井戸 栄治

Objective: To examine the biological properties of HIV-1/SIVmac chimeric viruses from HIV-1 isolates that have different replication rates, cell tropisms and cytopathicities. Design and methods: Four chimeric viruses with gag, pol, vif, vpx, nef and long terminal repeats of SIVmac and vpr, tat, rev, vpu and env of various HIV-1 isolates were constructed and compared in vitro. Cynomolgus monkeys were inoculated with two chimeras that were replicative in monkey peripheral blood mononuclear cells (PBMC). Results: The type-specific neutralization of the chimeras by monoclonal antibodies 0.5 beta and mu 5.5, which recognize V3 of HIV-1(IIIB) and HIV-1(MN) respectively, was observed to be similar to those of the parental viruses, HIV-1(NL432), HIV-1(HAN2) and HIV-1(SF13). The chimeras constructed from HIV-1(SF2) and HIV-1(SF13), which were isolates from the same individual hut from different disease stages, reflected their parental properties, that is, the isolate from the later stage was rapid-high replicating, was more cytopathic and had a wider host range. Chimeras constructed from HIV-1(HAN2), HIV-1(SF13) and HIV-1(NL432) were infectious to macaque monkeys, although the monkeys infected with the chimera from HIV-1(SF13) showed lower virus loads and shorter viremic periods than those infected with the others. Conclusions: Chimeras have in vitro properties that are similar to those of their parental HIV-1 isolates, but their growth in macaque PBMC was dependent on which HIV-1 isolate was used. Evaluation of a vaccine by challenging with viruses possessing different antigenicities has become possible in macaque monkeys using newly constructed chimeras.

Two chimeric viruses were constructed between human immunodeficiency virus type 1 (HIV-1) and an apathogenic simian immunodeficiency virus (SIVagm3mc) from African green monkeys, One of the chimeras, HE-A391, expressed the HIV-1-derived env, vpu, tat and rev genes and the SIVagm3mc-derived LTR and the gag, pol and vif genes, The other chimera, SE-H13, contained the SIVagm3mc-derived env, tat and rev genes and the HIV-l-derived LTR and the gag, pol, vif and nef genes, Both constructs yielded infectious viruses and their phenotypes (growth-competence and cell-killing capacity) were examined in various CD4(+) cells including human and monkey PBMCs, The results indicated that the replicative properties of the chimeras were mainly dependent on the 5'-genomic half of the parental viruses, and the determinant for viral cytopathogenicity was located within the 5' half of the HIV-1 genome.

A macaque monkey infected with NM-3, a human immunodeficiency virus type 1 (HIV-1)-simian immunodeficiency virus strain mac (SIVmac) chimeric virus with env, rev, tat and vpu derived from HIV-1 and LTR, gag, pol, vif and vpx derived from SIVmac, became a long-term carrier (more than 2 . 8 years), This monkey produced neutralizing antibodies to the original NM-3 as well as to the parental HIV-1, The virus recovered at 116 weeks replicated more rapidly and productively in macaque peripheral blood mononuclear cells than the original virus, The recovered virus was not neutralized either by antibodies raised early in the monkey or by a neutralizing monoclonal antibody that recognizes the V3 loop of HIV-1 Env, whereas both the early antibodies and the monoclonal antibody neutralized the original NM-3, Analysis of the virus genomic population revealed a few common mutations in the V3 region that caused amino acid changes, These data are consistent with the hypothesis that the virus escaped from the early antibodies and that the observed mutations contributed to this, as with HIV-1-infected humans, The observed mutations could equally well be the result of adaptation to simian cells, These results suggest that the HIV-1-SIVmac chimeric virus will be useful for investigating genetic variation of HIV-1 env and alteration of biological properties in vivo in relation to the frost immune response.

To clarify the physiological function of two zinc finger motifs in the nucleocapsid (NC) domain of the Gag protein of human immunodeficiency virus type 1 (HIV-1), we changed cysteine to serine in either of the two motifs or both by site-directed mutagenesis. Viral infectivity was lost by any of the mutations, but their effects appeared differently in the respective mutants. Northern blot analysis showed that the first finger mutant was far less efficient (approximately 10% of the wild type) in genomic RNA encapsidation and that the dual mutant of both fingers completely failed to encapsidate the RNA. In contrast, the second finger mutant retained its ability for RNA encapsidation with an efficiency similar to that of the wild type, Immunoblot analysis of the lysates of CD4-positive M8166 cells transfected with the mutant proviral DNAs showed that the processing of Gag precursors was delayed in two mutant viruses having alterations in the first finger sequence, whereas the processing of the second finger mutant appeared to be normal. On the other hand, immunoblot analysis of the virus particles showed that the second finger mutant particles contained some proteins that were thought to be degradation products of p24(CA). Electron microscopic observation showed that all particles of these mutant viruses were morphologically alike except that they had a slightly larger diameter than that of the wild type. These results indicate that these finger motifs of HIV-1 NC protein do not function equivalently. Namely, the first finger is primarily responsible for RNA encapsidation and the second is required for stabilization of virus particles.

The geographic distribution of human T-cell lymphotropic/leukemia virus type I (HTLV-I) was initially believed to be limited to southwestern Japan, the Caribbean basin, and Africa, However, extensive searches in recent years have discovered its existence in other areas of the world as well as in isolated, ethnic populations such as South Amerindians. Australo-Melanesian aborigines, religiously segregated Jews, and Pygmies. Previous genetic analyses indicated that HTLV-I can be phylogenetically classified into three major lineages: Melanesian, Central African, and Cosmopolitan groups. Recently, more detailed characterization using long terminal repeat sequences (the most variable genomic region) has revealed that the Cosmopolitan group consists of four subtypes: (A) Transcontinental, (B) Japanese, (C) West African, and (D) North African. Most HTLV-I isolates of the same ethnic group from distant locations and those from different groups inhabiting the same area showed phylogenetic similarities. These observations indicate the present distribution of this virus should be interpreted from the anthropological backgrounds of the virus-possessing populations as well as spatial contact among them, Thus, the molecular epidemiology of HTLV-I and its simian counterpart, STLV-I, provides us with important clues for understanding not only the origin and dissemination of this retrovirus but past human movements over the globe.

To investigate the functional complementation of essential genes for virus growth between HIV-1 and SIVagm derived from African green monkeys, we co-transfected replication-defective molecular clones containing mutations in gag, pol, env, tat or rev, and monitored transient complementation by reverse transcriptase assay (RT), cytopathic effect (CPE) and immunofluorescence assay (IFA). The following results were obtained: 1) No complementation was observed in combinations of the gag and pol mutants. 2) The rev mutant of HIV-1 was minimally complemented by other SIVagm mutants, although the rev mutant of SIVagm was significantly complemented by other HIV-1 mutants. 3) Among all combinations tested, the enu mutant of HIV-1 was the most effectively complemented by SIVagm mutants. 4) CPE was mostly absent in combinations of the env mutant of SIVagm and the gag, pol or tnt mutants of HIV-1, although there were significant positive results in RT and IFA assays. These findings provided basic information about the functional compatibility of pathogenic HIV-1 and nonpathogenic SIVagm which will be useful for generating chimeras of these two viruses.

A new endemic focus of human T-lymphotropic virus type I (HTLV-I) was recently reported among Mashhadi Jews, a group of immigrants from northeastern Iran to Israel. We extracted DNAs from fresh peripheral blood mononuclear cells (PBMCs) and/or gargle mouthwash from 10 HTLV-I carriers, who consisted of members of one family, and HTLV-I-associated myelopathy (HAM) and adult T-cell leukemia (ATL) patients. Long terminal repeat (LTR) regions of proviral DNAs were sequenced and analyzed phylogenetically. In a phylogenetic tree, all the Mashhadi HTLV-I isolates belonged to subtype A, one of the three subtypes of the cosmopolitan type of HTLV-I, and made a tight cluster distinct from the other isolates of subtype A from Japan, India, the Caribbean Basin, and South America. Although a few nucleotide substitutions were observed among the clones sequenced, no characteristic sequence variation was found in different disease manifestations, even in one family or different sources of DNA preparation.

The infectivity of the human immunodeficiency virus (HIV) depends upon correct proteolytic processing of viral polyprotein precursors, the pr55(gag) and Pr160(gag-pol) polyproteins. The processing is mediated spontaneously by the viral protease unit (PR) contained within the Pr160(gag-pol) precursor. However, little is known about the mechanism of this process. The expression in Escherichia coli and the isolation of a 14-kDa HIV-1 PR ''miniprecursor'' with Ala(28) mutated to serine has permitted study of the mechanism for cleavage at the N-terminus of the protease. The miniprecursor is active against a synthetic peptide substrate, and its specific activity is near that of the mutant mature protease. The rate of conversion of radiolabeled precursor to mature protease is quantitated by measuring the amounts of the two radiolabeled proteins separated by SDS-PAGE. The apparent first-order conversion rate constant, k(app,) is dependent on miniprecursor concentration indicating a second-order reaction and suggesting an interdimeric processing mechanism. A significant first-order rate constant is observed when the plot of k(app) versus initial precursor concentration is extrapolated to zero. This observation suggests the presence of an alternative processing mechanism involving a single active precursor dimer. The presence of both mechanisms is an advantage for the virus to ensure processing under various conditions.

Isolates of human T-lymphotropic virus type I (HTLV-I) were phylogenetically analyzed from native inhabitants in India and South America (Colombia and Chile) and from Ainu (regarded as pure Japanese descendants from the preagricultural ''Jomon'' period). Their genomes were partially sequenced together with isolates from Gabon in central Africa and from Ghana in West Africa. The phylogenetic tree was constructed from the sequence data obtained and those of previously reported HTLV-I isolates and simian T-lymphotropic virus type I (STLV-I) isolates. The heterogeneity of HTLV-I was recently recognized, and one major type, generally called the ''cosmopolitan'' type, contained Japanese, Caribbean, and West African isolates. The phylogenetic tree constructed in the present study has shown that this cosmopolitan type can be further grouped into three lineages (subtypes A, B, and C). Subtype A consists of some Caribbean, two South American, and some Japanese isolates, including that from the Ainu, in addition to an Indian isolate, and subtype B consists of other Japanese isolates in addition to another Indian isolate, suggesting that there might be at least two ancestral lineages of the Japanese HTLV-I. Subtype A implies a close connection of the Caribbean and South American natives with the Japanese and thereby a possible migration of the lineage to the American continent via Beringia in the Paleolithic era. Subtype C consists of the West African and other Caribbean isolates, indicating that not all but part of the Caribbean strains directly originated from West Africa probably during the period of slave trade. The tree also has shown that the HTLV-I isolate from Gabon in central Africa forms a cluster with STLV-I from a chimpanzee, suggesting a possible interspecies transmission between man and the chimpanzee in the past. No specific clustering was observed in the tree in relation to manifestations of the disease such as adult T-cell leukemia and HTLV-I-related neurological disorders. Thus, the topology of the phylogenetic tree reflects the movement of people carrying the virus in the past.

Human immunodeficiency virus type 1 (HIV-1) protease optimally catalyzes in the pH range of 4-6 in contrast to nearly all of the other eukaryotic aspartic proteases, which catalyze best in the pH range of 2-4. A possible structural reason for the higher optimal pH of HIV-1 protease is the absence of a hydrogen bond to the carboxyl group of active-site Asp25, which is nearly universally present in others. To investigate this hypothesis, we have mutated residue 28 in HIV-1 protease from alanine to serine. Both the wild-type and the mutant A28S enzymes have been overexpressed in Escherichia coli using a chemically synthesized gene and purified for a comparative study in enzyme kinetics. The k(cat) and K(m) values were determined by a radiometric assay for the wild-type enzyme from pH 3.2 to 7.0, and for the mutant enzyme from pH 3.2 to 6.0. The low pK values of the active site of the free enzyme, pK(e1), are 3.3 and 3.4 for the wild-type and mutant enzymes, respectively. The low pK values of the active site of the enzyme bound to substrate, pK(es1), are 5.1 and 4.3 for the wild-type and mutant enzymes, respectively. The high pK values of the free enzyme, pK(e2), are 6.8 and 5.6, and the corresponding ones for the substrate-bound enzyme, pK(es2), are 6.9 and 6.0 for the wild-type and mutant enzymes, respectively. The lowering of pK values in mutant HIV-1 protease indicates that the hydroxyl group of Ser28 forms a new hydrogen bond to active-site Asp25 to increase its acidity.