a gag protein) and a 28-residue segment of the env precursor polyprotein of Rous sarcoma virus. The N-terminal amino acid sequences of the D-type major gag protein (p27) and the nucleic acid-binding protein (p14) show only limited amino acid sequence homology to functionally homologous proteins of C-type retroviruses.

Maturation of murine leukemia virus env proteins in the absence of other viral proteins

A mutant of Akv which produces env but no detectable gag or pol products (A. Rein, D. R. Lowy, B. I. Gerwin, S. K. Ruscetti, and R. H. Bassin, J. Virol. 41, 626-634 (1982] was examined for maturation of env gene protein products. In comparison with wild-type Akv, the mutant AK 71 synthesizes gPr85env and produces gp70 and Prp15E in normal amounts and with normal kinetics. Cell surface gp70 was found alike in the mutant and wild type. However, cleavage of Pr15E to p15E did not occur in the mutant. This final cleavage step of AK 71 Prp15E could be made to occur by superinfecting cells containing the mutant with baboon endogenous virus. Thus, unlike earlier steps, this final step in maturation of the env gene product appears to require gag or pol gene products. It is proposed that the virus-encoded protease is required for this last step.

Influence of base-pairing in the leader region on in vitro translation of Rous sarcoma virus RNA

The capacity of the leader region of Rous sarcoma virus (RSV) RNA to act as a regulator of viral protein synthesis was tested in vitro. When DNA/RNA hybrids of sufficient length (greater than 90-100 nucleotides) are created within the leader, synthesis of Pr76gag is inhibited. The inhibition is dependent upon the length of the hybrid rather than its position with the exception that encumberance of the 5'-terminal 33 nucleotides does block translation. These findings demonstrate that physical alteration of the non-coding leader structure directly affects downstream initiation of protein synthesis. It is thus likely that biochemical or physiologic changes in vivo which alter the structure of the leader may affect regulation of viral protein synthesis.

The gag and pol genes of bovine leukemia virus: nucleotide sequence and analysis

The DNA sequence of the gag and pol regions of a provirus cloned from a bovine tumor is presented. In order to confirm these results the sequence of portions of a second clone, derived from a virus-producing cell line, was also determined. The gag gene was found to consist of 1179 nucleotides, which probably encode only three proteins: an N-terminal protein of 109 amino acids, a major core protein (p24) of 215 amino acids, and a nucleic acid binding protein (p12) of 69 residues. An open reading frame, whose translated product showed clear homology to the avian and murine proteases, was found beginning immediately upstream of the 3' end of gag. Following this protease region, a third long open reading frame, encoding 852 amino acids, showed clear homology to both avian and murine pol genes. The mechanism of translation of the protease and pol gene products cannot be predicted with certainty. Like Moloney murine leukemia virus (M-MuLV), BLV has a termination signal at the 3' end of gag, but unlike M-MuLV the protease is in a different reading frame. Like Rous sarcoma virus (RSV), BLV has a termination signal at the 3' end of the protease region and the reverse transcriptase is in a different (i.e., the third) reading frame. Possible translation mechanisms are discussed. Finally, the BLV gag and pol gene products are highly related to those of the human T-cell leukemia virus (HTLV); relatedness varied from 37% amino acid identities within the N terminal gag protein to 54% within the nucleic acid binding protein. Highly significant homology with both murine and avian type-C proteins was found within p24, p12, and the putative protease, reverse transcriptase, and endonuclease. Based on this homology, the BLV-HTLV family of viruses appears about equally distantly related to murine and avian type-C viruses.

Murine leukemia virus protease is encoded by the gag-pol gene and is synthesized through suppression of an amber termination codon

We have purified from Moloney murine leukemia virus (Mo-MuLV) a protease that has the capacity of accurately cleaving the polyprotein precursor Pr65gag into the mature viral structural proteins. Both the NH2- and COOH-terminal amino acid sequences have been determined and aligned with the amino acid sequence deduced from the DNA sequence of Mo-MuLV by other workers. The results show that: (i) the protease is located at the 5' end of the pol gene, and the first four amino acids are overlapped with the 3' end of the gag gene; (ii) the fifth amino acid residue is glutamine, which is inserted by suppression of the UAG termination codon at the gag-pol junction; and (iii) the protease is composed of 125 amino acids with calculated Mr = 13,315, and the COOH terminus of the protease is adjacent to the NH2 terminus of reverse transcriptase. The map order of the gag-pol gene is proposed to be 5'-p15-p12-p30-p10-protease-reverse transcriptase-endonuclease-3'.

Nucleotide sequence and expression of an AIDS-associated retrovirus (ARV-2)

The nucleotide sequence of molecular clones of DNA from a retrovirus, ARV-2, associated with the acquired immune deficiency syndrome (AIDS) was determined. Proviral DNA of ARV-2 (9737 base pairs) has long terminal repeat structures (636 base pairs) and long open reading frames encoding gag (506 codons), pol (1003 codons), and env (863 codons) genes. Two additional open reading frames were identified. Significant amino acid homology with several other retroviruses was noted in the predicted product of gag and pol, but ARV-2 was as closely related to murine and avian retroviruses as it was to human T-cell leukemia viruses (HTLV-I and HTLV-II). By means of an SV-40 vector in transfected simian cells, the cloned gag and env genes of ARV-2 were shown to express viral proteins.

Purification and chemical and immunological characterization of avian reticuloendotheliosis virus gag-gene-encoded structural proteins

Five gag-gene-encoded structural proteins, designated p12, pp18, pp20, p30, and p10 were purified from replication-competent avian reticuloendotheliosis-associated virus (REV-A) by high-performance liquid chromatography complemented with chloroform-methanol extraction and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Based on amino acid composition and NH2- and COOH-terminal sequence analysis p12, pp18, p30, and p10 are distinct from one another, whereas pp20 is likely identical to pp18 in primary structure. The p12 was resistant to Edman degradation and was found to be myristylated at the NH2-terminal amino group. Sequence comparisons among the retrovirus family show that pp18/pp20 and p10 are, respectively, homologs of phospho-proteins and nucleic acid-binding proteins. A comparison of terminal sequences with the nucleotide sequence of spleen necrosis virus (SNV) revealed that the gag genes of SNV and REV-A are highly conserved; together with the identification of REV-A gag-precursor polyprotein, Pr60gag in immunoprecipitates of radiolabeled cell lysates, this comparison also led to the establishment of the organization of Pr60gag, viz., NH2-p12-pp18-p30-p10-OH. Sequence comparisons show that REV-A/SNV is related to mammalian type C viruses: the pp18-p30 region is most homologous to the macaque/colobus group and least to simian sarcoma virus (SSV), whereas both the 5'- and 3'-gag regions (i.e., p12 and p10) are clostest to SSV. Immunological studies using monospecific antisera and Western-blot analysis showed that antigenic determinants of REV-A p30 are conserved in most of mammalian type C and type D viruses, but those of REV-A p12 are shared only with simian sarcoma-associated virus (SSAV) and endogenous viruses of macaques.

ERV3, a full-length human endogenous provirus: chromosomal localization and evolutionary relationships

A full-length human endogenous provirus termed ERV3 was isolated from a human fetal recombinant DNA library by low stringency hybridization with two probes: baboon endogenous virus LTR; and a pol-env subclone from the endogenous chimpanzee provirus, CH2. DNA sequencing within the clone and comparisons with other retroviruses revealed that ERV3 contains gag and pol gene sequences that are significantly related to those of mammalian type C retroviruses and previously described human endogenous proviruses. The ERV3 genome was determined to reside at a single locus on human chromosome 7 using a panel of rodent X human somatic cell hybrids.

Human placental syncytiotrophoblastic Mr 75,000 polypeptide defined by antibodies to a synthetic peptide based on a cloned human endogenous retroviral DNA sequence

Antibodies to a synthetic undecapeptide (NH2-Cys-Glu-Asn-Pro-Ser-Gln-Phe-Tyr-Glu-Arg-Leu-COOH), the sequence (except cysteine) of which was deduced from a previously reported cloned human retroviral gag-gene-related DNA sequence erv-1, were raised in rabbits. In immunohistochemical staining these antibodies reacted with normal human first-trimester placentas and with blighted ova and benign and malignant trophoblastic tumors (hydatidiform and destructive moles, choriocarcinomas) but not with any other normal embryonic or adult tissues tested. In all tissues the reactivity was mainly confined to cells with trophoblastic morphology. In immunoblotting the antibody detected an Mr 75,000 polypeptide in syncytiotrophoblasts isolated from first-trimester placentas and in three different lines of cultured choriocarcinoma cells. The undecapeptide blocked the reactivity of the antibody.

Myristylation of gag-onc fusion proteins in mammalian transforming retroviruses

Four cell lines producing transforming proteins encoded by three mammalian oncogenes (fes, abl, and ras) were investigated for incorporation of [3H]myristate into gag-onc fusion proteins. Using 5-min pulse-labelings, fusion proteins of Abelson murine leukemia virus, Gardner-Arnstein strain of feline sarcoma virus (FeSV), and Snyder-Theilen strain of FeSV were shown to be myristylated. In a 4-hr pulse, p29gag-ras of rat sarcoma virus (RaSV) was also shown to incorporate radiolabel. The fatty acid was recovered from this labeled protein by acid hydrolysis, and identified by reverse-phase thin-layer chromatography to be [3H]myristic acid. The results indicate that substitution of viral gag sequences by cellular oncogene sequences does not abolish their ability to become post-translationally modified by this long chain fatty acid (A. Schultz and S. Oroszlan, J. Virol. 46, 355-361). It is assumed that in the fusion proteins the myristyl moiety is linked through an amide linkage to the amino-terminal glycine as previously found for several retroviral gag precursor polyproteins (L. E. Henderson, H. C. Krutzsch, and S. Oroszlan, Proc. Natl. Acad. Sci. USA 80, 339-343). The possible role of myristylation of transforming proteins is discussed.

Nucleotide sequences of the retroviral long terminal repeats and their adjacent regions

The nucleotide sequences of the LTRs and their adjacent regions from 19 type C and one type B retrovirus were compared. Salient features are: (a) The R regions in the genomes of most of the type C retroviruses begin with GC and end with CA. (b) The mammalian type C retroviruses have a polyadenylation signal "AATAAA" in the R region, and most have a "CAT" box and a "TATA" box in the U3 region. (c) The avian type C retroviruses have an AATAAA sequence, and some also have "CAT-like" and "TATA-like" boxes, in the U3 region. (d) As with many transposable elements, the IR regions of the proviruses begin with TG and end with CA, and the DR sequences in the host genomes flanking the proviruses are different from one another. Although SNV is an avian retrovirus, the nucleotide sequences in the R, U5, TBS, and PU region are more similar to the mammalian type C than to the avian type C retroviruses.

Complete amino acid sequence of the basic nucleic acid binding protein of feline leukemia virus

The complete amino acid sequence of the nucleic acid binding protein p10 of the Rickard strain of feline leukemia virus (FeLV) has been determined. Fragments obtained by enzymatic digestion were purified by reverse-phase liquid chromatography and subjected to semiautomated Edman degradation. FeLV p10 is a basic polypeptide composed of 57 amino acids with Mr = 6604. The structure of p10 is compared to the structures of other retroviral nucleic acid binding proteins, and an analysis of a highly conserved region, the putative binding domain, is presented.