Characterization of Moloney murine leukemia virus mutants with single-amino-acid substitutions in the Cys-His box of the nucleocapsid protein

An analytical study of the dimerization of in vitro generated RNA of Moloney murine leukemia virus MoMuLV

The genome of Moloney murine leukemia virus(MoMuLV) is composed of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Recently it was shown that in vitro generated MuLV RNA formed dimeric molecules and that dimerization sequences are located within the Psi encapsidation domain between positions 215 and 420. Conditions for the spontaneous dimerization of a MuLV RNA fragment encompassing the Psi domain have been investigated. The rate of spontaneous MuLV RNA dimer formation is dependent upon RNA, NaCl and MgCl2 concentrations as well as temperature. Thermal denaturation of in vitro generated dimer RNA of 350 nt, from positions 215 to 565, gave a Tm of about 58 degrees C in 100 mM NaCl. This Tm value is very close to that found for RNA corresponding to the 5' 755 nt and to the genomic 70 S RNA isolated from virions. According to thrermodynamic parameters derived from denaturation curves of MuLV dimer RNA generated in vitro, the dimer linkage structure probably involves short sequences.

Role of the gag polyprotein precursor in packaging and maturation of Rous sarcoma virus genomic RNA

Rous sarcoma virus nucleocapsid protein (NC) has been shown by site-directed mutagenesis to be involved in viral RNA packaging and in the subsequent maturation of genomic RNA in the progeny viral particles. To investigate whether NC exerts these activities as a free protein or as a domain of the polyprotein precursor Pr76gag, we have constructed several mutants unable to process Pr76gag and analyzed their properties in a transient-transfection assay of chicken embryo fibroblasts, the natural host of Rous sarcoma virus. A point mutation in the protease (PR) active site completely prevents Pr76gag processing. The full-length Pr76gag polyprotein is still able to package viral RNA, but cannot mature it. A shorter gag precursor polyprotein lacking the C-terminal PR domain, but retaining that of the NC protein, is however, unable even to package viral RNA. This indicates that the NC protein can participate in packaging viral RNA only as part of a full-length Pr76gag and that the PR domain is, indirectly or directly, also involved in RNA packaging. These results also demonstrate that processing of Pr76gag is necessary for viral RNA dimerization.

BIK1, a protein required for microtubule function during mating and mitosis in Saccharomyces cerevisiae, colocalizes with tubulin

BIK1 function is required for nuclear fusion, chromosome disjunction, and nuclear segregation during mitosis. The BIK1 protein colocalizes with tubulin to the spindle pole body and mitotic spindle. Synthetic lethality observed in double mutant strains containing a mutation in the BIK1 gene and in the gene for alpha- or beta-tubulin is consistent with a physical interaction between BIK1 and tubulin. Furthermore, over- or underexpression of BIK1 causes aberrant microtubule assembly and function, bik1 null mutants are viable but contain very short or undetectable cytoplasmic microtubules. Spindle formation often occurs strictly within the mother cell, probably accounting for the many multinucleate and anucleate bik1 cells. Elevated levels of chromosome loss in bik1 cells are indicative of defective spindle function. Nuclear fusion is blocked in bik1 x bik1 zygotes, which have truncated cytoplasmic microtubules. Cells overexpressing BIK1 initially have abnormally short or nonexistent spindle microtubules and long cytoplasmic microtubules. Subsequently, cells lose all microtubule structures, coincident with the arrest of division. Based on these results, we propose that BIK1 is required stoichiometrically for the formation or stabilization of microtubules during mitosis and for spindle pole body fusion during conjugation.

The complete nucleotide sequence of a pathogenic molecular clone of simian immunodeficiency virus

The complete nucleotide sequence of an infectious clone of simian immunodeficiency virus of macaques, SIVmac239, has been determined. Virus produced from this molecular clone causes AIDS in rhesus monkeys in a time frame suitable for laboratory investigation. The proviral genome including both long terminal repeats is 10,279 base pairs in length and contains open reading frames for gag, pol, vif, vpr, vpx, tat, rev, and env. The nef gene contains an in-frame premature stop after the 92nd codon. At the nucleotide level, SIVmac239 is closely related to SIVmac251 (98%) and SIVmac142 (96%). It will not be possible to test which features of the viral sequence are critical molecular determinants for the pathogenesis of AIDS.

Rearrangements in unintegrated retroviral DNA are complex and are the result of multiple genetic determinants

We used a replication-competent retrovirus shuttle vector based on a DNA clone of the Schmidt-Ruppin A strain of Rous sarcoma virus to characterize rearrangements in circular viral DNA. In this system, circular molecules of viral DNA present after acute infection of cultured cells were cloned as plasmids directly into bacteria. The use of a replication-competent shuttle vector permitted convenient isolation of a large number of viral DNA clones; in this study, over 1,000 clones were analyzed. The circular DNA molecules could be placed into a limited number of categories. Approximately one-third of the rescued molecules had deletions in which one boundary was very near the edge of a long terminal repeat (LTR) unit. Subtle differences in the patterns of deletions in circular DNAs with one versus two copies of the LTR sequence were observed, and differences between deletions emanating from the right and left boundaries of the LTR were seen. A virus with a missense mutation in the region of the pol gene responsible for integration and exhibiting a temperature sensitivity phenotype for replication had a marked decrease in the number of rescued molecules with LTR-associated deletions when infection was performed at the nonpermissive temperature. This result suggests that determinants in the pol gene, possibly in the integration protein, play a role in the generation of LTR-associated deletions. Sequences in a second region of the genome, probably within the viral gag gene, were also found to affect the types of circular viral DNA molecules present after infection. Sequences in this region from different strains of avian sarcoma-leukosis viruses influenced the fraction of circular molecules with LTR-associated deletions, as well as the relative proportion of circular molecules with either one or two copies of the LTR. Thus, the profile of rearrangements in unintegrated viral DNA is complex and dependent upon the nature of sequences in the gag and pol regions.

Point mutations in the proximal Cys-His box of Rous sarcoma virus nucleocapsid protein

To extend our previous studies of the function of the Cys-His box of Rous sarcoma virus NC protein, we have constructed a series of point mutations of the conserved or nonconserved amino acids of the proximal Cys-His box and a one-amino-acid deletion. All mutants were characterized for production of viral proteins and particles, for packaging and maturation of viral RNA, for reverse transcriptase activity, and for infectivity. Our results indicated the following. (i) Mutations affecting the strictly conserved amino acids cysteine 21, cysteine 24, and histidine 29 were lethal; only the mutant His-29----Pro was still able to package viral RNA, most of it in an immature form. (ii) Mutation of the highly conserved glycine 28 to valine reduced viral RNA packaging by 90% and infectivity 30-fold, whereas mutant Gly-28----Ala was fully infectious. This suggests a steric hindrance limit at this position. (iii) Shortening the distance between cysteine 24 and histidine 29 by deleting one amino acid abolished the maturation of viral RNA and yielded noninfectious particles. (iv) Substitution of tyrosine 22 by serine lowered viral RNA packaging efficiency and yielded particles that were 400-fold less infectious; double mutant Tyr-22Thr-23----SerSer had the same infectivity as Tyr-22----Ser, whereas mutant Thr-23----Ser was fully infectious. (v) Changing glutamine 33 to a charged glutamate residue did not affect virus infectivity. Similarities and differences between our avian mutants and those in murine retroviruses are discussed.

Properties of avian retrovirus particles defective in viral protease

The structural and enzymatic components of retroviral cores are formed by proteolytic cleavage of precursor polypeptides, mediated by the viral protease (PR). We constructed an active-site mutation, D37I, in the PR of avian leukosis virus. The D37I mutation was introduced into an infectious DNA clone, and quail cell lines expressing the mutant virus were established. These cell lines produce normal amounts of virus particles, the major internal protein components of which are the uncleaved gag and gag-pol precursors. As in other retroviral systems, the protease-defective virions are noninfectious and retain the "immature" type A morphology as determined by thin-section transmission electron microscopy. The virion cores are stable at nonionic detergent concentrations that completely disrupt wild-type cores. Digestion of mutant virions with exogenous PR in the presence of detergent leads to complete and correct cleavage of the gag precursor but incomplete cleavage of the gag-pol precursor. The protease-defective virions encapsidate normal amounts of genomic RNA and tRNA(Trp) that is properly annealed to the primer-binding site, but some of the genomic RNA remains monomeric. Results from UV cross-linking experiments show that the gag polyprotein of mutant virions interacts with viral RNA and that this interaction occurs through the nucleocapsid (NC) domain. However, within mutant virions the interaction of the NC domain with RNA differs from that of mature NC with RNA in wild-type virions. Reverse transcriptase (RT) activity associated with mutant virions is diminished but still detectable. Digestion of the virions with PR leads to a fivefold increase in activity, but this PR-mediated activation of RT is incomplete. Since in vitro cleavage of the gag-pol precursor is also incomplete, we hypothesize that amino acid sequences N terminal to the reverse transcriptase domain inhibit RT activity.

Retroviral nucleocapsid protein-metal ion interactions: folding and sequence variants

Retroviral nucleocapsid proteins contain one or two proposed metal-binding sequences of the form Cys-Xaa2-Cys-Xaa4-His-Xaa4-Cys. Previously, we reported that an 18-amino acid peptide derived from the nucleocapsid protein of Rauscher murine leukemia virus (RMLV) binds metals such as Co2+ and Zn2+. We have now synthesized the entire nucleocapsid protein from RMLV. We report here that the protein also binds Co2+ and Zn2+ and does so with a higher affinity than does the peptide. Limited proteolysis and circular dichroism studies reveal that metal binding induces folding of the metal-binding domain and, perhaps, the regions adjacent to it but the remainder of the protein remains in a relatively unstructured state. In addition, we have synthesized sequence variants of the metal-binding domain that correspond to viral mutations reported in the literature. In many cases, the metal-binding properties of these peptides correlate with the observed biological activity, providing further evidence for the importance of metal binding to nucleocapsid function.

Structure and assembly of turnip crinkle virus. VI. Identification of coat protein binding sites on the RNA

Structural studies of turnip crinkle virus have been extended to include the identification of high-affinity coat protein binding sites on the RNA genome. Virus was dissociated at elevated pH and ionic strength, and a ribonucleoprotein complex (rp-complex) was isolated by chromatography on Sephacryl S-200. Genomic RNA fragments in the rp-complex, resistant to RNase A and RNase T1 digestion and associated with tightly bound coat protein subunits, were isolated using coat-protein-specific antibodies. The identity of the protected fragments was determined by direct RNA sequencing. These approaches allowed us to study the specific RNA-protein interactions in the rp-complex obtained from dissociated virus particles. The location of one protected fragment downstream from the amber terminator codon in the first and largest of the three viral open reading frames suggests that the coat protein may play a role in the regulation of the expression of the polymerase gene. We have also identified an additional cluster of T1-protected fragments in the region of the coat protein gene that may represent further high-affinity sites involved in assembly recognition.

Noninfectious human immunodeficiency virus type 1 mutants deficient in genomic RNA

All retroviruses contain, in the nucleocapsid domain of the Gag protein, one or two copies of the sequence Cys-X2-Cys-X4-His-X4-Cys. We have generated a series of mutants in the two copies of this motif present in human immunodeficiency virus type 1. These mutants encoded virus particles that were apparently composed of the normal complement of viral proteins but contained only 2 to 20% of the normal level of genomic RNA. No infectivity could be detected in the mutant particles, while 10(5) infectious U were present in an equivalent amount of wild-type particles. Thus, the mutants have another defect in addition to the inefficiency with which they encapsidate genomic RNA. Our results show that both copies of the motif are required for normal RNA packaging and for infectivity. Mutants of this type may have important applications, including nonhazardous materials for research, immunogens in vaccine and immunotherapy studies, and diagnostic reagents.

Spleen necrosis virus gag polyprotein is necessary for particle assembly and release but not for proteolytic processing

The nature of spleen necrosis virus pol gene expression and the role of gag and gag-pol polyproteins in virion assembly was investigated. The DNA sequence of the gag-pol junction revealed that the two genes occupy the same open reading frame but are separated by an in-frame amber stop codon. Biochemical analysis of gag-pol translational readthrough in vitro and in Escherichia coli suggests that, in a manner similar to that in other mammalian type C retroviruses, amber stop codon suppression is required for pol gene expression. Removal of the gag stop codon had little or no effect on synthesis or cleavage of the polyprotein but interrupted particle assembly. This block could be overcome by complementation with wild-type gag protein.

Mutations of RNA and protein sequences involved in human immunodeficiency virus type 1 packaging result in production of noninfectious virus

To identify RNA and protein sequences involved in packaging of human immunodeficiency virus type 1 (HIV-1), various mutations were introduced into the viral genome. Portions of the human immunodeficiency virus type 1 genome between the first splice donor site and the gag initiation codon were deleted to investigate the RNA packaging site (psi). Point mutations that alter cysteine residues in one or both zinc finger motifs of p7, a cleavage product of the gag precursor, were created to study the role of the gag zinc fingers in packaging. The psi site mutants and the gag mutants exhibited similar phenotypes. Cells transfected with the mutant genomes, while expressing normal levels of human immunodeficiency virus type 1 RNA and proteins, produced viral particles that were normal in protein content but lacked detectable viral RNA. These mutant virions were unable to productively infect cells. The combination of human immunodeficiency virus type 1 packaging mutations should minimize fortuitous assembly of infectious virus and may provide a means to produce noninfectious particles for candidate vaccines.

RNA-binding properties of the matrix protein (p19gag) of avian sarcoma and leukemia viruses

We have reinvestigated the ability of the matrix protein (MA) (p19gag) of avian sarcoma and leukemia viruses to interact with RNA. Previous reports claimed on the one hand that MA can bind tightly and with a high degree of specificity to avian sarcoma and leukemia virus RNA in vitro and on the other that it cannot bind to RNA at all. We found that MA purified by any of several methods does bind to RNA, as measured by its ability to cause retention of radioactive RNA on nitrocellulose membranes in a filtration assay. However, this interaction is weak and lacks specificity. The interaction of MA with RNA was barely detectable by classical sedimentation analysis, and from this observation we estimate that the intrinsic MA-RNA association constant is ca. 10(3) M-1, at least 3 orders of magnitude smaller than the constant describing the interaction of the viral nucleocapsid protein (NC) (p12gag) with RNA, ca. 10(6) M-1. Separately purified phosphorylated and nonphosphorylated MA species bound RNA equally. We also found that MA can bind to DNA with an affinity similar to that for RNA. The large quantitative discrepancy between our results and earlier published reports can be traced in part to methods of data analysis.

cis elements and trans-acting factors involved in dimer formation of murine leukemia virus RNA

The genetic material of all retroviruses examined so far consists of two identical RNA molecules joined at their 5' ends by the dimer linkage structure (DLS). Since the precise location of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analyzed the dimerization process of Moloney murine leukemia virus (MoMuLV) genomic RNA. For this purpose we derived an in vitro model for RNA dimerization. By using this model, murine leukemia virus RNA was shown to form dimeric molecules. Deletion mutagenesis in the 620-nucleotide leader of MoMuLV RNA showed that the dimer promoting sequences are located within the encapsidation element Psi between positions 215 and 420. Furthermore, hybridization assays in which DNA oligomers were used to probe monomer and dimer forms of MoMuLV RNA indicated that the DLS probably maps between positions 280 and 330 from the RNA 5' end. Also, retroviral nucleocapsid protein was shown to catalyze dimerization of MoMuLV RNA and to be tightly bound to genomic dimer RNA in virions. These results suggest that MoMuLV RNA dimerization and encapsidation are probably controlled by the same cis element, Psi, and trans-acting factor, nucleocapsid protein, and thus might be linked during virion formation.

A study of the dimer formation of Rous sarcoma virus RNA and of its effect on viral protein synthesis in vitro

The genetic material of all retroviruses examined so far is an RNA dimer where two identical RNA subunits are joined at their 5' ends by a structure named dimer linkage structure (DLS). Since the precise location and structure of the DLS as well as the mechanism and role(s) of RNA dimerization remain unclear, we analysed the dimerization process of Rous sarcoma virus (RSV) RNA. For this purpose we set up an in vitro model for RSV RNA dimerization. Using this model RSV RNA was shown to form dimeric molecules and this dimerization process was greatly activated by nucleocapsid protein (NCp12) of RSV. Furthermore, RSV RNA dimerization was performed in the presence of complementary 5'32P-DNA oligomers in order to probe the monomer and dimer forms of RSV RNA. Data indicated that the DLS of RSV RNA probably maps between positions 544-564 from the 5' end. In an attempt to define sequences needed for the dimerization of RSV RNA, deletion mutageneses were generated in the 5' 600 nt. The results showed that the dimer promoting sequences probably are located within positions 208-270 and 400-600 from the 5' end and hence possibly encompassing the cis-acting elements needed for the specific encapsidation of RSV genomic RNA. Also it is reported that synthesis of the polyprotein precursor Pr76gag is inhibited upon dimerization of RSV RNA. These results suggest that dimerization and encapsidation of genome length RSV RNA might be linked in the course of virion formation since they appear to be under the control of the same cis elements, E and DLS, and the trans-acting factor nucleocapsid protein NCp12.

What is the role of the cys-his motif in retroviral nucleocapsid (NC) proteins?

Retroviruses encode a small, basic nucleocapsid (NC) protein that is found complexed to genomic RNA within the viral particle. The NC protein appears to function not only in a histone-like manner in packaging the RNA into the particle but also in specifically selecting the viral genomic RNA for packaging. A cysteine-histidine (cys-his) region, usually composed of 14 amino acids and reminiscent of the 'zinc fingers' of transcription factors, is the only highly conserved sequence element among the retroviral NC proteins. This review discusses the biochemical properties of NC, and its possible role(s) in retroviral replication. We also speculate on how the biochemical properties may relate to its function in RNA recognition and packaging.

HIV-1 Gag mutants can dominantly interfere with the replication of the wild-type virus

The products of the human immunodeficiency virus (HIV) gag gene exist in a highly multimerized state in the mature virion. For that reason, they may represent a particularly suitable target for the generation of dominant negative mutants. A number of HIV site-directed Gag mutants did show interference with the production of infectious viral particles from cells in which they were cotransfected with a wild-type proviral DNA. Furthermore, cells constitutively expressing such HIV Gag mutants had an impaired ability to support HIV replication when infected with wild-type virus. The block was localized to the late stages of the virus life cycle. Such Gag variants could constitute prototypes for the development of anti-HIV intracellular immunization.