Alteration of zinc-binding residues of simian immunodeficiency virus p8(NC) results in subtle differences in gag processing and virion maturation associated with degradative loss of mutant NC.

In all retroviruses analyzed to date (except for the spumaretroviruses), the Zn(2+)-coordinating residues of nucleocapsid (NC) perform or assist in crucial reactions necessary to complete the retrovirus life cycle. Six replication-defective mutations have been engineered in the two NC Zn(2+) fingers (ZFs) of simian immunodeficiency virus [SIV(Mne)] that change or delete specific Zn(2+)-interacting Cys residues and were studied by using electron microscopy, reversed-phase high-performance liquid chromatography, immunoblotting, and RNA quantification. We focused on phenotypes of produced particles, specifically morphology, Gag polyprotein processing, and genomic RNA packaging. Phenotypes were similar among viruses containing a point or deletion mutation involving the same ZF. Mutations in the proximal ZF (ZF1) resulted in near-normal Gag processing and full-length genomic RNA incorporation and were most similar to wild-type (WT) virions with electron-dense, conical cores. Mutation of the distal ZF, as well as point mutations in both ZFs, resulted in more unprocessed Gag proteins than a deletion or point mutation in ZF1, with an approximate 30% reduction in levels of full-length genomic RNA in virions. These mutant virions contained condensed cores; however, the cores typically appeared less electron dense and more rod shaped than WT virions. Surprisingly, deletion of both ZFs, including the basic linker region between the ZFs, resulted in the most efficient Gag processing. However, genomic RNA packaging was approximately 10% of WT levels, and those particles produced were highly abnormal with respect to size and core morphology. Surprisingly, all NC mutations analyzed demonstrated a significant loss of processed NC in virus particles, suggesting that Zn(2+)-coordinated NC is protected from excessive proteolytic cleavage. Together, these results indicate that Zn(2+) coordination is important for correct Gag precursor processing and NC protein stability. Additionally, SIV particle morphology appears to be the result of proper and complete Gag processing and relies less on full-length genomic RNA incorporation, as dictated by the Zn(2+) coordination in the ZFs of the NC protein.

Ubiquitination of HIV-1 and MuLV Gag.

Our previous biochemical studies of HIV-1 and MuLV virions isolated and identified mature Gag products, HIV-1 p6(Gag) and MuLV p12(Gag), that were conjugated to a single ubiquitin. To study the importance of the monoubiquitination of Gag, a series of lysine to arginine mutants were constructed that eliminated ubiquitination at one or both of the lysines in HIV-1(NL4-3) p6(Gag) and both lysines in Moloney MuLV p12(Gag). HPLC and immunoblot analysis of the HIV-1 mutants demonstrated that either of the lysines in p6(Gag), K27 or K33, could be monoubiquitinated. However, infectivity assays showed that monoubiquitination of HIV-1 p6(Gag) or MuLV p12(Gag) is not required for viral replication in vitro. Pulse-chase radiolabeling of HIV-1-producing cells revealed that monoubiquitination of p6(Gag) does not affect the short-term release of virus from the cell, the maturation of Pr55(Gag), or the sensitivity of these processes to proteasome inhibitors. Experiments with protease-deficient HIV-1 showed that Pr55(Gag) can be monoubiquitinated, suggesting that p6(Gag) is first modified as a domain within Gag. Examination of the proteins inside an HIV-1 mutant found that free ubiquitin was incorporated into the virions in the absence of the lysines in p6(Gag), showing that the ubiquitin inside the virus is not initially brought in as a p6(Gag) conjugate. Although our results establish that monoubiquitination of p6(Gag) and p12(Gag) is not required for viral replication in vitro, this modification may be a by-product of interactions between Gag and cellular proteins during assembly and budding.

Proteasome inhibition interferes with gag polyprotein processing, release, and maturation of HIV-1 and HIV-2.

Retrovirus assembly and maturation involve folding and transport of viral proteins to the virus assembly site followed by subsequent proteolytic cleavage of the Gag polyprotein within the nascent virion. We report that inhibiting proteasomes severely decreases the budding, maturation, and infectivity of HIV. Although processing of the Env glycoproteins is not changed, proteasome inhibitors inhibit processing of Gag polyprotein by the viral protease without affecting the activity of the HIV-1 viral protease itself, as demonstrated by in vitro processing of HIV-1 Gag polyprotein Pr55. Furthermore, this effect occurs independently of the virus release function of the HIV-1 accessory protein Vpu and is not limited to HIV-1, as proteasome inhibitors also reduce virus release and Gag processing of HIV-2. Electron microscopy analysis revealed ultrastructural changes in budding virions similar to mutants in the late assembly domain of p6(gag), a C-terminal domain of Pr55 required for efficient virus maturation and release. Proteasome inhibition reduced the level of free ubiquitin in HIV-1-infected cells and prevented monoubiquitination of p6(gag). Consistent with this, viruses with mutations in PR or p6(gag) were resistant to detrimental effects mediated by proteasome inhibitors. These results indicate the requirement for an active proteasome/ubiquitin system in release and maturation of infectious HIV particles and provide a potential pharmaceutical strategy for interfering with retrovirus replication.

Mutational analysis of the hydrophobic tail of the human immunodeficiency virus type 1 p6(Gag) protein produces a mutant that fails to package its envelope protein.

The p6(Gag) protein of human immunodeficiency virus type 1 (HIV-1) is produced as the carboxyl-terminal sequence within the Gag polyprotein. The amino acid composition of this protein is high in hydrophilic and polar residues except for a patch of relatively hydrophobic amino acids found in the carboxyl-terminal 16 amino acids. Internal cleavage of p6(Gag) between Y36 and P37, apparently by the HIV-1 protease, removes this hydrophobic tail region from approximately 30% of the mature p6(Gag) proteins in HIV-1MN. To investigate the importance of this cleavage and the hydrophobic nature of this portion of p6(Gag), site-directed mutations were made at the minor protease cleavage site and within the hydrophobic tail. The results showed that all of the single-amino-acid-replacement mutants exhibited either reduced or undetectable cleavage at the site yet almost all were nearly as infectious as wild-type virus, demonstrating that processing at this site is not important for viral replication. However, one exception, Y36F, was 300-fold as infectious the wild type. In contrast to the single-substitution mutants, a virus with two substitutions in this region of p6(Gag), Y36S-L41P, could not infect susceptible cells. Protein analysis showed that while the processing of the Gag precursor was normal, the double mutant did not incorporate Env into virus particles. This mutant could be complemented with surface glycoproteins from vesicular stomatitis virus and murine leukemia virus, showing that the inability to incorporate Env was the lethal defect for the Y36S-L41P virus. However, this mutant was not rescued by an HIV-1 Env with a truncated gp41(TM) cytoplasmic domain, showing that it is phenotypically different from the previously described MA mutants that do not incorporate their full-length Env proteins. Cotransfection experiments with Y36S-L41P and wild-type proviral DNAs revealed that the mutant Gag dominantly blocked the incorporation of Env by wild-type Gag. These results show that the Y36S-L41P p6(Gag) mutation dramatically blocks the incorporation of HIV-1 Env, presumably acting late in assembly and early during budding.

Chemical inactivation of retroviral infectivity by targeting nucleocapsid protein zinc fingers: a candidate SIV vaccine.

Although most viral vaccines used in humans have been composed of live attenuated viruses or whole killed viral particles, the latter approach has received little attention in research on experimental primate immunodeficiency virus vaccines. Inactivation procedures involving heat or formalin appear to adversely affect the viral envelope proteins. Recently we have inactivated human immunodeficiency virus type 1 (HIV-1) with the compound 2,2'-dithiodipyridine (Aldrithiol-2, Aldrich, Milwaukee, WI), which inactivates infectivity of retroviruses by covalently modifying the nucleocapsid zinc finger motifs. HIV-1 inactivated with Aldrithiol-2 retained the conformational and functional integrity of the viral and virion-associated cellular proteins on the viral membrane. We have extended our studies of zinc finger targeted inactivation to simian immunodeficiency virus (SIV) and evaluated the feasibility of applying the procedures to large scale (>30 l) production and purification of the primate immunodeficiency viruses. There was no detectable residual infectivity of SIV after treatment with 1 mM Aldrithiol-2 (>5 logs inactivation). Treatment with Aldrithiol-2 resulted in extensive reaction with the nucleocapsid protein of treated virus, as shown by immunoblot and high-performance liquid chromatography (HPLC) analysis. As expected, the virion gp120SU appeared to be completely unreactive with Aldrithiol-2. Sucrose gradient purification and concentration procedures resulted in little loss of viral infectivity or virion-associated gp120SU. When tested in a gp120-CD4 dependent cell binding assay, the inactivated virus bound to cells comparably to the untreated virus. Analysis of gp120-CD4 mediated postbinding fusion events showed that the inactivated virus could induce CD4-dependent fusion with efficiencies similar to the untreated virus. Inactivation and processing of primate immunodeficiency viruses by methods described here results in highly concentrated virus preparations that retain their envelope proteins in a native configuration. These inactivated virus preparations should be useful in whole killed-particle vaccine experiments as well as laboratory reagents to prepare antisera, including monoclonal antibodies, and to study noninfective virion-cell interactions.

Probing the topography of HIV-1 nucleocapsid protein with the alkylating agent N-ethylmaleimide.

Retroviral nucleocapsid (NC) proteins contain one or two zinc fingers (ZFs) consisting of a CCHC peptide motif that coordinates Zn(II). Mutational and biochemical analyses have shown that NC ZFs are directly involved in multiple stages of viral replication, including genomic RNA encapsidation, virus maturation, and the early infection process. The multiple roles of the conserved retroviral ZFs make them attractive targets for antiviral agents. We have previously shown that a variety of chemical compounds can inactivate the whole virus by attacking NC ZFs. For the enhancement of the specificity of antiviral reagents, it is desirable to have a detailed knowledge of the spatial organization of reactive sites on the NC protein in its free and oligonucleotide-bound states. A method has been developed using chemical probes to assess the reactivity of specific Cys residues in the NC protein, and is being used to investigate the topography of ZFs in different contexts. In this study we focus on the reaction mechanism of N-ethylmaleimide (NEM) with free HIV-1 NCp7 protein. Our results show that the conformation of free NCp7 restricts the initial site of attack to Cys-49 (the most distal Cys residue in the second ZF) and that the reactivity of thiols in full-length protein differs from that of the isolated ZF peptides. A moderate to near complete reduction in reaction rate was observed when NCp7 was complexed with different oligonucleotides. These findings provide a set of experimentally determined parameters that can serve to guide computational modeling of the NC protein and will be useful for the rational design of drugs directed against retroviral ZFs.

Cytoskeletal proteins inside human immunodeficiency virus type 1 virions.

We have identified three types of cytoskeletal proteins inside human immunodeficiency virus type 1 (HIV-1) virions by analyzing subtilisin-digested particles. HIV-1 virions were digested with protease, and the treated particles were isolated by sucrose density centrifugation. This method removes both exterior viral proteins and proteins associated with microvesicles that contaminate virion preparations. Since the proteins inside the virion are protected from digestion by the viral lipid envelope, they can be isolated and analyzed after treatment. Experiments presented here demonstrated that this procedure removed more than 95% of the protein associated with microvesicles. Proteins in digested HIV-1(MN) particles from infected H9 and CEM(ss) cell lines were analyzed by high-pressure liquid chromatography, protein sequencing, and immunoblotting. The data revealed that three types of cytoskeletal proteins are present in virions at different concentrations relative to the molar level of Gag: actin (approximately 10 to 15%), ezrin and moesin (approximately 2%), and cofilin (approximately 2 to 10%). Our analysis of proteins within virus particles detected proteolytic fragments of alpha-smooth muscle actin and moesin that were cleaved at sites which might be recognized by HIV-1 protease. These cleavage products are not present in microvesicles from uninfected cells. Therefore, these processed proteins are most probably produced by HIV-1 protease digestion. The presence of these fragments, as well as the incorporation of a few specific cytoskeletal proteins into virions, suggests an active interaction between cytoskeletal and viral proteins.

[Primary structure of the beta-subunit of Na+,K+-ATPase from the swine kidney. I. Analysis of products of trypsin hydrolysis of immobilized proteins]. / Pervichnaia struktura beta-sub''edinitsy Na+,K+-ATP-azy pochek svin'i. I. Analiz produktov tripticheskogo gidroliza immobilizovannogo belka.

The Na+, K+-ATPase's beta-subunit immobilized on thiol-glass was hydrolyzed with trypsin. Over 25 peptides covering ca. 90% of the protein polypeptide chain were isolated from the digest by HPLC and characterized. Structural analysis allowed us to localize the sites of attachment of all three carbohydrate chains of beta-subunit. Sequence data were used to design of oligonucleotide hybridization probes for gene cloning.

[Primary structure of the OSCP protein that confers sensitivity to oligomycin on the mitochondrial H+-ATPase complex. I. Tryptic and cyanogen bromide peptides]. / Pervichnaia struktura OSCP--belka, pridaiushchego mitokhondrial'nomu H+-ATP-aznomu kompleksu chuvstvitel'nost' k oligoitsinu. I. Tripticheskie i bromtsianovye peptidy.

Trypsin and cyanogen bromide were used for cleavage of the OSCP preparations. The peptide mixtures thus formed were separated into individual components by a combination of various chromatographic procedures: gel filtration, ion exchange and paper chromatography, as well as reversed-phase HPLC. As a result, 31 tryptic peptides and 9 out of 10 possible cyanogen bromide peptides were isolated. Determination of the amino acid sequences of these peptide allowed the alignment of cyanogen bromide fragments in the polypeptide chain that shed light on the "architecture" of the protein molecule as a whole. It also afforded the overlappings for tryptic peptides, 16 in the N-terminal and 8 in the C-terminal portions of the molecule.