Characterization of a soluble stable human cytomegalovirus protease and inhibition by M-site peptide mimics.

The human cytomegalovirus (HCMV) protease is a potential target for antiviral chemotherapeutics; however, autoprocessing at internal sites, particularly at positions 143 and 209, hinders the production of large quantities of stable enzyme for either screening or structural studies. Using peptides encompassing the sequence of the natural M-site substrate (P5-P5', GVVNA/SCRLA), we previously demonstrated that substitution of glycine for valine at the P3 position in the substrate abrogates processing by the recombinant protease in vitro. We now demonstrate that introduction of the V-to-G substitution in the P3 positions of the two major internal processing sites, positions 143 and 209, in the mature HCMV protease renders the enzyme stable to autoprocessing. When expressed in Escherichia coli, the doubly substituted protease was produced almost exclusively as the 30-kDa full-length protein. The full-length V141G, V207G (V-to-G changes at positions 141 and 207) protease was purified as a soluble protein by a simple two-step procedure, ammonium sulfate precipitation followed by DEAE ion-exchange chromatography, resulting in 10 to 15 mg of greater than 95% pure enzyme per liter. The stabilized enzyme was characterized kinetically and was indistinguishable from the wild-type recombinant protease, exhibiting Km and catalytic constant values of 0.578 mM and 13.18/min, respectively, for the maturation site (M-site) peptide substrate, GVVNASCRLARR (underlined residues indicate additions to or substitutions from peptides derived from the wild-type substrate). This enzyme was also used to perform inhibition studies with a series of truncated and/or substituted maturation site peptides. Short nonsubstrate M-site-derived peptides were demonstrated to be competitive inhibitors of cleavage in vitro, and these analyses defined amino acids VVNA, P4 through P1 in the substrate, as the minimal substrate binding and recognition sequence for the HCMV protease.

Comprehensive mutant enzyme and viral variant assessment of human immunodeficiency virus type 1 reverse transcriptase resistance to nonnucleoside inhibitors.

The nonnucleoside reverse transcriptase (RT) inhibitors comprise a class of structurally diverse compounds that are functionally related and specific for the human immunodeficiency virus type 1 RT. Viral variants resistant to these compounds arise readily in cell culture and in treated, infected human. Therefore, the eventual clinical usefulness of the nonnucleoside inhibitors will rely on a thorough understanding of the genetic and biochemical bases for resistance. A study was performed to assess the effects of substitutions at each RT amino acid residue that influences the enzyme's susceptibility to the various nonnucleoside compounds. Single substitutions were introduced into both purified enzyme and virus. The resulting patterns of resistance were markedly distinct for each of the tested inhibitors. For instance, a > 50-fold loss of enzyme susceptibility to BI-RG-587 was engendered by any of four individual substitutions, while the same level of relative resistance to the pyridinone derivatives was mediated only by substitution at residue 181. Similarly, substitution at residue 181. Similarly, substitution at residue 106 had a noted effect on virus resistance to BI-RG-587 but not to the pyridinones. The opposite effect was mediated by a substitution at residue 179. Such knowledge of nonucleoside inhibitor resistance profiles may help in understanding the basis for resistant virus selection during clinical studies of these compounds.

Mutant ras-encoded proteins with altered nucleotide binding exert dominant biological effects.

We report that residues Lys-16 and Asp-119 play critical roles in the guanine nucleotide binding and, consequently, the biological function of the Ha-ras-encoded protein (Ha). Substitution of an asparagine residue for Lys-16 reduces the affinity of Ha for GDP and GTP by a factor of 100 but does not alter the specificity of nucleotide binding. The replacement of Asp-119 with an alanine residue reduces the affinity of Ha for GDP and GTP by a factor of 20 and reduces the relative affinity of Ha for GDP over IDP from 200-500 to 10. Based on these observations, a structural model for the GDP/GTP-binding site of Ha is proposed. By microinjecting purified proteins into NIH 3T3 cells, we observed that the ability of [Ala119]Ha to induce changes characteristic of cellular transformation was much greater than that of normal Ha and similar to that of the oncogenic [Val12, Thr59]Ha. In this assay, [Asn16]Ha and [Val12, Asn16, Thr59]Ha were similar in potency to normal Ha. In yeast cells, Ha proteins with reduced nucleotide affinity exert a dominant temperature-dependent lethality that is avoided by the coexpression of the activated yeast ras gene [Ala18, Val19]RAS2. We interpret the biological consequences of reducing the nucleotide affinity of ras proteins in terms of two opposing factors: a growth-promoting effect, resulting from an increase in the GDP-GTP exchange rate, and a growth-limiting effect, resulting from an increase in the nucleotide-free ras protein species.

Visualization of bacterial polysaccharides by scanning transmission electron microscopy.

Highly purified capsular polysaccharides of Neisseria meningitidis groups A, B, and C have been visualized by high resolution Scanning Transmission Electron Microscopy (STEM). Spheroidal macromolecules approximately 200 A in diameter are characteristic of the Meningococcus A and C polysaccharides whereas filaments that are 400-600 A in length are found in Meningococcus B polysaccharide preparations. Filaments are occasionally found associated with the spheroidal Meningococcus A and C polysaccharides and it is proposed that these structures are composed of a long (1-4 microns) filament or filaments that are arranged in spheroidal molecules or micelles of high molecular weight. The Meningococcus B polysaccharide, by contrast, is a short flexuous filament or strand of relatively low molecular weight. A relationship between morphology and antigenicity is proposed.

Infectious hepatitis (hepatitis A) research in nonhuman primates.

A satisfactory animal model has been found for laboratory studies of human hepatitis A-namely, the white-moustached marmoset (Saguinus mystax). With this species it has been possible to perform serum-neutralization tests and to develop immune-adherence and complement-fixation tests demonstrating antigen and antibody to the virus. The recent work in marmosets has also led to determination of the agent's characteristics: it most closely resembles the enteroviruses of the picornavirus family. These advances open the way for development of a routine serologic test for diagnosis of the disease, of a human immune globulin for general use that would be precisely standardized for hepatitis A antibody, and, ultimately, of a vaccine. They also provide bases for epidemiologic studies that could reveal nonspecific measures for the disease's control. In addition, there is indication that marmosets could be used for safety control of the hepatitis B vaccine that has already been developed. An adequate supply of S. mystax-threatened by recent embargoes on their exportation-is essential to continuation of this work. The question of marmoset supply, both in the short term and over the long range, deserves serious review.

Biophysical and biochemical properties of CR326 human hepatitis A virus.

CR326 human hepatitis A virus purified by isopycnic banding from infected marmoset sera was shown to consist of 27 mmu spherical particles on electron microscopic examination. The particles were identified as hepatitis A virus by tests by infectivity and by specific neutralization of infectivity with convalescent human hepatitis A serum. Also, identical 27 mmu viruses in liver extracts gave specific reactions with hepatitis A antisera when tested by immune electron microscopy. The buoyant density of the virus in CsCl was 1.34 and it was heat (60 C), ether, and acid stable but was destroyed by heat (100 C), formalin (1:4000), and ultraviolet irradiation. Electron microscopic studies of sections of infected marmoset liver showed intracytoplasmic virus particles, usually in vesicles. Presumptive findings for RNA, together with the intracytoplasmic location of the virus, indicated the virus to be of RNA-type. The attributes of the virus indicate it is closely related to the enterovirus family and not to hepatitis B virus.

Physical, chemical and morphologic dimensions of human hepatitis A virus strain CR326 (38578).

CR326 human hepatitis A virus purified by isopycnic banding from infected marmoset sera was shown to consist of 27 nm spherical particles on electron microscopic examination. The particles were identified as hepatitis A virus by tests for infectivity and by specific neutralization of infectivity with convalescent human hepatitis A serum. Also, indentical 27 nm viruses in liver extracts gave specific reactions with hepatitis A antisera when tested by immune electron microscopy. The bouyant density of the virus in CsCl was 1.34 and it was heat (60 degrees), ether and acid stable but was destroyed by heat (100 degrees), formalin (1:4000) and ultraviolet irradiation. Electron microscopic studies of sections of infected marmoset liver showed intracytoplasmic virus particles, usually in vesicles. Presumptive findings for RNA, together with the intracytoplasmic location of the virus, indicated the virus to be of RNA-type. The attributes of the virus indicate it is closely related to the enterovirus family and not to hepatitis B virus.

Characterization of CR326 human hepatitis A virus, a probable enterovirus.

CR326 human hepatitis A virus purified by isopycnic banding from infected marmoset sera was shown to consist of 27 mmu spherical particles on electron microscopic examination. The particles were identified as hepatitis A virus by tests for infectivity and by specific neutralization of infectivity with convalescent human hepatitis A serum. Also, identical 27 mmu viruses in liver extracts gave specific reactions with hepatitis A antisera when tested by immune electron microscopy. The buoyant density of the virus in CsCl was 1.34 and it was heat (60 degrees C), ether and acid stable but was destroyed by heat (100 degrees C), formalin (1:4000) and ultraviolet irradiation. Electron microscopic studies of sections of infected marmoset liver showed intracytoplasmic virus particles, usually in vesicles. Presumptive findings for RNA, together with the intracytoplasmic location of the virus, indicated the virus to be of RNA-type. The attributes of the virus indicate it is closely related to the enterovirus family and not to hepatitis B virus.