Human T-lymphotropic virus types I and II.

Human T-lymphotropic virus types I (HTLV-I) and II (HTLV-II) are members of a family of four known retroviruses that are oncogenic as opposed to cytopathic. This family includes HTLV-I and -II, bovine leukemia virus, and simian T-cell leukemia virus. The two types of HTLV are closely related, and for more than a decade we have been aware of the presence of these viruses in humans. In the first part of this article I summarize recent epidemiologic and clinical findings related to the presence of HTLV-I and -II in the Americas. In the second part, I discuss how these viruses may regulate themselves and how in turn they might cause leukemia and neurologic disease in humans.     

Delineation of type-specific regions on the envelope glycoproteins of human T cell leukemia viruses.

Two different approaches were used to map the type-specific regions on human T cell leukemia virus (HTLV) envelope glycoproteins. 1) Antibody reactivities of polymerase chain reaction-confirmed HTLV-I or HTLV-II carriers' sera were analyzed by Western blot assay with seven recombinant proteins containing different regions of HTLV-I or HTLV-II envelope proteins. 2) Rabbit antibodies elicited by nine HTLV-I Env synthetic peptides were used to react with the native HTLV envelope glycoproteins in an antibody-dependent cellular cytotoxicity (ADCC) assay. The results of the Western blot analysis showed that RP-B2, which contains amino acid residues 166 to 213 from HTLV-II exterior glycoprotein, was specifically reactive with 90.6% (48 of 53) of the HTLV-II carriers' sera but not with any of the HTLV-I carriers' serum (0 of 71). In contrast, RP-B, which contains amino acid residues 166 to 229 from HTLV-I exterior glycoprotein, was reactive with 85.1% (114 of 134) of the HTLV-I carriers' sera but not with any HTLV-II carrier serum (0 of 62). Furthermore, anti-HTLV-I Env synthetic peptide antibody-mediated ADCC identified several distinguishing HTLV-I ADCC epitopes in the middle region (amino acid residues 177 to 257) of the HTLV-I exterior glycoprotein. Therefore, HTLV type-specific epitopes reside mainly in a 69-amino acid sequence bounded by two cysteine residues (amino acids 157 and 225 for HTLV-I and 153 and 221 for HTLV-II), in the middle region of the exterior envelope glycoproteins.     

Splicing regulatory elements within tat exon 2 of human immunodeficiency virus type 1 (HIV-1) are characteristic of group M but not group O HIV-1 strains

In the NL4-3 strain of human immunodeficiency virus type 1 (HIV-1), regulatory elements responsible for the relative efficiencies of alternative splicing at the tat, rev, and the env/nef 3' splice sites (A3 through A5) are contained within the region of tat exon 2 and its flanking sequences. Two elements affecting splicing of tat, rev, and env/nef mRNAs have been localized to this region. First, an exon splicing silencer (ESS2) in NL4-3, located approximately 70 nucleotides downstream from the 3' splice site used to generate tat mRNA, acts specifically to inhibit splicing at this splice site. Second, the A4b 3' splice site, which is the most downstream of the three rev 3' splice sites, also serves as an element inhibiting splicing at the env/nef 3' splice site A5. These elements are conserved in some but not all HIV-1 strains, and the effects of these sequence changes on splicing have been investigated in cell transfection and in vitro splicing assays. SF2, another clade B virus and member of the major (group M) viruses, has several sequence changes within ESS2 and uses a different rev 3' splice site. However, splicing is inhibited by the two elements similarly to NL4-3. As with the NL4-3 strain, the SF2 A4b AG dinucleotide overlaps an A5 branchpoint, and thus the inhibitory effect may result from competition of the same site for two different splicing factors. The sequence changes in ANT70C, a member of the highly divergent outlier (group O) viruses, are more extensive, and ESS2 activity in tat exon 2 is not present. Group O viruses also lack the rev 3' splice site A4b, which is conserved in all group M viruses. Mutagenesis of the most downstream rev 3' splice site of ANT70C does not increase splicing at A5, and all of the branchpoints are upstream of the two rev 3' splice sites. Thus, splicing regulatory elements in tat exon 2 which are characteristic of most group M HIV-1 strains are not present in group O HIV-1 strains.     

Transforming viruses spontaneously arise from nontransforming reticuloendotheliosis virus strain T-derived viruses as a result of increased accumulation of spliced viral RNA.

The highly oncogenic avian retrovirus reticuloendotheliosis virus strain T (Rev-T) contains a substitution of the oncogene v-rel for much of env and a deletion of gag and pol relative to the helper virus Rev-A. Replacement of gag and pol sequences in Rev-T suppresses transformation by reducing the accumulation of spliced viral mRNA and v-rel protein in infected cells (C. K. Miller and H. M. Temin, J. Virol 58:75-80, 1986). After infection of spleen cells with viruses containing gag and pol sequences, revertant viruses that are strongly transforming were found. Approximately three-fourths of the revertant viruses appeared structurally the same as the parental virus, and approximately one-fourth of the revertant viruses had large deletions (similar in size and location to the deletion in Rev-T). Two revertant viruses that appeared structurally the same as the parental virus were molecularly cloned. The regions sufficient to change the parental virus to a strongly transforming virus were determined by construction of recombinant viruses. In one revertant virus, the region sufficient for transformation contained a 327-base-pair insertion 5' of the 3' splice site used by Rev-T. In the other revertant virus, the region sufficient for transformation contained a 1-base-pair transition and a deletion of one copy of a 9-base-pair direct repeat, both 3' of the 3' splice site used by Rev-T. These differences resulted in the accumulation of increased levels of subgenomic v-rel mRNA and protein, ultimately leading to transformation.     

The 3'' region of bovine leukemia virus genome encodes a trans-activator protein.

The genome of bovine leukemia virus (BLV) contains several overlapping, long open reading frames 3' to the envelope gene. Experiments presented here show that the cDNA encompassing the X region open reading frames encodes a trans-activator function capable of increasing the level of gene expression directed by the BLV long terminal repeat sequences. This study provides further evidence of the structural and functional similarities of the bovine leukemia virus and the human T lymphotropic viruses, HTLV-I and HTLV-II.     

Tempo and mode of human and simian T-lymphotropic virus (HTLV/STLV) evolution revealed by analyses of full-genome sequences

We investigated the tempo and mode of evolution of the primate T-lymphotropic viruses (PTLVs). Several different models of nucleotide substitution were tested on a general phylogenetic tree obtained using the 20 full-genome HTLV/STLV sequences available. The likelihood ratio test showed that the Tamura and Nei model with discrete gamma-distributed rates among sites is the best-fitting substitution model. The heterogeneity of nucleotide substitution rates along the PTLV genome was further investigated for different genes and at different codon positions (cdp's). Tests of rate constancy showed that different PTLV lineages evolve at different rates when first and second cdp's are considered, but the molecular-clock hypothesis holds for some PTLV lineages when the third cdp is used. Negative selection was evident throughout the genome. However, in the gp46 region, a small fragment subjected to positive selection was identified using a Monte Carlo simulation based on a likelihood method. Employing correlations of the virus divergence times with anthropologically documented migrations of their host, a possible timescale was estimated for each important node of the PTLV tree. The obtained results on these slow-evolving viruses could be used to fill gaps in the historical records of some of the host species. In particular, the HTLV-I/STLV-I history might suggest a simian migration from Asia to Africa not much earlier than 19,500-60,000 years ago.     

HIV-1 drug-resistance and drug-dependence

Background

The Deltaretrovirus genus comprises viruses that infect humans (HTLV), various simian species (STLV) and cattle (BLV). HTLV-I is the main causative agent in adult T-cell leukemia in endemic areas and some of the simian T-cell lymphotropic viruses have been implicated in the induction of malignant lymphomas in their hosts. BLV causes enzootic bovine leukosis in infected cattle or sheep. During the past few years several new Deltaretrovirus isolates have been described in various primate species. Two new HTLV-like viruses in humans have recently been identified and provisionally termed HTLV-III and HTLV-IV. In order to identify a broad spectrum of Deltaretroviruses by a single PCR approach we have established a novel consensus PCR based on nucleotide sequence data obtained from 42 complete virus isolates (HTLV-I/-II, STLV-I/-II/-III, BLV). The primer sequences were based on highly interspecies-conserved virus genome regions. We used this PCR to detect Deltaretroviruses in samples from adult patients with a variety of rare T-cell neoplasms in Germany.

Results

The sensitivity of the consensus PCR was at least between 10^-2 and 10^-3 with 100% specificity as demonstrated by serial dilutions of cell lines infected with either HTLV-I, HTLV-II or BLV. Fifty acute T-cell lymphoblastic leukemia (T-ALL) samples and 33 samples from patients with various rare mature T-cell neoplasms (T-PLL, Sézary syndrome and other T-NHL) were subsequently investigated. There were no cases with HTLV-I, HTLV-II or any other Deltaretroviruses.

Conclusion

The results rule out a significant involvement of HTLV-I or HTLV-II in these disease entities and show that other related Deltaretroviruses are not likely to be involved. The newly established Deltaretrovirus PCR may be a useful tool for identifying new Deltaretroviruses.     

Pseudotyping with human T-cell leukemia virus type I broadens the human immunodeficiency virus host range.

Several epidemiologic and clinical studies suggest that patients coinfected with human immunodeficiency virus (HIV), the primary etiologic agent in AIDS, and other viruses, such as cytomegalovirus or human T-cell leukemia virus (HTLV), have a more severe clinical course than those infected with HIV alone. Cells infected with two viruses can, in some cases, give rise to phenotypically mixed virions with altered or broadened cell tropism and could therefore account for some of these findings. Such pseudotypes could alter the course of disease by infecting more tissues than are normally infected by HIV. We show here that HIV type 1 (HIV-1) efficiently incorporates the HTLV type I (HTLV-I) envelope glycoprotein and that both HIV-1 and HTLV-II accept other widely divergent envelope glycoproteins to form infectious pseudotype viruses whose cellular tropisms and relative abilities to be transmitted by cell-free virions or by cell contact are determined by the heterologous envelope. We also show that the mechanism by which virions incorporate heterologous envelope glycoproteins is independent of the presence of the homologous glycoprotein or heterologous gag proteins. These results may have important implications for the mechanism of HIV pathogenesis.     

Serine/arginine-rich proteins contribute to negative regulator of splicing element-stimulated polyadenylation in rous sarcoma virus

Rous sarcoma virus (RSV) requires large amounts of unspliced RNA for replication. Splicing and polyadenylation are coupled in the cells they infect, which raises the question of how viral RNA is efficiently polyadenylated in the absence of splicing. Optimal RSV polyadenylation requires a far-upstream splicing control element, the negative regulator of splicing (NRS), that binds SR proteins and U1/U11 snRNPs and functions as a pseudo-5' splice site that interacts with and sequesters 3' splice sites. We investigated a link between NRS-mediated splicing inhibition and efficient polyadenylation. In vitro, the NRS alone activated a model RSV polyadenylation substrate, and while the effect did not require the snRNP-binding sites or a downstream 3' splice site, SR proteins were sufficient to stimulate polyadenylation. Consistent with this, SELEX-binding sites for the SR proteins ASF/SF2, 9G8, and SRp20 were able to stimulate polyadenylation when placed upstream of the RSV poly(A) site. In vivo, however, the SELEX sites improved polyadenylation in proviral clones only when the NRS-3' splice site complex could form. Deletions that positioned the SR protein-binding sites closer to the poly(A) site eliminated the requirement for the NRS-3' splice site interaction. This indicates a novel role for SR proteins in promoting RSV polyadenylation in the context of the NRS-3' splice site complex, which is thought to bridge the long distance between the NRS and poly(A) site. The results further suggest a more general role for SR proteins in polyadenylation of cellular mRNAs.     

Spontaneous cell proliferation is associated with poor sensitivity to glucocorticoids in patients infected with HTLV

BACKGROUND: Human T-cell lymphotropic viruses (HTLV)-I/II have a special tropism for infecting T cells and inducing spontaneous lymphocyte proliferation. Leukaemia and neurological manifestations are associated with HTLV-I/II infections, and treatment is usually based on anti-inflammatory drugs including glucocorticoids. Although steroid resistance has been reported, it is unknown whether this condition is related to the infection itself or to the treatment. OBJECTIVE: We investigated whether spontaneous cell proliferation is associated with T-cell sensitivity to glucocorticoids. MATERIALS AND METHODS: Twenty-eight HTLV-I/II patients and 11 healthy age-matched controls took part in this study. Lymphocytes were isolated and cultured in vitro to measure spontaneous and mitogen-induced proliferation as well as cellular sensitivity to dexamethasone. RESULTS: Patients with HTLV-I/II infection showed similar stimulated and unstimulated T-cell proliferation as well as comparable sensitivity to dexamethasone in vitro. There were no group differences in the frequency of glucocorticoid responders versus non-responders. However, T cells of patients with spontaneous proliferation were unresponsive to mitogenic stimulation and were remarkably more resistant to dexamethasone than cells of patients with normal proliferation. CONCLUSION: These data suggest that the poor clinical response to steroids may be associated with spontaneous cell proliferation during HTLV infection.     

Mutations at alternative 5' splice sites of M1 mRNA negatively affect influenza A virus viability and growth rate

Different amino acid sequences of influenza virus proteins contribute to different viral phenotypes. However, the diversity of the sequences and its impact on noncoding regions or splice sites have not been intensively studied. This study focuses on the sequences at alternative 5' splice sites on M1 mRNA. Six different mutations at the splice sites were introduced, and viral growth characteristics for those mutants generated by reverse genetics with 12 plasmids were examined, for which G12C (the G-to-C mutation at the first nucleotide of the intron for the mRNA3 5' splice site), C51G (at the 3' end of the exon of the M2 mRNA 5' splice site), and G146C (for the first nucleotide of the intron for mRNA4) are lethal mutations. On the other hand, mutants with the mutation G11C (at the 3' end of exon of the mRNA3 5' splice site), G52C (for the first nucleotide of the intron for M2 mRNA), or G145A (at the 3' end of the exon of mRNA4) were rescued, although they had significantly attenuated growth rates. Notably, these mutations did not change any amino acids in M1 or M2 proteins. The levels of precursor (M1 mRNA) and spliced products (M2 mRNA, mRNA3, and mRNA4) from the recombinant mutant virus-infected cells were further analyzed. The production levels of mRNA3 in cells infected with G11C, G52C, and G145A mutant viruses were reduced in comparison with that in wild-type recombinant virus-infected ones. More M2 mRNA was produced in G11C mutant virus-infected cells than in wild-type-virus-infected cells, and there was little M2 mRNA and none at all in G145A and G52C mutant virus-infected ones, respectively. Results obtained here suggest that introducing these mutations into the alternative 5' splice sites disturbed M1 mRNA splicing, which may attenuate viral growth rates.     

Pyrimidine tract binding protein and La autoantigen interact differently with the 5' untranslated regions of lentiviruses and oncoretrovirus mRNAs

Retrovirus genomic mRNA exhibits a several hundred nucleotides-long untranslated region (5' UTR) which encloses many control elements required for retrovirus replication. In addition, this 5' UTR contains translation regulatory elements, such as internal ribosome entry sites (IRESes) that have been described in oncoretroviruses, as well as in lentiviruses. UV cross-linking experiments suggested that the pyrimidine tract binding protein (PTB), a cellular protein known to regulate the activity of several picornaviral IRESes, binds to human T-cell leukemia virus (HTLV)-I RNA but not to lentiviral human immunodeficiency virus (HIV)-1, HIV-2 or simian immunodeficiency virus RNAs. To calculate the affinity of such RNA-protein interactions, we developed a new method based on the BIAcore technology. The absence of affinity of PTB for lentiviral RNAs was confirmed, whereas its affinity for HTLV-I RNAs was 1000-fold lower than for picornaviral RNAs. The BIAcore technology also revealed a significant affinity of the La autoantigen, previously described for its involvement in translational control of viral mRNAs, for HIV-1 and HTLV-I RNAs. Addition of recombinant PTB to in vitro translation experiments weakly enhanced translation initiation in the presence of HTLV-I IRES, suggesting that such an IRES requires additional trans-acting factors.     

Regulation of human T cell leukemia virus expression

Retroviruses of the type C morphology have been implicated in a wide variety of diseases in animals and humans. The human T cell leukemia viruses types I (HTLV-I) and II (HTLV-II), the prototypic human-type C retroviruses, have been identified as the causative agents of some forms of human leukemia and neurological disorders. The genetic structure and regulation of the HTLVs are more complex than their avian and murine leukemia virus counterparts. In addition to the gag, pol, and env genes that encode the characteristic virion proteins of all replication competent retroviruses, the genomes of HTLV encode the non-structural proteins, Tax and Rex, which are required for regulating viral gene expression. To understand what appears to be a complex mechanism of disease induction by HTLV, elucidating the regulation and function of the viral gene products and the interaction of these products with each other, as well as with cellular factors, will be critical. This review focuses primarily on regulation of HTLV gene expression in the infected human T lymphocyte, but also discusses analogous gene regulation by the human immunodeficiency virus (HIV). It concentrates specifically on the role these gene products play in virus replication and, ultimately, pathogenesis.     

Human T-cell leukemia virus (HTLV) type II Rex protein binds specifically to RNA sequences of the HTLV long terminal repeat but poorly to the human immunodeficiency virus type 1 Rev-responsive element.

The human T-cell leukemia viruses (HTLVs) encode a trans-regulatory protein, Rex, which differentially regulates viral gene expression by controlling the cytoplasmic accumulation of viral mRNAs. Because of insufficient amounts of purified protein, biochemical characterization of Rex activity has not previously been performed. Here, utilizing the baculovirus expression system, we purified HTLV type II (HTLV-II) Rex from the cytoplasmic fraction of recombinant baculovirus-infected insect cells by heparin-agarose chromatography. We directly demonstrated that Rex specifically bound HTLV-II 5' long terminal repeat RNA in both gel mobility shift and immunobinding assays. Sequences sufficient for Rex binding were localized to the R-U5 region of the HTLV-II 5' long terminal repeat and correlate with the region required for Rex function. The human immunodeficiency virus type 1 (HIV-1), has an analogous regulatory protein, Rev, which directly binds to and mediates its action through the Rev-responsive element located within the HIV-1 env gene. We demonstrated that HTLV-II Rex rescued an HIV-1JR-CSF Rev-deficient mutant, although inefficiently. This result is consistent with a weak binding activity to the HIV-1 Rev-responsive element under conditions in which it efficiently bound the HTLV-II long terminal repeat RNA.