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.

The HTLV-I Rex response element mediates a novel form of mRNA polyadenylation.

HTLV-I structural gene expression is posttranscriptionally regulated by the Rex protein and the Rex response element (RexRE), a 255 nucleotide RNA stem-loop structure located in the retroviral 3' LTR. Independent of Rex, the RexRE also plays a critical role in the polyadenylation of all HTLV-I transcripts. Folding of the RexRE serves to spatially juxtapose the widely separated AAUAAA hexamer and GU-rich elements that are essential for polyadenylation. In turn, this folding promotes the cooperative and stable binding of two nuclear factors at these elements that commits this poly(A) site to 3' processing. These findings highlight a novel mechanism of 3' end formation in the HTLV family of retroviruses and underscore the general requirement for protein-protein interactions in the polyadenylation reaction.

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).

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.

Comparative analysis of the HTLV-I Rex and HIV-1 Rev trans-regulatory proteins and their RNA response elements.

The Rex proteins of types I and II human T-cell leukemia viruses (HTLV-I, HTLV-II) are required for expression of the viral structural gene products, gag and env and, thus, are essential for the replication of these pathogenic retroviruses. The action of Rex is sequence specific, requiring the presence of a cis-acting Rex response element located in the 3' long terminal repeat. This element corresponds to a predicted RNA secondary structure and functions in an orientation-dependent but position-independent manner. Rex acts through this response element to stimulate the nuclear export of the unspliced or singly spliced viral mRNA species encoding the virion structural proteins that are normally excluded from the cytoplasm. Although the Rex proteins of HTLV-I and HTLV-II can also function via the related Rev response element present in the env gene of the type I human immunodeficiency virus (HIV-1), the analogous HIV-1 Rev protein is unable to act on the HTLV-I Rex response element. This nonreciprocal pattern of genetic complementation by Rex and Rev suggests that these viral trans-regulators may interact directly with their RNA response elements.

Distinct transcription factors bind specifically to two regions of the human histone H4 promoter.

Two proteins specifically binding to separate regions of the human histone H4 promoter were identified in nuclear extracts prepared from synchronized S-phase HeLa cells. Competition experiments with H4 promoter mutants and DNase protection assays ("footprinting") demonstrate that these factors bind to regions of the H4 promoter that are essential for maximal expression in vitro. One of these factors (H4TF-1) binds to sequences between -80 and -110 base pairs upstream of the H4 cap site, whereas the other (H4TF-2) binds to the H4 subtype-specific sequence element immediately upstream from the "TATA" homology. Neither of these activities can efficiently bind to any of the other histone gene subtypes or simian virus 40 DNA. Binding of H4TF-1 to the distal region of the pHu4A histone H4 promoter is inhibited competitively with varying efficiency by four of six human histone H4 genes cloned in this laboratory, whereas efficient competition for binding of H4TF-2 is exhibited by five of the six H4 genes. Since both of these factors bind to significant regions of the pHu4A histone H4 promoter and can be bound by several different human H4 genes, we believe that they are important for maximal transcription of the gene and that they may be involved in its regulated expression during the cell cycle.

Identification of promoter elements necessary for transcriptional regulation of a human histone H4 gene in vitro.

We have examined the nucleotide sequences necessary for transcription of a human histone H4 gene in vitro. Maximal transcription of the H4 promoter requires, in addition to the TATA box and cap site, promoter elements between 70 and 110 nucleotides upstream from the transcription initiation site. These distal promoter elements are recognized preferentially in extracts from synchronized S-phase HeLa cells. The inability of non-S-phase nuclear extracts to recognize the H4 upstream sequences reflects a specific lack of a transcription factor which interacts with those sequences. These results indicate that the cell cycle regulation of human histone gene expression involves both a specific transcription factor and distal transcription signals in the H4 promoter.