Oral immune dysfunction is associated with the expansion of FOXP3+PD-1+Amphiregulin+ T cells during HIV infection

Residual systemic inflammation and mucosal immune dysfunction persist in people living with HIV, despite treatment with combined anti-retroviral therapy, but the underlying immune mechanisms are poorly understood. Here we report that the altered immune landscape of the oral mucosa of HIV-positive patients on therapy involves increased TLR and inflammasome signaling, localized CD4+ T cell hyperactivation, and, counterintuitively, enrichment of FOXP3+ T cells. HIV infection of oral tonsil cultures in vitro causes an increase in FOXP3+ T cells expressing PD-1, IFN-γ, Amphiregulin and IL-10. These cells persist even in the presence of anti-retroviral drugs, and further expand when stimulated by TLR2 ligands and IL-1β. Mechanistically, IL-1β upregulates PD-1 expression via AKT signaling, and PD-1 stabilizes FOXP3 and Amphiregulin through a mechanism involving asparaginyl endopeptidase, resulting in FOXP3+ cells that are incapable of suppressing CD4+ T cells in vitro. The FOXP3+ T cells that are abundant in HIV-positive patients are phenotypically similar to the in vitro cultured, HIV-responsive FOXP3+ T cells, and their presence strongly correlates with CD4+ T cell hyper-activation. This suggests that FOXP3+ T cell dysregulation might play a role in the mucosal immune dysfunction of HIV patients on therapy.

Toward a physical map of the genome of the nematode Caenorhabditis elegans

A technique for digital characterization and comparison of DNA fragments, using restriction enzymes, is described. The technique is being applied to fragments from the nematode Caenorhabditis elegans (i) to facilitate cross-indexing of clones emanating from different laboratories and (ii) to construct a physical map of the genome. Eight hundred sixty clusters of clones, from 35 to 350 kilobases long and totaling about 60% of the genome, have been characterized.

Activation of human immunodeficiency virus transcription in T cells revisited: NF-kappaB p65 stimulates transcriptional elongation

Human immunodeficiency virus type 1 (HIV-1) is able to establish a persistent latent infection during which the integrated provirus remains transcriptionally silent. Viral transcription is stimulated by NF-kappaB, which is activated following the exposure of infected T cells to antigens or mitogens. Although it is commonly assumed that NF-kappaB stimulates transcriptional initiation alone, we have found using RNase protection assays that, in addition to stimulating initiation, it can also stimulate elongation from the HIV-1 long terminal repeat. When either Jurkat or CCRF/CEM cells were activated by the mitogens phorbol myristate acetate and phytohemagglutinin, elongation, as measured by the proportion of full-length transcripts, increased two- to fourfold, even in the absence of Tat. Transfection of T cells with plasmids carrying the different subunits of NF-kappaB demonstrated that the activation of transcriptional elongation is mediated specifically by the p65 subunit. It seems likely that initiation is activated because of NF-kappaB's ability to disrupt chromatin structures through the recruitment of histone acetyltransferases. To test whether p65 could stimulate elongation under conditions where it did not affect histone acetylation, cells were treated with the histone deacetylase inhibitor trichostatin A. Remarkably, addition of p65 to the trichostatin A-treated cell lines resulted in a dramatic increase in transcription elongation, reaching levels equivalent to those observed in the presence of Tat. We suggest that the activation of elongation by NF-kappaB p65 involves a distinct biochemical mechanism, probably the activation of carboxyl-terminal domain kinases at the promoter.

Measurement of the rate of nu(e) + d --> p + p + e(-) interactions produced by (8)B solar neutrinos at the Sudbury Neutrino Observatory

Solar neutrinos from (8)B decay have been detected at the Sudbury Neutrino Observatory via the charged current (CC) reaction on deuterium and the elastic scattering (ES) of electrons. The flux of nu(e)'s is measured by the CC reaction rate to be straight phi(CC)(nu(e)) = 1.75 +/- 0.07(stat)(+0.12)(-0.11)(syst) +/- 0.05(theor) x 10(6) cm(-2) s(-1). Comparison of straight phi(CC)(nu(e)) to the Super-Kamiokande Collaboration's precision value of the flux inferred from the ES reaction yields a 3.3 sigma difference, assuming the systematic uncertainties are normally distributed, providing evidence of an active non- nu(e) component in the solar flux. The total flux of active 8B neutrinos is determined to be 5.44+/-0.99 x 10(6) cm(-2) s(-1).

Tackling Tat

Activation of cellular genes typically involves control of transcription initiation by DNA-binding regulatory proteins. The human immunodeficiency virus transactivator protein, Tat, provides the first example of the regulation of viral gene expression through control of elongation by RNA polymerase II. In the absence of Tat, initiation from the long terminal repeat is efficient, but transcription is impaired because the promoter engages poorly processive polymerases that disengage from the DNA template prematurely. Activation of transcriptional elongation occurs following the recruitment of Tat to the transcription machinery via a specific interaction with an RNA regulatory element called TAR, a 59-residue RNA leader sequence that folds into a specific stem-loop structure. After binding to TAR RNA, Tat stimulates a specific protein kinase called TAK (Tat-associated kinase). This results in hyperphosphorylation of the large subunit of the RNA polymerase II carboxyl- terminal domain. The kinase subunit of TAK, CDK9, is analogous to a component of a positive acting elongation factor isolated from Drosophila called pTEFb. Direct evidence for the role of TAK in transcriptional regulation of the HIV long terminal repeat comes from experiments using inactive mutants of the CDK9 kinase expressed in trans to inhibit transcription. A critical role for TAK in HIV transcription is also demonstrated by selective inhibition of Tat activity by low molecular mass kinase inhibitors. A second link between TAK and transactivation is the observation that the cyclin component of TAK, cyclin T1, also participates in TAR RNA recognition. It has been known for several years that mutations in the apical loop region of TAR RNA abolish Tat activity, yet this region of TAR is not required for binding by recombinant Tat protein in vitro, suggesting that the loop region acts as a binding site for essential cellular co-factors. Tat is able to form a ternary complex with TAR RNA and cyclin T1 only when a functional loop sequence is present on TAR.

Direct evidence that HIV-1 Tat stimulates RNA polymerase II carboxyl-terminal domain hyperphosphorylation during transcriptional elongation

The human immunodeficiency virus type-1 (HIV-1) Tat protein regulates transcription by stimulating RNA polymerase processivity. Using immobilised templates, we have been able to study the effects of Tat on protein kinase activity during the pre-initiation and elongation stages of HIV-1 transcription. In pre-initiation complexes formed at the HIV-1 LTR, the C-terminal domain (CTD) of RNA polymerase II is rapidly phosphorylated by transcription factor IIH (TFIIH). Addition of Tat does not affect either the rate or the extent of CTD phosphorylation in the pre-initiation complexes. By contrast, Tat is able to stimulate additional CTD phosphorylation in elongation complexes. This reaction creates a novel form of the RNA polymerase that we have called RNA polymerase IIo*. Formation of the RNA polymerase IIo* occurs only after transcription of templates carrying a functional TAR RNA element and is strongly inhibited by low concentrations of 5,6-dichloro-1-beta- D -ribofuranosyl benzimidazole (DRB), a potent inhibitor of CDK9, the protein kinase subunit of the Tat-associated kinase (TAK). Immunoblotting experiments have shown that CDK9 and its associated cyclin, cyclin T1, are present at equivalent levels in both the pre-initiation and elongation complexes. We conclude that activation of the CDK9 kinase, leading to CTD phosphorylation, occurs only in elongation complexes that have transcribed through the Tat-recognition element, TAR RNA.

Stimulation of Tat-associated kinase-independent transcriptional elongation from the human immunodeficiency virus type-1 long terminal repeat by a cellular enhancer

The human immunodeficiency virus type-1 (HIV-1) long terminal repeat (LTR) initiates transcription efficiently but produces only short transcripts in the absence of the trans-activator protein, Tat. To determine whether a cellular enhancer could provide the signals required to recruit an elongation-competent polymerase to the HIV-1 LTR, the B cell-specific immunoglobulin heavy chain gene enhancer (IgHE) was inserted upstream of the LTR. The enhancer increased transcription in the absence of Tat between 6- and 7-fold in transfected B cells, but the full-length transcripts remained at basal levels in HeLa cells, where the enhancer is inactive. RNase-protection studies showed that initiation levels in the presence and absence of the enhancer were constant, but the enhancer significantly increased the elongation capacity of the polymerases. Tat-stimulated elongation is strongly inhibited by the nucleoside analogue 5,6-dichloro-1-beta-D-ribofuranosylbenzimidazole (DRB), which inhibits the Tat-associated kinase, TAK (CDK9). However, polymerases initiating transcription from LTRs carrying the enhancer were able to efficiently elongate in the presence of DRB. Specific repression of TAK by expression in trans of the CDK9 kinase also inhibited Tat-stimulated elongation but did not inhibit enhancer-dependent transcription significantly. Thus, the activation of polymerase processivity by the IgHE involves a unique mechanism which is independent of TAK.

Synergistic stimulation of HIV-1 rev-dependent export of unspliced mRNA to the cytoplasm by hnRNP A1

The structural and accessory proteins of human immunodeficiency virus type 1 are expressed by unspliced or partially spliced mRNAs. Efficient transport of these mRNAs from the nucleus requires the binding of the viral nuclear transport protein Rev to an RNA stem-loop structure called the RRE (Rev response element). However, the RRE does not permit Rev to stimulate the export of unspliced mRNAs from the efficiently spliced beta-globin gene in the absence of additional cis-acting RNA regulatory signals. The p17gag gene instability (INS) element contains RNA elements that can complement Rev activity. In the presence of the INS element and the RRE, Rev permits up to 30 % of the total beta-globin mRNA to be exported to the cytoplasm as unspliced mRNA. Here, we show that a minimal sequence of 30 nt derived from the 5' end of the p17 gag gene INS element (5' INS) is functional and permits the export to the cytoplasm of 14% of the total beta-globin mRNA as unspliced pre-mRNA. Gel mobility shift assays and UV cross-linking experiments have shown that heterogeneous nuclear ribonucleoprotein (hnRNP) A1 and a cellular RNA-binding protein of 50 kDa form a complex on the 5' INS. Mutants in the 5' INS that prevent hnRNP A1 and 50 kDa protein binding are inactive in the transport assay. To confirm that the hnRNP A1 complex is responsible for INS activity, a synthetic high-affinity binding site for hnRNP A1 was also analysed. When the high affinity hnRNP A1 binding site was inserted into the beta-globin reporter, Rev was able to increase the cytoplasmic levels of unspliced mRNAs to 14%. In contrast, the mutant hnRNP A1 binding site, or binding sites for hnRNP C and L are unable to stimulate Rev-mediated RNA transport. We conclude that hnRNP A1 is able to direct unspliced globin pre-mRNA into a nuclear compartment where it is recognised by Rev and then transported to the cytoplasm.

Transfer of Tat and release of TAR RNA during the activation of the human immunodeficiency virus type-1 transcription elongation complex

The HIV-1 trans-activator protein, Tat, is a potent activator of transcriptional elongation. Tat is recruited to the elongating RNA polymerase during its transit through the trans-activation response region (TAR) because of its ability to bind directly to TAR RNA expressed on the nascent RNA chain. We have shown that transcription complexes that have acquired Tat produce 3-fold more full-length transcripts than complexes not exposed to Tat. Western blotting experiments demonstrated that Tat is tightly associated with the paused polymerases. To determine whether TAR RNA also becomes attached to the transcription complex, DNA oligonucleotides were annealed to the nascent chains on the arrested complexes and the RNA was cleaved by RNase H. After cleavage, the 5' end of the nascent chain, carrying TAR RNA, is quantitatively removed, but the 3' end of the transcript remains associated with the transcription complex. Even after the removal of TAR RNA, transcription complexes that have been activated by Tat show enhanced processivity. We conclude that Tat, together with cellular co-factors, becomes attached to the transcription complex and stimulates processivity, whereas TAR RNA does not play a direct role in the activation of elongation and is used simply to recruit Tat and cellular co-factors.

An inhibitor of the Tat/TAR RNA interaction that effectively suppresses HIV-1 replication

One of the first steps in HIV gene expression is the recruitment of Tat protein to the transcription machinery after its binding to the RNA response element TAR. Starting from a pool of 3.2 x 10(6) individual chemical entities, we were able to select a hybrid peptoid/peptide oligomer of 9 residues (CGP64222) that was able to block the formation of the Tat/TAR RNA complex in vitro at nanomolar concentrations. NMR studies demonstrated that the compound binds similarly to polypeptides derived from the Tat protein and induces a conformational change in TAR RNA at the Tat-binding site. In addition, 10-30 microM CGP64222 specifically inhibited Tat activity in a cellular Tat-dependent transactivation assay [fusion-induced gene stimulation (FIGS) assay] and blocked HIV-1 replication in primary human lymphocytes. By contrast, peptides of a comparable size and side-chain composition inhibited cell fusion in the FIGS assay and only partially inhibited HIV-1 replication in primary human lymphocytes. Thus, we have discovered a compound, CGP64222, that specifically inhibits the Tat/TAR RNA interaction, both in vitro and in vivo.

Structure of HIV-1 TAR RNA in the absence of ligands reveals a novel conformation of the trinucleotide bulge

Efficient transcription from the human immunodeficiency virus (HIV) promoter depends on binding of the viral regulatory protein Tat to a cis-acting RNA regulatory element, TAR. Tat binds at a trinucleotide bulge located near the apex of the TAR stem-loop structure. An essential feature of Tat-TAR interaction is that the protein induces a conformational change in TAR that repositions the functional groups on the bases and the phosphate backbone that are critical for specific intermolecular recognition of TAR RNA. We have previously determined a high resolution structure for the bound form of TAR RNA using heteronuclear NMR. Here, we describe a high resolution structure of the free TAR RNA based on 871 experimentally determined restraints. In the free TAR RNA, bulged residues U23 and C24 are stacked within the helix, while U25 is looped out. This creates a major distortion of the phosphate backbone between C24 and G26. In contrast, in the bound TAR RNA, each of the three residues from the bulge are looped out of the helix and U23 is drawn into proximity with G26 through contacts with an arginine residue that is inserted between the two bases. Thus, TAR RNA undergoes a transition from a structure with an open and accessible major groove to a much more tightly packed structure that is folded around basic side chains emanating from the Tat protein.

Flexible regions of RNA structure facilitate co-operative Rev assembly on the Rev-response element

The oligomerisation of Rev on the Rev-response element (RRE) was studied using a series of model substrates. Only a monomer of Rev is able to bind efficiently to a high affinity site that is flanked by perfect duplex RNA. Addition of a bulge or a second stem structure adjacent to the high affinity site permits the co-operative incorporation of a second Rev molecule to the RNA. Model RREs carrying bulges can bind Rev with a higher degree of co-operativity than the native structure. Oligomerisation was efficient when the bulge was moved to the opposite strand of the duplex, but was severely impaired when the distance between the bulge and the high affinity site was increased by more than 8 bp. Rev can oligomerise at either end of the RNA-protein complex formed at the high affinity site; when the duplex flanking a high affinity site is disrupted by a bulge or a stem, oligomerisation proceeds in the direction of the disruption regardless of the orientation of the high affinity site. The results are consistent with the "molecular rheostat" model for RRE function, which suggests that Rev binding to the RRE is highly distributive and provides a sensitive measurement of intracellular Rev concentrations.

Interactions of INS (CRS) elements and the splicing machinery regulate the production of Rev-responsive mRNAs

The human immunodeficiency virus type (HIV-1) Rev protein stimulates the export to the cytoplasm of unspliced HIV-1 mRNAs carrying the Rev response element (RRE). However, simple addition of the RRE to beta-globin pre-mRNA does not confer a Rev response on this heterologous transcript. In this paper, we demonstrate that a strong Rev response is conferred on beta-globin pre-mRNA when an inhibitory (INS) element is inserted into the gene together with the RRE. In the presence of INS element, Rev was able to stimulate the export to the cytoplasm of unspliced mRNA 10 to 15-fold. INS elements from the HIV-1 p17 gag and pol genes were equally active in complementing Rev-dependent nuclear export of unspliced mRNA. By contrast, mutated p17 gag INS element, known to be inactive in gag mRNA instability assays, was unable to complement the Rev/RRE system and stimulate nuclear export. Similarly, AUUUA-instability elements from the granulocyte-macrophage colony stimulating factor mRNA (GM-CSF) destabilised beta-globin mRNA but could not substitute for the HIV INS elements. Complementation between the Rev/RRE system and the INS elements was only observed when splicing was efficient. When splicing of the beta-globin gene receptor is impaired by mutations in the 5' splice donor, the 3' splice acceptor sequence, or the polypyrimidine tract, the majority of the unspliced mRNA is exported from the nucleus in the absence of Rev. In the presence of splice site mutations, Rev is able to act independently of a functional INS element and increase the export of unspliced mRNA three to fivefold. We propose that nuclear factor(s) binding to INS elements separate unspliced beta-globin pre-mRNA from the splicing apparatus. Pre-mRNA in this "INS compartment" remains accessible to Rev. Thus, there is a synergy between the INS elements and Rev which leads to enhanced nuclear export of unspliced mRNA.

Human immunodeficiency virus type-1 Tat is an integral component of the activated transcription-elongation complex

The human immunodeficiency virus type 1 transactivator protein, Tat, stimulates transcriptional elongation from the viral long terminal repeat. To test whether Tat associates directly with activated transcription complexes, we have used the lac repressor protein (LacR) to "trap" elongating RNA polymerases. The arrested transcription complexes were purified by binding biotinylated templates to streptaviridin-coated magnetic beads. Transcription complexes were released from the magnetic beads following cleavage of the templates with restriction enzymes and were immunoblotted with antibodies to Tat, LacR and RNA polymerase II. The Tat protein copurified with RNA polymerase bound to wild-type templates but did not copurify with transcription complexes prepared by using templates carrying mutations in the transactivation response element (TAR) RNA. We conclude that Tat and cellular cofactors become attached to the transcription complex during its transit through TAR.

The structure of the human immunodeficiency virus type-1 TAR RNA reveals principles of RNA recognition by Tat protein

The human immunodeficiency virus type-1 (HIV-1) Tat protein stimulates transcriptional elongation. Tat is introduced to the transcription machinery by binding to the transactivation response region (TAR) RNA stem-loop encoded by the 5' leader sequence found on all HIV-1 mRNAs. We have used multidimensional heteronuclear NMR to determine the structure of the TAR RNA in the presence of the ADP-1 polypeptide, a 37-mer that carries the minimal RNA recognition region of the Tat protein and closely mimics Tat binding specificity. In the presence of a variety of ligands, including ADP-1, related basic peptides and the amino acid derivative argininamide, the bulge region of TAR undergoes a local conformational rearrangement and forms a more stable structure. The structure of TAR in the bound form has been determined from over 1000 NMR-derived constraints. The U23 residue at the 5' end of the bulge is positioned near G26 and A27 in the major groove, rather than stacked on A22 as in the free TAR. U23 and G26 are brought into close proximity by contacts to the guanidinium group and side-chain amide group of a common arginine residue. However, the interaction of this guanidinium group with TAR is not the only source of binding specificity. Besides NOEs to the arginine residue participating in the conformational change, ADP-1 shows additional intermolecular NOEs to TAR, suggesting that there are multiple points of contacts between TAR RNA and residues from the basic and core regions of Tat. These structural results provide important clues towards the identification of small molecular mass and/or peptidomimetic inhibitors of the essential Tat-TAR interaction.

Progress in anti-HIV structure-based drug design

The course of drug development for the treatment of HIV-1 infection and AIDS is being revolutionized by high-resolution structures of essential viral proteins. We survey the impact on drug design of the recently elucidated structural knowledge of two essential enzymes, reverse transcriptase and protease, and three new targets, the viral integrase and the gene regulatory protein-RNA interactions, Tat-TAR and Rev-RRE.

The human immunodeficiency virus long terminal repeat includes a specialised initiator element which is required for Tat-responsive transcription

The effects of mutations in human immunodeficiency virus type-1 (HIV-1) long terminal repeat on initiation and on Tat-mediated trans-activation were studied using cell-free transcription assays. All the elements that are necessary for efficient transcription initiation in vitro are included in the core promoter. This region contains three tandem Sp1 binding sites, a TATA element and an initiator (INR) sequence. Although the HIV-1 INR element overlaps the trans-activation response region (TAR), it forms an integral part of the promoter. The HIV-1 INR element was characterised in detail using a template that carries a complete HIV-1 promoter and a displaced TAR RNA element. The results demonstrate that the sequence G+1GGTCT is essential for HIV-1 INR function. RNase protection experiments show that Tat acts exclusively to stimulate transcriptional elongation. Mutations in the core promoter elements reduce initiation rates dramatically but do not block Tat activity. For each mutation studied, the total level of transcription in the presence of Tat is proportional to the rate of initiation in the absence of Tat. Furthermore the rate of initiation remains constant in the presence or absence of Tat. We conclude that the elements of the HIV-1 core promoter act in concert to simulate initiation. By contrast, Tat acts independently of the core promoter elements and stimulates elongation. The data strongly suggest that Tat is recruited to the elongating transcription complex during its transit through TAR.

The RNA element encoded by the trans-activation-responsive region of human immunodeficiency virus type 1 is functional when displaced downstream of the start of transcription

The human immunodeficiency virus type 1 (HIV-1) trans-activator protein, Tat, specifically stimulates transcription from the viral long terminal repeat. Tat binds to an RNA stem-loop structure encoded by the trans-activation response region (TAR). To test whether TAR is functional when displaced downstream of the start of transcription, we assayed a series of templates carrying duplicated TAR elements in cell-free transcription systems. When the normally positioned TAR element (TAR-1) is inactivated by mutations in either the Tat binding site or the apical loop sequence, which acts as the binding site for a cellular factor, transactivation can be rescued by a wild-type TAR element placed downstream (TAR-2). The TAR-2 element is functional even when placed > 200 nt downstream of TAR-1. TAR complementation experiments have also shown that a functional TAR element requires both an intact Tat binding site and an intact apical loop sequence. For example, if TAR-1 carries a mutation in the loop element it cannot be rescued by a TAR-2 element carrying a mutation in the Tat binding site. Substitution mutations in TAR-1 show that the 5' half of TAR also encodes an essential DNA element which is required for efficient transcription initiation. These results strongly suggest that Tat and cellular cofactors which bind TAR RNA associate with the transcription complex during its transit through TAR.

A molecular rheostat. Co-operative rev binding to stem I of the rev-response element modulates human immunodeficiency virus type-1 late gene expression

The complete biologically active human immunodeficiency virus type-1 (HIV-1) rev-response element (RRE) RNA is 351 nucleotides (nt) in length, and includes an extra 58 nt on the 5' end and 59 nt on the 3' end beyond the sites proposed in the original models for the RRE secondary structure. The extra sequences are able to form a duplex structure which extends Stem I. The presence of an elongated Stem I structure in the RRE RNA was confirmed by nuclease mapping experiments. Nuclease protection experiments have shown that rev binds to restricted regions of the RRE, including the high affinity site located at the base of Stem IIb and along the length of the Stem I region. The three large stem-loop structures which protrude from Stem I and Stem IIb (Stems IIc, III+IV and V) remain accessible to nucleases even in the presence of a large excess of protein. Gel-retardation experiments show that the truncations of Stem I reduced the total number of rev molecules that can bind co-operatively and with high affinity to the RRE RNA. To test whether the elongated Stem I structure is required for maximal rev activity, a series of truncations which progressively reduced the length of Stem I was introduced into an HIV-1 derived reporter plasmid. In the presence of rev and a functional RRE, there is an increase in the levels of gag and env mRNA in the cytoplasm and a decrease in levels of tat and rev mRNAs. Each of the truncations in Stem I reduced the rev responses, with the longest truncations producing the greatest losses of activity. The data suggest that the RRE acts as a "molecular rheostat" designed to detect rev levels during the early stages of the HIV growth cycle.

Methylphosphonate mapping of phosphate contacts critical for RNA recognition by the human immunodeficiency virus tat and rev proteins

The HIV-1 regulatory proteins tat and rev are both RNA binding proteins which recognize sequences in duplex RNA which are close to structural distortions. Here we identify phosphate contacts which are critical for each binding reaction by use of a new method. Model RNA binding sites are constructed carrying substitutions of individual phosphodiesters by uncharged methylphosphonate derivatives isolated separately as Rp and Sp diastereoisomers and tested for protein binding by competition assays. In the binding of tat to the trans-activation response region (TAR), three phosphates, P21 and P22 which are adjacent to the U-rich bulge and P40 on the opposite strand, are essential and in each case both isomers inhibit binding. Similarly, in the interaction between the HIV-1 rev protein and the rev-responsive element (RRE) both methylphosphonate isomers at P103, P104, P124 and P125 interfere with rev binding. At P106, only the Rp methylphosphonate isomer is impaired in rev binding ability and it is proposed that the Rp oxygen is hydrogen-bonded to an uncharged amino acid or to a main chain hydrogen atom. Synthetic chemistry techniques also provide evidence for the conformations of non-Watson-Crick G106:G129 and G105:A131 base-pairs in the RRE 'bubble' structure upon rev binding. Almost all functional groups on the 5 bulged residues in the bubble have been ruled out as sites of contact with rev but, by contrast, the N7-positions of each G residue in the flanking base-pairs are identified as sites of likely hydrogen-bonding to rev. The results show that both tat and rev recognize the major groove of distorted RNA helixes and that both proteins make specific contacts with phosphates which are displaced from the sites of base-pair contact.

RNA recognition by the human immunodeficiency virus Tat and Rev proteins

The human immunodeficiency virus (HIV-1) regulatory proteins, Tat and Rev, are important potential targets for the development of new drug therapies against HIV infection. Both proteins are highly specific RNA-binding proteins that recognize cis-acting regulatory elements in the viral mRNAs. These interactions are fascinating paradigms of a new principle of RNA recognition in which the protein makes contact with functional groups displayed in a distorted major groove of an RNA duplex.

Human immunodeficiency virus type 1 transactivator protein, tat, stimulates transcriptional read-through of distal terminator sequences in vitro

The human immunodeficiency virus type 1 transactivator protein, tat, specifically stimulates transcription from the viral long terminal repeat. We used cell-free transcription systems to test whether tat can stimulate transcriptional read-through of an artificial terminator sequence (e.g., a stable RNA stem-loop structure followed by a tract of nine uridine residues) placed downstream of the viral long terminal repeat. In the absence of tat, RNA polymerases are prematurely released from the template at the terminator sequence. Recombinant tat protein purified from Escherichia coli increased the synthesis of full-length transcripts approximately 25-fold and decreased the amount of transcripts ending at the terminator sequence. The reaction is strictly dependent upon the presence of a functional transactivation-responsive region (TAR) sequence. Mutations in the tat binding site on TAR RNA and mutations in the TAR RNA loop block transactivation in vivo. Neither type of mutation is able to respond to tat in vitro. These results strongly suggest that after transcription through the TAR region, tat modifies the transcription complex to increase its elongation capacity.

Hydrogen-bonding contacts in the major groove are required for human immunodeficiency virus type-1 tat protein recognition of TAR RNA

The binding site for tat on TAR RNA was analysed by preparing a series of model RNA substrates carrying site-specific functional group modifications. The test RNAs were prepared by annealing two short synthetic oligoribonucleotides to form a duplex structure with a U-rich bulge and flanking sequences identical to TAR RNA. Tat binds these duplex RNAs with approximately half the affinity for wild-type TAR RNA. Substitution at positions U23 or U25 by the base analogue, O4-methyl-dT, which is deficient in its ability to hydrogen-bond at the N3 position reduces tat affinity more than 20-fold. Modifications to purines in the stem of TAR RNA that affect hydrogen-bonding ability in either the major or the minor groove of duplex RNA were also tested. Removal of the nitrogen atom at either the N7 position of G26 or at the N7 position of A27 reduces tat affinity 10- to 20-fold. By contrast removal of the exocyclic amino group in the minor groove at position G26, by substitution with inosine, does not affect tat binding significantly. A single methylphosphonate substitution at the phosphate bond between A22 and U23 also leads to a significant loss of tat binding ability, whereas all other methylphosphonate substitutions in the U-rich bulge are not harmful to tat binding. We conclude that tat forms multiple specific hydrogen bonds to a series of dispersed sites displayed in the major groove of the TAR RNA molecule. These include the N3-H of U23, the N7 of G26, the N7 of A26 and the phosphate between A22 and U23.

High affinity binding of TAR RNA by the human immunodeficiency virus type-1 tat protein requires base-pairs in the RNA stem and amino acid residues flanking the basic region

The binding site for tat protein on TAR RNA has been defined in quantitative terms using an extensive series of mutations. The relative dissociation constants for the mutant TAR RNAs were measured using a dual-label competition filter binding assay in which 35S-labelled wild-type TAR RNA (K1) was competed against 3H-labelled mutant TAR RNA (K2). The error in the self-competition experiment was usually less than 10% (e.g. K2/K1 = 1.07 +/- 0.05, n = 19) and the experimental data accurately matched theoretical curves calculated with fitted dissociation constants. Mutations in U23, a critical residue in the U-rich "bulge" sequence, or in either of the two base-pairs immediately above the "bulge", G26.C39 and A27.U38 reduced that affinity by 8- to 20-fold. Significant contributions to tat binding affinity were also made by the base-pairs located immediately below the bulge. For example, mutation of A22.U40 to U.A reduced tat affinity 5-fold, and mutation of G21.C41 to C.G reduced tat affinity 4-fold. The binding of a series of peptides spanning the basic "arginine-rich" sequence of tat was examined using both filter-binding and gel mobility shift assays. Each of the peptides showed significantly reduced affinities for wild-type TAR RNA compared to the tat protein. The ADP-2 (residues 43 to 72), ADP-3 (residues 48 to 72) and ADP-5 (residues 49 to 86) peptides were unable to discriminate between wild-type TAR RNA and TAR RNA mutants with the same fidelity as the tat protein. For example, these peptides showed no more than 3-fold reductions in affinity relative to wild-type TAR RNA for the U23-->C mutation in the bulge, or G26.G39-->C.G mutation in the stem of TAR RNA. By contrast, the ADP-I (residues 37 to 72), ADP-4 (residues 32 to 62) and ADP-6 (residues 32 to 72) peptides, which each carry amino acid residues from the "core" region of the tat protein have binding specificities that more closely resemble the protein. The ADP-4 and ADP-6 peptides showed between 4- and 7-fold reductions in affinity for the U23-->C or G26.C39-->C.G mutations. The ADP-1 peptide most closely resembles the protein in its binding specificity and showed 9-fold and 14-fold reductions in affinity for the two mutants, respectively. Chemical-modification interference assays using diethylpyrocarbonate (DEPC) and ethylnitrosourea (ENU) were also used to compare the binding properties of the tat protein and the tat-derived peptides.(ABSTRACT TRUNCATED AT 400 WORDS)

Recognition of the high affinity binding site in rev-response element RNA by the human immunodeficiency virus type-1 rev protein

The Human Immunodeficiency Virus type-1 rev protein binds with high affinity to a bubble structure located within the rev-response element (RRE) RNA in stemloop II. After this initial interaction, additional rev molecules bind to the RRE RNA in an ordered assembly process which requires a functional bubble structure, since mutations in the bubble sequence that reduce rev affinity block multiple complex formation. We have used synthetic chemistry to characterize the interaction between rev protein and its high affinity binding site. A minimal synthetic duplex RNA (RBC6) carrying the bubble and 12 flanking base pairs is able to bind rev with 1 to 1 stoichiometry and with high affinity. When the bubble structure is inserted into synthetic RNA molecules carrying longer stretches of flanking double-stranded RNA, rev forms additional complexes resembling the multimers observed with the RRE RNA. The ability of rev to bind to RBC6 analogues containing functional group modifications on base and sugar moieties of nucleoside residues was also examined. The results provide strong evidence that the bubble structure contains specific configurations of non-Watson--Crick G:G and G:A base pairs and suggest that high affinity recognition of RRE RNA by rev requires hydrogen bonding to functional groups in the major groove of a distorted RNA structure.

Human immunodeficiency virus type 1 regulator of virion expression, rev, forms nucleoprotein filaments after binding to a purine-rich "bubble" located within the rev-responsive region of viral mRNAs

The human immunodeficiency virus type 1 rev protein binds with high affinity (Kd less than 1-3 nM) to a purine-rich "bubble" containing bulged GG and GUA residues on either side of a double-helical RNA stem-loop located toward the 5' end of rev-response element RNA. High-affinity rev binding is maintained when the bubble is placed in heterologous stem-loop structures, but rev binding is reduced when either the bulged residues or flanking base pairs in the stem are altered. Rev binding to the purine-rich bubble nucleates assembly of long filamentous ribonucleoprotein structures containing polymers of rev bound to flanking RNA sequences. It is proposed that rev regulates human immunodeficiency virus RNA expression by selectively packaging viral transcripts carrying the rev-response element sequence into rod-like nucleoprotein complexes that block splicing of the packaged mRNAs.

Control of human immunodeficiency virus replication by the tat, rev, nef and protease genes

Immediately after infection, human immunodeficiency virus directs the synthesis of three regulatory proteins tat, rev and nef that together allow the synthesis of the structural proteins of the virus after a delay of several hours. Viral mRNA production is controlled by the tat gene, which appears to stimulate elongation by RNA polymerase II, and the rev gene, which allows the accumulation of unspliced or partially spliced mRNAs in the cytoplasm. The nef gene is dispensible for virus growth but may limit virus spread by downregulating the levels of cellular surface proteins such as the CD4 receptor. Virus maturation also depends critically on the protease gene which allows the orderly rearrangement of the viral core structures in newly budded virions as well as the vpu and vif genes which allow efficient production of mature envelope glycoprotein.

RNA binding by the tat and rev proteins of HIV-1

HIV-1 tat protein binds specifically to HIV-1 TAR RNA. A Scatchard analysis of tat binding has shown that the purified protein forms a one-to-one complex with HIV-1 TAR RNA with a dissociation constant of Kd = 12 nM. Tat binding in vitro is dependent upon the presence of 3 non-base paired U residues which produce a 'bulge' in the TAR RNA stem-loop structure. Deletion of the uridine residues in the bulge or substitution with guanine residues produced RNAs with a 6 to 8-fold lower affinity than wild-type TAR. By contrast, mutations that alter the sequence of the 6 nucleotide-long loop at the tip of TAR RNA structure, and mutations which alter the sequence of the stem whilst preserving Watson-Crick base pairing, do not affect tat binding significantly. There is a direct correlation between the ability of tat to bind to TAR RNA and to activate HIV transcription. Viral LTRs encoding TAR sequences known to bind tat weakly, are not stimulated efficiently by tat in vivo. HIV-1 regulator of virion expression (rev) protein binds specifically to RNA transcripts containing the 223 nucleotide-long RRE sequence with an apparent dissociation constant of 1-3 nM. The minimum binding site for rev is a 'bubble' containing 2 G residues on one side and the sequence AGU on the other. Rev is able to bind efficiently to this restricted site in the context of the RRE sequence as well as in the context of a stable RNA duplex with a sequence unrelated to that found in the RRE.(ABSTRACT TRUNCATED AT 250 WORDS)

HIV-1 tat protein stimulates transcription by binding to a U-rich bulge in the stem of the TAR RNA structure

The HIV-1 trans-activator protein, tat, is an RNA binding protein with a high affinity for a U-rich bulge near the tip of the stem in the RNA stem-loop structure encoded by the trans-activation responsive region (TAR). A Scatchard analysis of tat binding has shown that the purified protein forms a one-to-one complex with HIV-1 TAR RNA with a dissociation constant of Kd = 12 nM. Deletion of the uridine residues in the bulge or substitution with guanine residues produced RNAs with a 6- to 8-fold lower affinity than wild-type TAR. Introduction of a point mutation expected to destabilize base pairing in nearby residues of the TAR stem-loop structure reduced tat binding 10-fold. In contrast, mutations that alter the sequence of the six nucleotide long loop at the tip of TAR RNA structure, and mutations which alter the sequence of the stem whilst preserving Watson-Crick base pairing, do not affect tat binding significantly. There is a direct correlation between the ability of tat to bind to TAR RNA and to activate HIV transcription. Viral LTRs carrying TAR sequences encoding any of the mutations known to produce transcripts which bind tat weakly, are not stimulated efficiently by tat in vivo.

HIV-1 regulator of virion expression (Rev) protein binds to an RNA stem-loop structure located within the Rev response element region

HIV-1 Rev protein, purified from E. coli, binds specifically to an RNA transcript containing the 223 nucleotide long Rev response element (RRE) sequence. Rev binds to RRE in vitro with an apparent dissociation constant of 1 to 3 nM as determined by filter binding, gel mobility shift assays, or an immunoprecipitation assay using a monoclonal antibody specific for the Rev C-terminus. Antisense RRE sequences are bound by Rev with a 20-fold lower affinity than wild-type RRE sequences. The Rev-RRE complex forms even in the presence of a 10,000-fold molar excess of 16S rRNA, whereas formation of the low affinity antisense RRE-Rev complex is efficiently blocked by addition of excess 16S rRNA. A approximately 33 nucleotide fragment is protected from ribonuclease T1 digestion by the binding of Rev to RRE RNA, suggesting that Rev binds with high affinity to only a restricted region of the RRE. This protected fragment is unable to rebind Rev protein but has been mapped to a 71 nucleotide long Rev binding domain sequence that overlaps the protected fragment.

Human immunodeficiency virus 1 tat protein binds trans-activation-responsive region (TAR) RNA in vitro

tat, the trans-activator protein for human immunodeficiency virus 1 (HIV-1), has been expressed in Escherichia coli from synthetic genes. Purified tat binds specifically to HIV-1 trans-activation-responsive region (TAR) RNA in gel-retardation, filter-binding, and immunoprecipitation assays. tat does not bind detectably to antisense TAR RNA sequences, cellular mRNA sequences, variant TAR RNA sequences with altered stem-loop structures, or TAR DNA.

Regulatory and essential light-chain-binding sites in myosin heavy chain subfragment-1 mapped by site-directed mutagenesis

Site-directed mutagenesis of the cloned subfragment-1 (S-1) region of the unc-54 gene, encoding the myosin heavy chain B (MHC B) from Caenorhabditis elegans, has been used to locate binding sites for the regulatory and essential light chains. MHC B S-1 synthesized in Escherichia coli co-migrated with rabbit skeletal muscle myosin S-1 (Mr 90,000), was recognized by anti-nematode myosin antiserum on immunoblots, and specifically bound to 125I-labelled regulatory and essential light chains in a gel overlay assay. Deletion of 102 residues from the C terminus (mutant 655) reduced regulatory and essential light-chain binding to about 30% and 20% of wild-type levels, respectively. Similar reductions in relative binding of the two light chains were seen with mutant 534, in which 38 residues were deleted from the C terminus. Potential binding sites within 75 residues of the C terminus of S-1 were mapped by construction of five other mutant S-1 clones (398, 399, 400, 409 and 411) containing internal deletions of ten to 12 amino acid residues. These showed up to 30% reductions in their ability to bind essential light chains, but did not differ significantly from wild-type in their ability to bind regulatory light chains. Another mutant, 415, containing a deletion of a conserved acidic hexapeptide, E-D-I-R-D-E, showed enhancement of binding of regulatory and essential light chains to 150% and 165% of wild-type levels. Hence, the major binding sites for both light chains are within 38 amino acid residues of the C terminus.

Transformation of growth factor-dependent myeloid stem cells with retroviral vectors carrying c-myc

Myeloid progenitor cells and macrophages derived from bone marrow and spleen were efficiently transformed in vitro by infection with Moloney-based retroviral vectors carrying a human c-myc gene. Infected cells were plated in agar in the presence of combinations of the murine lymphokines CSF-1, IL-3, GM-CSF and IL-1. Between 20% and 100% of the colony-forming cells in the initial bone marrow or spleen population could be infected and gave rise to drug-resistant colonies. A large fraction of the infected cells showed continued proliferation after transfer to liquid media and we have derived over 200 growth factor-dependent cell lines. These include adherent and non-adherent CSF-1 or GM-CSF dependent macrophages and macrophage precursors and cell lines which require complex combinations of growth factors for optimal growth. Each of the cell lines displays a unique pattern of expression of surface markers specific for the myeloid lineage including the Mac-1, Mac-2, Mac-3, Ser-4 and F4/80 antigens. Surface markers not specifically associated with the myeloid lineage such as the MHC class II antigens and the Fc-receptor; and surface markers normally associated with the B-cell and T-cell lineages such as B220, L3T4 and Thy1.2 are also found on these cell lines.