Functional replacement of the HIV-1 rev protein by the HTLV-1 rex protein

Nucleolar localization of myc transcripts

In situ hybridization has revealed a striking subnuclear distribution of c-myc RNA transcripts. A major fraction of the sense-strand nuclear c-myc transcripts was localized to the nucleoli. myc intron 1-containing RNAs were noticeably absent from nucleoli, accumulating instead in the nucleoplasm. The localization of myc RNA to nucleoli was shown to be common to a number of diverse cell types, including primary Sertoli cells and several cell lines. Furthermore, nucleolar localization was not restricted to c-myc and N-myc and myoD transcripts also displayed this phenomenon. In contrast, gamma-actin or lactate dehydrogenase transcripts did not display nucleolar localization. These observations suggest a new role for the nucleolus in transport and/or turnover of potential mRNAs.

Dominant negative mutants of human T-cell leukemia virus type I Rex and human immunodeficiency virus type 1 Rev fail to multimerize in vivo

Human T-cell leukemia virus type I (HTLV-I) Rex and human immunodeficiency virus type 1 (HIV-1) Rev are essential gene products required for the replication of these two pathogenic human retroviruses. Both Rex and Rev act at a posttranscriptional level by binding to highly structured RNA-response elements, the Rex-response element in HTLV-I and the Rev-response element in HIV-1. Using a sensitive in vivo assay of protein-protein interaction, we now demonstrate that the HTLV-I Rex and HIV-1 Rev proteins readily form homomultimeric complexes in the absence of their cognate RNA-response elements yet fail to form heteromultimeric complexes with each other. Dominant negative mutations have been identified in both the rex and rev genes which presumably specify a critical activation or effector domain in each of these viral transactivators. Surprisingly, these dominant negative mutants of Rex and Rev fail to interact in vivo. These findings raise the possibility that the binding of nonfunctional monomers rather than functional multimers underlies the transdominant phenotype of these Rex and Rev mutants. Further, it seems likely that the assembly of functional and stable multimers of Rex and Rev in vivo may depend not only on the intrinsic multimerization domains of these proteins but also on the binding of a bridging cellular cofactor to the related activation domains present in each viral transactivator.

The c-rel protooncogene product represses NF-kappa B p65-mediated transcriptional activation of the long terminal repeat of type 1 human immunodeficiency virus

The long terminal repeat (LTR) of the type 1 human immunodeficiency virus (HIV-1) and the 5' regulatory region of the gene encoding the interleukin 2 receptor alpha subunit (IL-2R alpha) share functional kappa B enhancer elements involved in the regulation of these inducible transcription units during T-cell activation. These kappa B enhancer elements are recognized by a structurally related family of interactive proteins that includes p50, p65, and the product of the c-rel protooncogene (c-Rel). Recent biochemical studies have shown that p65 and p50 form the prototypical NF-kappa B complex, which is rapidly translocated from the cytoplasm to the nucleus during T-cell activation. This intracellular signaling complex potently stimulates kappa B-directed transcription from either the HIV-1 LTR or the IL-2R alpha promoter via the strong transactivation domain present in p65. We now demonstrate that nuclear expression of human c-Rel, which is induced by either phorbol ester or tumor necrosis factor alpha with delayed kinetics relative to p65, markedly represses p65-mediated activation of these transcription units. These inhibitory effects of c-Rel correlate with its DNA-binding activity but not with its ability to heterodimerize with p50, suggesting that c-Rel inhibition involves competition with p50/p65 for occupancy of the kappa B enhancer element. Together, these findings suggest that one function of c-Rel is as a physiologic repressor of the HIV-1 LTR and IL-2R alpha promoters, serving to efficiently counter the strong transcriptional activating effects of p65.

Posttranscriptional regulation by the human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex proteins through a heterologous RNA binding site

The human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex proteins induce cytoplasmic expression of incompletely spliced viral mRNAs by binding to these mRNAs in the nucleus. Each protein binds a specific cis-acting element in its target RNAs. Both proteins also associated with nucleoli, but the significance of this association is uncertain because mutations that inactivate nucleolar localization signals in Rev or Rex also prevent RNA binding. Here we demonstrate that Rev and Rex can function when tethered to a heterologous RNA binding site by a bacteriophage protein. Under these conditions, cytoplasmic accumulation of unspliced RNA occurs without the viral response elements, mutations in the RNA binding domain of Rev do not inhibit function, and nucleolar localization can be shown to be unnecessary for the biological response.

Specific binding of the human T-cell leukemia virus type I Rex protein to a short RNA sequence located within the Rex-response element

Expression of the structural proteins of human T-cell leukemia virus type I is dependent upon the interaction of the viral Rex trans activator with its highly structured cis-acting RNA target sequence, the 254-nucleotide Rex-response element. Nucleotides critical for Rex binding in vitro have been mapped by modification interference analysis to a discrete 12-nucleotide RNA sequence that is predicted to form a stem-bulge-stem structure. This minimal RNA binding site was sufficient to mediate specific Rex binding in vitro when analyzed in the context of a short RNA probe. The critical importance of this short RNA sequence in mediating Rex function in vivo is supported by its complete conservation among all primate T-cell leukemia virus isolates.

I kappa B/MAD-3 masks the nuclear localization signal of NF-kappa B p65 and requires the transactivation domain to inhibit NF-kappa B p65 DNA binding

The active nuclear form of the NF-kappa B transcription factor complex is composed of two DNA binding subunits, NF-kappa B p65 and NF-kappa B p50, both of which share extensive N-terminal sequence homology with the v-rel oncogene product. The NF-kappa B p65 subunit provides the transactivation activity in this complex and serves as an intracellular receptor for a cytoplasmic inhibitor of NF-kappa B, termed I kappa B. In contrast, NF-kappa B p50 alone fails to stimulate kappa B-directed transcription, and based on prior in vitro studies, is not directly regulated by I kappa B. To investigate the molecular basis for the critical regulatory interaction between NF-kappa B and I kappa B/MAD-3, a series of human NF-kappa B p65 mutants was identified that functionally segregated DNA binding, I kappa B-mediated inhibition, and I kappa B-induced nuclear exclusion of this transcription factor. Results from in vivo expression studies performed with these NF-kappa B p65 mutants revealed the following: 1) I kappa B/MAD-3 completely inhibits NF-kappa B p65-dependent transcriptional activation mediated through the human immunodeficiency virus type 1 kappa B enhancer in human T lymphocytes, 2) the binding of I kappa B/MAD-3 to NF-kappa B p65 is sufficient to retarget NF-kappa B p65 from the nucleus to the cytoplasm, 3) selective deletion of the functional nuclear localization signal present in the Rel homology domain of NF-kappa B p65 disrupts its ability to engage I kappa B/MAD-3, and 4) the unique C-terminus of NF-kappa B p65 attenuates its own nuclear localization and contains sequences that are required for I kappa B-mediated inhibition of NF-kappa B p65 DNA binding activity. Together, these findings suggest that the nuclear localization signal and transactivation domain of NF-kappa B p65 constitute a bipartite system that is critically involved in the inhibitory function of I kappa B/MAD-3. Unexpectedly, our in vivo studies also demonstrate that I kappa B/MAD-3 binds directly to NF-kappa B p50. This interaction is functional as it leads to retargeting of NF-kappa B p50 from the nucleus to the cytoplasm. However, no loss of DNA binding activity is observed, presumably reflecting the unique C-terminal domain that is distinct from that present in NF-kappa B p65.

Dissociation of unintegrated viral DNA accumulation from single-cell lysis induced by human immunodeficiency virus type 1

Acute cytopathic retroviral infections are accompanied by the accumulation, due to superinfection, of large amounts of unintegrated viral DNA in the cells. The cytopathic effects of human immunodeficiency virus type 1 (HIV-1) infection are specific for cells that express the CD4 viral receptor and consist of syncytium formation and single-cell lysis. Here we investigated the relationship between superinfection and single-cell lysis by HIV-1. Antiviral agents were added to C8166 or Jurkat lymphocytes after HIV-1 infection had occurred. Treatment with azidothymidine or a neutralizing anti-gp120 monoclonal antibody reduced or eliminated, respectively, the formation of unintegrated viral DNA but did not inhibit single-cell killing. Furthermore, in the infected Jurkat cells, the levels of unintegrated viral DNA peaked several days before significant single-cell lysis was observed. Essentially complete superinfection resistance was established before the occurrence of single-cell killing. These results demonstrate that single-cell lysis by HIV-1 can be dissociated from superinfection and unintegrated viral DNA accumulation. These results also indicate that single-cell killing may involve envelope glycoprotein-receptor interactions not accessible to the exterior of the cell.

trans activation of the tumor necrosis factor alpha promoter by the human T-cell leukemia virus type I Tax1 protein

In a cotransfection assay, the human T-cell leukemia virus type I Tax1 gene product specifically activated transcription from the mouse tumor necrosis factor alpha promoter. The activation patterns of 5' deletion mutants, artificial enhancer constructs, and point mutations in the promoter indicate that the major Tax1-responsive element is a site at position -655 which binds the NF-kappa B/rel and NF-GMa transcription factors.

Rapid complementation assay for anti-HIV-1 drug screening and analysis of envelope protein function

A complementation assay is described that can be used with relative safety to quantitate rapidly inhibitory effects of potential anti-HIV-1 drugs on virtually any stage of the HIV-1 life cycle by measurements of chloramphenicol acetyltransferase (CAT) activity. Of particular interest is that this system is also capable of detecting inhibition of the viral trans-activator Rev, an important potential target for drug intervention. Other applications of the system may include studies to identify domains of the envelope glycoprotein that determine infectivity and tropism or that define epitopes recognized by neutralization antibodies.

Mechanism of action of regulatory proteins encoded by complex retroviruses

Complex retroviruses are distinguished by their ability to control the expression of their gene products through the action of virally encoded regulatory proteins. These viral gene products modulate both the quantity and the quality of viral gene expression through regulation at both the transcriptional and posttranscriptional levels. The most intensely studied retroviral regulatory proteins, termed Tat and Rev, are encoded by the prototypic complex retrovirus human immunodeficiency virus type 1. However, considerable information also exists on regulatory proteins encoded by human T-cell leukemia virus type I, as well as several other human and animal complex retroviruses. In general, these data demonstrate that retrovirally encoded transcriptional trans-activators can exert a similar effect by several very different mechanisms. In contrast, posttranscriptional regulation of retroviral gene expression appears to occur via a single pathway that is probably dependent on the recruitment of a highly conserved cellular cofactor. These two shared regulatory pathways are proposed to be critical to the ability of complex retroviruses to establish chronic infections in the face of an ongoing host immune response.

The v-rel oncogene: insights into the mechanism of transcriptional activation, repression, and transformation

The v-rel oncogene product from the avian reticuloendotheliosis virus strain T corresponds to a member of the Rel-related family of enhancer-binding proteins that includes both the mammalian 50- and 65-kDa subunits of the NF-kappa B transcription factor complex. However, in contrast to NF-kappa B, v-Rel has been shown to function as a dominant-negative repressor of kappa B-dependent transcription in many mature cell types. We now demonstrate that a highly conserved motif within the Rel homology domain of v-Rel containing a consensus protein kinase A phosphorylation site is required for DNA binding, transcriptional repression, and cellular transformation mediated by this oncoprotein. However, replacement of the serine phosphate acceptor within the protein kinase A site with an alanine did not alter any of these functions of v-Rel, suggesting that phosphorylation at this site is not central to the regulation of this oncogene product. Rather, the inactive mutations appear to identify a functional domain within v-Rel required for these various biological activities. It is notable that these same mutations do not impair the ability of v-Rel to heterodimerize with the 50-kDa subunit of NF-kappa B, suggesting that v-Rel-mediated transcriptional repression likely involves direct nuclear blockade of the kappa B enhancer rather than indirect alterations in the composition of preformed cytoplasmic NF-kappa B complexes. Paradoxically, when introduced into undifferentiated F9 cells, v-Rel functions as a kappa B-specific transcriptional activator rather than as a dominant-negative repressor. These stimulatory effects of v-Rel require both the conserved protein kinase A phosphorylation site and additional unique C-terminal sequences not needed for v-Rel-mediated repression in mature cells. Retinoic acid-induced differentiation of these F9 cells restores the repressor function of v-Rel. These opposing biological actions of v-Rel occurring in cells at distinct stages of differentiation may have important implications for the mechanism of v-Rel-mediated transformation occurring in avian splenocytes.

The Rev protein of human immunodeficiency virus type 1 promotes polysomal association and translation of gag/pol and vpu/env mRNAs

Biochemical examination of the Rev-dependent expression of gag mRNAs produced from gag-Rev-responsive element (RRE) expression plasmids showed a large discrepancy between the level of cytoplasmic gag mRNA and the produced Gag protein. Significant levels of the mRNA produced in the absence of Rev were localized in the cytoplasm, while very low levels of Gag protein were produced. In the presence of Rev, the levels of mRNA increased by 4- to 16-fold, while the Gag protein production increased by 800-fold. These findings indicated that in addition to promoting nucleus-to-cytoplasm transport, Rev increased the utilization of cytoplasmic viral mRNA. Poly(A) selection and in vitro translation of cytoplasmic gag mRNA verified that the mRNA produced in the absence of Rev was functional. To analyze the translational defect in the absence of Rev, we examined the association of the cytoplasmic gag mRNA with ribosomes. gag mRNA produced in the absence of Rev was excluded from polysomes, while gag mRNA produced in the presence of Rev was associated with polysomes and produced Gag protein. These observations showed that the presence of Rev was required for efficient loading of gag mRNA onto polysomes. This effect required the presence of the RRE on the mRNA. Analysis of mRNAs produced from a rev-minus proviral clone confirmed that the presence of Rev promoted polysomal loading of both gag/pol and vpu/env mRNAs. The localization of gag mRNA was also examined by in situ hybridization. This analysis showed that in the presence of Rev, most of the gag mRNA was found in the cytoplasm, while in the absence of Rev, most of the gag mRNA was found in the nucleus and in the region surrounding the nucleus. These results suggest that a substantial fraction of the gag mRNA is retained in distinct cytoplasmic compartments in the absence and presence of Rev. These findings indicate that the presence of Rev is required along the entire mRNA transport and utilization pathway for the stabilization, correct localization, and efficient translation of RRE-containing mRNAs.

Definition of the human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex protein activation domain by functional exchange

The human retroviruses human immunodeficiency virus type 1 (HIV-1) and human T-cell leukemia virus type I (HTLV-I) are characterized by complex regulation of gene expression. Each virus encodes a posttranscriptional regulator, the 19-kDa HIV-1 Rev protein and the 27-kDa HTLV-I Rex protein, which is required for viral replication. Expression of these trans activators results in the cytoplasmic accumulation of unspliced or singly spliced viral mRNA which encode the gag, pol, and env gene products. The finding that the HTLV-I Rex protein is able to functionally substitute for the Rev protein of HIV-1 indicates that HIV-1 Rev and HTLV-I Rex may interact with the same component of a cellular pathway involved in either mRNA splicing or transport. In this study, we have generated functional Rev/Rex hybrid proteins by domain exchange. We have defined, using in vivo and in vitro analyses, the activation domains of Rev and Rex which are the putative targets of a common host cell factor(s) required for Rev and Rex function.

The Rev protein of human immunodeficiency virus type 1 promotes polysomal association and translation of gag/pol and vpu/env mRNAs

Biochemical examination of the Rev-dependent expression of gag mRNAs produced from gag-Rev-responsive element (RRE) expression plasmids showed a large discrepancy between the level of cytoplasmic gag mRNA and the produced Gag protein. Significant levels of the mRNA produced in the absence of Rev were localized in the cytoplasm, while very low levels of Gag protein were produced. In the presence of Rev, the levels of mRNA increased by 4- to 16-fold, while the Gag protein production increased by 800-fold. These findings indicated that in addition to promoting nucleus-to-cytoplasm transport, Rev increased the utilization of cytoplasmic viral mRNA. Poly(A) selection and in vitro translation of cytoplasmic gag mRNA verified that the mRNA produced in the absence of Rev was functional. To analyze the translational defect in the absence of Rev, we examined the association of the cytoplasmic gag mRNA with ribosomes. gag mRNA produced in the absence of Rev was excluded from polysomes, while gag mRNA produced in the presence of Rev was associated with polysomes and produced Gag protein. These observations showed that the presence of Rev was required for efficient loading of gag mRNA onto polysomes. This effect required the presence of the RRE on the mRNA. Analysis of mRNAs produced from a rev-minus proviral clone confirmed that the presence of Rev promoted polysomal loading of both gag/pol and vpu/env mRNAs. The localization of gag mRNA was also examined by in situ hybridization. This analysis showed that in the presence of Rev, most of the gag mRNA was found in the cytoplasm, while in the absence of Rev, most of the gag mRNA was found in the nucleus and in the region surrounding the nucleus. These results suggest that a substantial fraction of the gag mRNA is retained in distinct cytoplasmic compartments in the absence and presence of Rev. These findings indicate that the presence of Rev is required along the entire mRNA transport and utilization pathway for the stabilization, correct localization, and efficient translation of RRE-containing mRNAs.

HIV regulatory proteins: potential targets for therapeutic intervention

With the incidence of HIV infection on the rise worldwide, it is obvious that new approaches must be taken to halt the spread of disease. Unfortunately, this is no easy task; of all retroviruses studied to date HIV remains the most complex in terms of genomic organization, regulation of gene expression, and replication. However, as the mechanism of action of the unique viral regulatory proteins is deciphered, new windows of opportunity for attacking the virus like cycle are opened. The essential regulatory function served by both Tat and Rev transacting regulatory proteins makes them attractive targets for prophylactic and therapeutic intervention. This review will focus on our current understanding of Tat and Rev function.

Extensive sequence-specific information throughout the CAR/RRE, the target sequence of the human immunodeficiency virus type 1 Rev protein

The significance and location of sequence-specific information in the CAR/RRE, the target sequence for the Rev protein of the human immunodeficiency virus type 1 (HIV-1), have been controversial. We present here a comprehensive experimental and computational approach combining mutational analysis, phylogenetic comparison, and thermodynamic structure calculations with a systematic strategy for distinguishing sequence-specific information from secondary structural information. A target sequence analog was designed to have a secondary structure identical to that of the wild type but a sequence that differs from that of the wild type at every position. This analog was inactive. By exchanging fragments between the wild-type sequence and the inactive analog, we were able to detect an unexpectedly extensive distribution of sequence specificity throughout the CAR/RRE. The analysis enabled us to identify a critically important sequence-specific region, region IIb in the Rev-binding domain, strongly supports a proposed base-pairing interaction in this location, and places forceful constraints on mechanisms of Rev action. The generalized approach presented can be applied to other systems.

Inhibition of human immunodeficiency virus type 1 Rev-Rev-response element complex formation by complementary oligonucleotides

Complementary 18-mer oligodeoxynucleotides (oligonucleotides) specifically inhibited the formation of human immunodeficiency virus Rev-Rev-response element (RRE) complexes. Inhibition of Rev-RRE binding required blockage of G-7819 to G-7820 in band shift assays. Structural studies revealed both local and distal effects. RRE structure was also disrupted by oligonucleotides targeted to other minor stems, by altering RNA renaturation conditions, or by reducing Rev concentrations--indicating a dynamic RRE structure and involvement of a minor RRE stem in the maturation of initial Rev-RRE complexes. Thus, complementary oligonucleotides alter RRE structure and may prove useful for the design of therapeutic anti-RRE oligonucleotides.

Functional mapping of the human immunodeficiency virus type 1 Rev RNA binding domain: new insights into the domain structure of Rev and Rex

Expression of human immunodeficiency virus type 1 (HIV-1) structural proteins requires the direct interaction of the viral trans-activator protein Rev with its cis-acting RNA sequence (Rev-response element [RRE]). A stretch of 14 amino acid residues of the 116-amino-acid Rev protein is sufficient to impose nucleolar localization onto a heterologous protein. Our results demonstrated that these same amino acid residues confer Rev-specific RRE binding to the heterologous human T-cell leukemia virus type I Rex protein. In addition, our results indicated that amino acids distinct from the nuclear localization signal are important for Rex-specific RRE RNA binding.

Effector domains of human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex are functionally interchangeable and share an essential peptide motif

The human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex transactivators are posttranscriptional regulatory proteins that promote retroviral gene expression by interacting with specific viral mRNAs. Rev and Rex have markedly dissimilar amino acid sequences and RNA target specificities but are thought to act through the same cellular pathway. In this report, we demonstrate that short peptide domains which are required for effector activity in Rev and Rex are functionally interchangeable. Activity of these effector domains depends upon a previously unrecognized tetrapeptide motif that is present in both Rev and Rex and also in analogous proteins from other complex retroviruses. The conserved effector motif may mediate essential interactions of Rev, Rex, and other transactivators of this type with a common cellular cofactor.

Lethal neurotoxicity in mice of the basic domains of HIV and SIV Rev proteins. Study of these regions by circular dichroism

We have recently reported a basic domain-mediated neurotoxic activity of HIV-1 Tat [1991, J. Virol. 65, 961-965]. Here we have tested the neurotoxicity in vivo of several Rev-related synthetic peptides and found that only those mimicking the basic regions of Rev from HIV-1, HIV-2 and SIV were lethal to mice. In contrast, the homologous domain of HTLV-1 Rex was found to be inactive for lethal activity. Analysis of the tropism of these peptides for phospholipids has demonstrated a direct interaction of the basic domain-containing peptides, except Rex, with acidic--but not neutral--phospholipids. As determined by circular dichroism, a possible correlation between the conformation of the basic regions and the toxicity is discussed.

Functional conversion from HIV-1 Rev to HTLV-1 Rex by mutation

A nucleolar localizing rev gene mutant M10 of human immunodeficiency virus type 1 (HIV-1) lost a Rev function completely, instead, gained a Rex activity of human T cell leukemia virus type 1 (HTLV-1). The obtained compatibility between Rev M10 and Rex with their own nucleolar targeting signal (NOS) suggests a common molecular mechanism of their post-transcriptional regulation, despite no sequence similarities of both proteins and their responsive RNA elements, respectively.

The Rex regulatory protein of human T-cell lymphotropic virus type I binds specifically to its target site within the viral RNA

The Rex protein of human T-cell leukemia virus type I (HTLV-I) was expressed in bacteria and partially purified. Rex was shown to bind in vitro specifically to an RNA sequence located in the 3' long terminal repeat of HTLV-I, named Rex-responsive element (RXRE). Rex also bound in vitro to the human immunodeficiency virus type 1 (HIV-1) Rev-responsive element (RRE), while purified HIV-1 Rev protein did not bind to the RXRE. The binding results obtained in vitro are therefore in agreement with the nonreciprocal function of Rev and Rex in vivo. Rex binds specifically to both RRE and RXRE and activates expression in both HIV-1 and HTLV-I, while Rev binds to RRE and activates only HIV-1. Binding of Rex to RRE deletion mutants previously shown to lack either the Rev-responsive or the Rex-responsive portion suggested preferential binding of Rex to a distinct target within the RRE. These results demonstrated that Rex, like Rev, acts by binding to a specific RNA target.

Mutational analysis of functional domains in the HIV-1 Rev trans-regulatory protein

HIV-1 replication depends on the expression of trans-regulatory genes (tat, rev) encoded in the 3' part of the retroviral genome. HIV-1 Rev trans-activator protein allows the cytoplasmic translocation of incompletely spliced retroviral mRNA which is required for the translational switch from regulatory (Tat, Rev, Nef) to structural proteins (Gag, Pol, Env). The HIV-1 Rev regulatory protein comprises an activation domain (RAD) and a RNA binding domain (RBD). Both functional domains are not well defined and the RBD appears to overlap with the nuclear localization signal (NLS). Our mutational analysis localized the Rev protein domain important for RRE (nucleotide 7781 to 8000) binding in vitro to amino acid residues 31 to 50. Mutations in this domain always resulted in exclusion from the nucleoli. Furthermore, these mutants did not support Rev-dependent p24 Gag production in vivo. Sequences immediately upstream of this domain (RevM4, RevM19) were attenuated in their in vivo activity possibly indicating a role in Rev protein oligomerization. The observed tight correlation between subcellular localization and RNA binding in vitro indicates that this short stretch of amino acids supports two essential functions required for HIV-1 replication.

Functional analysis of human T-cell leukemia virus type I rex-response element: direct RNA binding of Rex protein correlates with in vivo activity

The human T-cell leukemia virus type I rex gene product plays a critical role in the expression of the retroviral structural proteins Gag and Env from incompletely spliced mRNAs. Rex protein acts through a cis element (rex-response element [RxRE]) which is located in the U3/R region of the 3' long terminal repeat and is present on all human T-cell leukemia virus type I-specific mRNAs. Two domains of the predicted secondary structure of the RxRE are crucially important for Rex action in vivo as measured by two assay systems. In vitro studies using highly purified recombinant Rex protein revealed a specific and direct interaction with radiolabeled RxRE sequences. The correlation between our in vivo results and the direct binding of Rex protein to mutant and wild-type RxRE sequences supports both the existence of the predicted secondary structure and the importance of this direct interaction with the cis-acting RNA sequence for Rex function in vivo.

The type I human T-cell leukemia virus (HTLV-I) Rex trans-activator binds directly to the HTLV-I Rex and the type 1 human immunodeficiency virus Rev RNA response elements

The Rex protein of the type I human T-cell leukemia virus (HTLV-I) is essential for the replication of this pathogenic retrovirus and, surprisingly, can also replace the function of the structurally distinct Rev protein of the type 1 human immunodeficiency virus (HIV-1). Rex action requires a 255-nucleotide viral RNA stem-loop structure termed the Rex RNA response element (RexRE) located in the 3' retroviral long terminal repeat. Rex function leads to the induced cytoplasmic expression of the incompletely spliced family of viral mRNAs that uniquely encode the HTLV-I structural and enzymatic proteins (Gag, Pol, and Env). Our studies now demonstrate that Rex acts by binding directly to the RexRE in a sequence-specific manner. These effects of Rex require the presence of a 10-nucleotide subregion of the RexRE that is essential for Rex function in vivo. Dominant-negative mutants of Rex also bind to the RexRE with high affinity, while a recessive-negative Rex mutant altered within its arginine-rich, positively charged domain fails to engage the RexRE. Analogously, both the wild-type and dominant-negative Rex proteins specifically bind to the structurally distinct HIV-1 Rev response element, a finding that likely underlies the respective stimulatory and inhibitory effects of these HTLV-I proteins in the heterologous HIV-1 system. However, consistent with their lack of amino acid homology, the binding sites for Rex and Rev within the HIV-1 Rev response element are distinct.

Mutational analysis of the human T-cell leukemia virus type I trans-acting rex gene product

Expression of the human T-cell leukemia virus type I (HTLV-I) rex gene is a prerequisite for the expression of the retroviral structural proteins. We have generated internal deletion mutants of this 27-kDa nucleolar trans-acting gene product to define functional domains in the Rex protein. The phenotype of the various mutant proteins was tested on the homologous HTLV-I rex response element sequence and the heterologous human immunodeficiency virus type 1 (HIV-1) rev response element sequence. Our results indicate that a region between amino acid residues 55 and 132 in the 189-amino-acid Rex protein is required for Rex-mediated trans activation on both retroviral response element sequences. In addition, substitution of the Rex nuclear localization signal by a sequence of the HIV-1 rev gene product targets the Rex protein to the correct subcellular compartment required for Rex function.

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.

Characterization of the transcriptional trans activator of human foamy retrovirus

The human foamy viruses, or spumaviruses, a distinct subfamily of complex human retroviruses, remain poorly understood both in terms of their pathogenic potential and in terms of the regulatory mechanisms that govern their replication. Here, we demonstrate that the human spumaretrovirus shares with other complex human retroviruses the property of encoding a transcriptional trans activator of the homologous viral long terminal repeat. This regulatory protein is encoded by the viral Bel-1 open reading frame and is localized to the nucleus of expressing cells. The Bel-1 trans activator is shown to function effectively in cell lines derived from human, simian, murine, and avian sources. The viral target sequence for Bel-1 has been mapped 5' to the start of viral transcription and is therefore likely to be recognized as a DNA sequence. Our results further suggest that the mechanism of action of the Bel-1 protein may be distinct from those reported for the transcriptional trans activators encoded by members of the other human retroviral subfamilies.

Effects of chimeric mutants of human immunodeficiency virus type 1 Rev and human T-cell leukemia virus type I Rex on nucleolar targeting signals

Two chimeric mutant genes derived from rev of human immunodeficiency virus type 1 and rex of human T-cell leukemia virus type I were constructed to investigate the functions of the nucleolar-targeting signals (NOS) in Rev and Rex proteins. A chimeric Rex protein whose NOS region was substituted with the NOS of Rev was located predominantly in the cell nucleolus and functioned like the wild-type protein in the Rex assay system. However, a chimeric Rev with the NOS of Rex abolished Rev function despite its nucleolar localization. This nonfunctional nucleolar-targeting chimeric protein inhibited the function of both Rex and Rev. In the same experimental conditions, this mutant interfered with the localization of the functional Rex in the nucleolus.

The occurrence of opportunistic non-Hodgkin's lymphomas in the setting of infection with the human immunodeficiency virus

The incidence of non-Hodgkin's lymphoma (NHL) has increased by over 50% in the United States since 1973. There is epidemiologic evidence that some of this increase is the result of AIDS-related lymphoma and that this component is increasing. Prolonged survival in the setting of a variety of immunodeficiency states is associated with an increased incidence of NHL. The development of antiretroviral therapy and improved therapy for the complications of AIDS has resulted in prolonged survival of patients with AIDS. As these patients survive longer with profound immunodeficiency, they have an increased cumulative risk of developing NHL. This may result in even more AIDS-related NHL in the future than predicted from current epidemiological studies. An increased understanding of the pathogenesis of AIDS-related NHL may lead to means of preventing their occurrence. Also, therapies that may prevent immunodeficiency from developing in HIV-infected patients may reduce the likelihood of NHL developing. Current efforts at treating these lymphomas are aimed at preventing the myelosuppression and immunosuppression associated with current regimens, lymphoma relapses within the central nervous system, and the opportunistic infections associated with treatment of these tumors. Ultimately, the best means of preventing the development of these lymphomas is by preventing infection with HIV.

Rex transregulation of human T-cell leukemia virus type II gene expression

The Rex protein of the human T-cell leukemia virus type II (HTLV-II), Rex-II, plays a central role in regulating the expression of the structural genes of this retrovirus. Rex-II acts posttranscriptionally by inducing the cytoplasmic expression of the incompletely spliced viral mRNAs that encode the Gag and Env structural proteins and the enzymes derived from the pol gene. We now define a 295-nucleotide cis-acting regulatory element within the 3' long terminal repeat of HTLV-II that is required for the effects of Rex-II. This Rex-II response element (RexIIRE) corresponds to a predicted, highly stable RNA secondary structure and functions when present in the sense but not in the antisense orientation. The RexIIRE confers responsiveness not only to Rex-II but also to the Rex protein of HTLV-I. Deletion and substitution mutagenesis of the RexIIRE permitted identification of a small subregion within the larger element critically required for Rex-II responsiveness and further suggested that the structurally distinct RexIIREs generated from the 5' and 3' long terminal repeats of HTLV-II may differentially regulate the cytoplasmic expression of unspliced gag-pol and singly spliced env mRNAs. While the Rev protein of human immunodeficiency virus type 1 fails to function via the RexIIRE, the Rex-II protein, like Rex-I, can functionally replace the Rev protein of human immunodeficiency virus type 1 via its interaction with the Rev response element (RevRE).

Attenuation of human immunodeficiency virus type 1 cytopathic effect by a mutation affecting the transmembrane envelope glycoprotein

The cytopathic effects of human immunodeficiency virus type 1 (HIV-1) infection are specific for cells that express the CD4 viral receptor and consist of syncytium formation and single-cell lysis. Here we report that a mutation (517A) affecting the amino terminus of the HIV-1 gp41 transmembrane envelope glycoprotein resulted in a virus that was markedly less cytopathic than was wild-type HIV-1. In systems in which cell-to-cell transmission of HIV-1 occurred, the replication ability of the 517A virus was comparable with that of the wild-type virus. Even though the levels of viral protein expression, virion production, and interaction of the envelope glycoproteins with CD4 were similar for the 517A and wild-type viruses, both syncytium formation and single-cell lysis were attenuated for the 517A mutant virus. These results demonstrate that an envelope glycoprotein region important for mediating post-receptor binding events in cell membrane fusion is important for the induction of cytopathic effects by HIV-1. These results also indicate that levels of HIV-1 viral proteins or viral particles produced in infected cells are in themselves not sufficient to induce cytopathic effects.

Transdominant repressors for human T-cell leukemia virus type I rex and human immunodeficiency virus type 1 rev function

Human T-cell leukemia virus type I (HTLV-I) encodes a 27-kDa trans-acting gene product (Rex) which is involved in the regulated expression of transcripts coding for the viral structural proteins. We used oligonucleotide-directed mutagenesis to generate a series of mutant HTLV-I rex genes. Transient expression experiments demonstrated that 3 of 28 mutant proteins are functionally inactive on the homologous HTLV-I rex response element, whereas an additional 2 mutant proteins are functionally inactive on the heterologous human immunodeficiency virus type 1 rev response element. One of these mutants is able to suppress the function of the wild-type HTLV-I Rex protein in trans on the homologous rex response element sequence. Furthermore, all of these mutants are able to inhibit Rex function on the heterologous rev response element sequence. Intriguingly, only three of these mutants are able to inhibit the human immunodeficiency virus type 1 Rev protein in a dominant-negative manner.

Human immunodeficiency virus rev protein recognizes a target sequence in rev-responsive element RNA within the context of RNA secondary structure

Human immunodeficiency virus type 1 Rev protein modulates the distribution of viral mRNAs from the nucleus to the cytoplasm by interaction with a highly structured viral RNA sequence, the Rev-responsive element (RRE). To identify the minimal functional elements of RRE, we evaluated mutant RREs for Rev binding in vitro and Rev response in vivo in the context of a Gag expression plasmid. The critical functional elements fold into a structure composed of a stem-loop A, formed by the ends of the RRE, joined to a branched stem-loop B/B1/B2, between bases 49 and 113. The 5' 132 nucleotides of RRE, RREDDE, which possessed a similar structure, bound Rev efficiently but were nonfunctional in vivo, implying separate binding and functional domains within the RRE. Excision of stem-loop A reduced Rev binding significantly and abolished the in vivo Rev response. The B2 branch could be removed without severe impairment of binding, but deletions in the B1 branch significantly reduced binding and function. However, deletion of 12 nucleotides, including the 5' strand of stem B, abolished both binding and function, while excision of the 3' strand of stem B only reduced them. Maintenance of the native RRE secondary structure alone was not sufficient for Rev recognition. Many mutations that altered the primary structure of the critical region while preserving the original RNA conformation were Rev responsive. However, mutations that changed a 5'..CACUAUGGG..3' sequence in the B stem, without affecting the overall structure abolished both in vitro Rev binding and the in vivo Rev response.

Different sites of interaction for Rev, Tev, and Rex proteins within the Rev-responsive element of human immunodeficiency virus type 1

We have analyzed the action of the Rev and Tev proteins of human immunodeficiency virus type 1 (HIV-1) and of the Rex protein of human T-cell leukemia virus type I (HTLV-I) on a series of Rev-responsive element (RRE) mutants. The minimum continuous RRE region necessary and sufficient for Rev function was determined to be 204 nucleotides. Interestingly, this region was not sufficient for Tev or Rex function. These proteins require additional sequences, which may stabilize the structure of the RRE or may contain additional sequence-specific elements. Internal RRE deletions revealed that the targets for Rev and Rex can be separated, since mutants responding to Rev and not Rex and vice versa were identified. Tev was active on both types of mutants, suggesting that it has a more relaxed specificity than do both Rev and Rex proteins. Although Rev and Rex targets within the RRE appear to be distinct, the trans-dominant mutant RevBL prevents the RRE interaction with Rex. RevBL cannot inhibit the function of Rex on RRE deletions that lack the Rev-responsive portion. These results indicate the presence of distinct sites within the RRE for interaction with these proteins. The binding sites for the different proteins do not function independently and may interfere with one another. Mutations affecting the RRE may change the accessibility and binding characteristics of the different binding sites.

Functional comparison of transactivation by human retrovirus rev and rex genes

The effect of rev-responsive element deletion on human immunodeficiency virus type 1 (HIV-1) and type 2 (HIV-2) gene expression was examined. The phenotypes of HIV-1 and HIV-2 provirus DNAs lacking the rev-responsive element, as determined by transfection experiments, were indistinguishable from those of virus DNAs carrying rev gene mutations. By using rev-response elements derived from these two viruses, we developed two monitoring systems to evaluate the functionality of HIV-1 rev, HIV-2 rev, and human T-lymphotropic virus type I rex. In both systems, HIV-1 rev and human T-lymphotropic virus type I rex transactivated HIV-2 very efficiently. On the contrary, HIV-2 rev and human T-lymphotropic virus type I rex were poor activators of HIV-1. No functional replacement of rex by HIV-2 rev was observed.

The v-rel oncogene encodes a kappa B enhancer binding protein that inhibits NF-kappa B function

Studies of NF-kappa B suggest that this enhancer binding activity corresponds to a family of at least four proteins (p50, p55, p75, and p85) differentially induced with biphasic kinetics during T cell activation. While p55 and p50 are closely related to the 50 kd DNA binding subunit of NF-kappa B, p75 and p85 exhibit DNA binding properties that distinguish them from this 50 kd polypeptide and its regulatory subunits I kappa B and p65. All four members of this kappa B-specific protein family are structurally related to the v-Rel oncoprotein and one, p85, appears identical to human c-Rel. v-Rel, but not nontransforming v-Rel mutants, binds to the kappa B enhancer and inhibits NF-kappa B-activated transcription from the IL-2 receptor alpha promoter and HIV-1 LTR. These findings suggest a Rel-related family of kappa B enhancer binding proteins and raise the possibility that the transforming activity of v-Rel is linked to its inhibitory action on cellular genes under NF-kappa B control.

Mutational analysis of the human immunodeficiency virus type 1 Rev transactivator: essential residues near the amino terminus

The expression of certain mRNAs from human immunodeficiency virus type 1 (HIV-1) is controlled by the viral transactivator Rev, a nucleolar protein that binds a cis-acting element in these mRNAs. Rev is encoded by two viral exons that specify amino acids 1 to 26 and 27 to 116, respectively. Earlier studies have mapped essential regions of the protein that are encoded in the second exon. By further mutational analysis of Rev, we have now identified a novel locus encoded by the first exon that also is essential for transactivation in vivo. Defined by mutations at residues 14 to 20, this locus coincides with a cluster of positively charged and nonpolar amino acids that is conserved in Rev proteins of all known primate immunodeficiency viruses. Rev proteins that contained mutations at this site were defective in both nuclear localization and transactivation and did not function as trans-dominant inhibitors of wild-type Rev. Fusion of these mutants to a heterologous nuclear protein complemented the defect in localization but did not restore biological activity. Our findings suggest that this N-terminal locus may play a direct role in transactivation, perhaps contributing to essential protein-protein interactions or forming part of the RNA-binding domain of Rev.

Visna virus encodes a post-transcriptional regulator of viral structural gene expression

Visna virus is an ungulate lentivirus that is distantly related to the primate lentiviruses, including human immunodeficiency virus type 1 (HIV-1). Replication of HIV-1 and of other complex primate retroviruses, including human T-cell leukemia virus type I (HTLV-I), requires the expression in trans of a virally encoded post-transcriptional activator of viral structural gene expression termed Rev (HIV-1) or Rex (HTLV-I). We demonstrate that the previously defined L open reading frame of visna virus encodes a protein, here termed Rev-V, that is required for the cytoplasmic expression of the incompletely spliced RNA that encodes the viral envelope protein. Transactivation by Rev-V was shown to require a cis-acting target sequence that coincides with a predicted RNA secondary structure located within the visna virus env gene. However, Rev-V was unable to function by using the structurally similar RNA target sequences previously defined for Rev or Rex and, therefore, displays a distinct sequence specificity. Remarkably, substitution of this visna virus target sequence in place of the HIV-1 Rev response element permitted the Rev-V protein to efficiently rescue the expression of HIV-1 structural proteins, including Gag, from a Rev- proviral clone. These results suggest that the post-transcriptional regulation of viral structural gene expression may be a characteristic feature of complex retroviruses.

Function of the human immunodeficiency virus types 1 and 2 Rev proteins is dependent on their ability to interact with a structured region present in env gene mRNA

The interaction of the human immunodeficiency virus type 1 (HIV-1) Rev protein with a structured region in env mRNA (the Rev-responsive element [RRE]) mediates the export of structural mRNAs from the nucleus to the cytoplasm. We demonstrated that unlike HIV-1 Rev, which functions with both the HIV-1 and HIV-2 RREs, HIV-2 Rev functions only with the HIV-2 RRE. Rev-RRE binding studies suggested that the lack of nonreciprocal complementation stems from the inability of HIV-2 Rev to interact with HIV-1 RRE RNA. Maintenance of RNA secondary structure, rather than the primary nucleotide sequence, appeared to be the major determinant for interaction of both HIV-1 and HIV-2 Rev with the HIV-2 RRE. Moreover, the binding domain of the HIV-2 RRE recognized by HIV-1 Rev was dissimilar to the binding domain of the HIV-1 RRE, in terms of both secondary structure and primary nucleotide sequence. Our results support the hypothesis that function of HIV Rev proteins and possibly the functionally similar Rex proteins encoded by the human T-cell leukemia viruses (HTLVs) HTLV-I and HTLV-II is controlled by the presence of RNA secondary structure generated within the RRE RNA.

Interaction of the human immunodeficiency virus type 1 Rev protein with a structured region in env mRNA is dependent on multimer formation mediated through a basic stretch of amino acids

Interaction of the human immunodeficiency virus type 1 (HIV-1) Rev protein with a structured region within env mRNA (termed RRE) mediates the export of virus structural mRNAs from the nucleus to the cytoplasm. We show that the region encompassing the basic stretch of amino acids is essential for the ability of Rev to bind to RRE RNA and function in vivo. By use of a functional truncated Rev protein in conjunction with authentic Rev, effects on gel mobilities of the Rev-RRE RNA complex attributable to multimerization of Rev protein were observed. Rev proteins, unable to multimerize, failed to bind RRE RNA. Identification of Rev mutants capable of forming multimers, but unable to bind RRE RNA, suggests that the multimerization and RNA-binding domains can be distinguished and that multimerization is likely a prerequisite for formation of the RRE RNA-binding site. A mutant Rev protein, shown previously to function as a trans-dominant inhibitor of Rev function, bound to RRE RNA as a multimer to a similar extent as wild-type Rev. This observation is consistent with the hypothesis that regulation of HIV gene expression by Rev involves the interaction with cellular factors and that the trans-dominant Rev is probably defective in this function.

Cloning and characterization of cDNAs encoding equine infectious anemia virus tat and putative Rev proteins

We isolated and characterized six cDNA clones from an equine infectious anemia virus-infected cell line that displays a Rev-defective phenotype. With the exception of one splice site in one of the clones, all six cDNAs exhibited the same splicing pattern and consisted of four exons. Exon 1 contained the 5' end of the genome; exon 2 contained the tat gene from mid-genome; exon 3 consisted of a small section of env, near the 5' end of the env gene; and exon 4 contained the putative rev open reading frame from the 3' end of the genome. The structures of the cDNAs predict a bicistronic message in which Tat is encoded by exons 1 and 2 and the presumptive Rev protein is encoded by exons 3 and 4. tat translation appears to be initiated at a non-AUG codon within the first 15 codons of exon 1. Equine infectious anemia virus-specific tat activity was expressed in transient transfections with cDNA expression plasmids. The predicted wild-type Rev protein contains 30 env-derived amino acids and 135 rev open reading frame residues. All of the cDNAs had a frameshift in exon 4, leading to a truncated protein and thus providing a plausible explanation for the Rev-defective phenotype of the original cells. We used peptide antisera to detect the faulty protein, thus confirming the cDNA sequence, and to detect the normal protein in productively infected cells.

Feedback regulation of human immunodeficiency virus type 1 expression by the Rev protein

Rev is an essential regulatory protein of the human immunodeficiency virus type 1 (HIV-1) that affects the transport and half-life of certain viral mRNAs. Rev exerts its function via a unique element, the Rev-responsive element (RRE), located within the env region of HIV-1. It has been previously demonstrated that Rev affects the relative levels of RRE-containing and RRE-lacking mRNAs. We have studied the effects of Rev on the expression of the three different groups of small, multiply spliced mRNAs that lack the RRE sequence and encode the regulatory proteins Tat, Rev, and Nef. To monitor the tat, rev, and nef mRNAs we generated specific S1 nuclease mapping probes that distinguish among them. Analysis of all the mRNA species producing Tat, Rev, and Nef revealed that their levels are coordinately regulated by Rev. They are increased in the absence of Rev protein and are down regulated in the presence of Rev. The corresponding proteins were measured by immunoprecipitations, and their levels are in agreement with the RNA levels. These results verify the model proposing that Rev is a general regulator indirectly affecting all the multiply spliced mRNAs to a similar extent. Therefore, Rev down regulates its own expression and the expression of Tat and Nef.

Structure-function analyses of the HTLV-I Rex and HIV-1 Rev RNA response elements: insights into the mechanism of Rex and Rev action

The ability of the Rex protein of the type I human T-cell leukemia virus (HTLV-I) to regulate expression of the retroviral gag and env structural genes post-transcriptionally is critically dependent on the presence of a Rex response element (RexRE). This cis-regulatory sequence is located within the retroviral 3' long terminal repeat and coincides with a predicted, highly stable RNA stem-loop structure. Rex action requires both the overall secondary structure intrinsic to the RexRE and specific sequences from one small subregion of this large structure. This small subregion likely forms a protein-binding site for Rex or a cellular RNA-binding factor. Whereas Rex can functionally replace the Rev protein of the type 1 human immunodeficiency virus (HIV-1) through its interaction with the analogous Rev response element (RevRE), distinct subregions of this HIV-1 RNA element mediate the responses to Rex and Rev. Strikingly, Rex acts as a dominant repressor of Rev action, following the deletion of the Rex responsive subregion of the RevRE. Similarly, Rev inhibits Rex function in a dominant manner when the Rev responsive subregion of the RevRE is deleted. Together, these findings suggest that Rex and Rev not only interact with their respective RNA response elements but also may either form mixed inactive multimers or interact with a common cellular factor(s). If binding of a common host protein is involved, this factor likely plays a central role either in spliceosome assembly or nuclear RNA transport.

Secondary structure of the human T-cell leukemia virus type 1 rex-responsive element is essential for rex regulation of RNA processing and transport of unspliced RNAs

Rex protein of human T-cell leukemia virus type 1 (HTLV-1) induces cytoplasmic expression of unspliced gag/pol mRNA and singly spliced env mRNA and thus is essential for replication of the virus. This regulation requires a cis-acting rex-responsive element (RXE), located in the 3' region of the viral RNA. By external deletion, we have identified RXE composed of 205 nucleotides. The secondary structure of RXE was confirmed by studies on its susceptibility to nuclease digestions to consist of four stem-loops and a long stretch of stem structure. Substitution and deletion mutations revealed that two regions of the stem-loops and their secondary structures are essential for rex regulation. Similar secondary structures were found in the corresponding regions of HTLV-2, bovine leukemia virus and human immunodeficiency virus. Furthermore, a sequence of 11 nucleotides in the RXE was found to be conserved in the secondary structures of HTLV-1, HTLV-2, and bovine leukemia virus. These observations suggest that the secondary structure as well as the conserved sequence may be important in expression of unspliced RNA even with diverged sequences as observed in these viruses.