Antibodies against a multiple-peptide conjugate comprising chemically modified human immunodeficiency virus type-1 functional Tat peptides inhibit infection

We demonstrated recently that selective side-chain modification of functional cysteine-rich (Tat(21-40)) and arginine-rich (Tat(53-68)) domains of the HIV-1 Tat protein blocks pathogenic activities of these peptides while retaining their immunological characteristics. In the present study, we have synthesized a multiple-peptide conjugate system comprising modified Tat(21-40) and Tat(53-68) peptides (HIV-1-Tat-MPC). Immunization of mice with this highly homogeneous 10.7 kDa HIV-1-Tat-MPC synthetic construct induced an effective immune response in mice. The antibodies generated against HIV-1-Tat-MPC efficiently suppressed Tat-induced viral replication and significantly reduced HIV-associated cytopathic effects in human monocytes. These results indicate that epitope-specific antibodies directed against functional sites of Tat protein using non-pathogenic peptides inhibit HIV pathogenesis. The HIV-1-Tat-MPC, therefore, has potential for the development of a safe, effective, and economical therapeutic vaccine to reduce the progression of HIV infection.     

Effects of the Tat basic domain on human immunodeficiency virus type 1 transactivation, using chemically synthesized Tat protein and Tat peptides.

To study the structure relationship of different Tat domains, the full-length Tat protein Tat1-86, the gene product of the first exon Tat1-72 which retains full activity of the protein, and a panel of shorter peptides mimicking different regions of the primary structure of the Tat protein were chemically synthesized by the solid-phase method, using an efficient protocol. Synthetic Tat1-86 and Tat1-72 transactivated beta-galactosidase activity in HeLa cells containing the lacZ gene under the control of the human immunodeficiency virus type 1 long terminal repeat. Analyses of the activity of Tat1-86 and Tat1-72 with the sulfhydryl of cysteine residues free or protected by the acetamidomethyl group showed that only the Tat fragments with deprotected cysteine residues retain transactivation ability. In contrast, peptide Tat1-48 was inactive, with cysteine residues either free or protected. Similarly, other shorter synthetic peptides covering the different Tat domains were inactive. Interestingly, when peptides Tat1-48 and Tat38-60 were used simultaneously, a significant transactivation was obtained. This result suggests that both peptide domains are implicated in transactivation, probably by acting at two different sites. This permits us to propose a fundamentally new step in the understanding of the molecular mechanism of Tat transactivation.     

Immunization with a novel HIV-1-Tat multiple-peptide conjugate induces effective immune response in mice

We report here a novel, highly immunogenic synthetic, multiple-peptide conjugate comprising functional domains Tat_21–40 and Tat_53–68 from HIV-1 group M plus Tat_9–20 from HIV-1 group O of the HIV-Tat protein (HIV-1-Tat-MPC). Vaccination of mice with HIV-1-Tat-MPC induced an effective immune response to all three functional domains. The anti-HIV-1-Tat-MPC antibodies efficiently inhibited Tat-induced viral activation in monocytes infected with HIV_Ba-L as well as with various clinical HIV-1 isolates, and reduced Tat-mediated cytopathicity in infected cells by 60–75%. Our results indicate that anti-HIV-1-Tat-MPC antibodies inhibit viral pathogenesis, possibly by blocking functional determinants of Tat and disrupting autocrine and paracrine actions of secreted Tat protein. This epitope-specific, synthetic Tat construct may, therefore, provide a subunit AIDS vaccine candidate for inducing an effective immunoprophylaxis response to reduce progression of HIV infection.     

Intracellular human immunodeficiency virus Tat expression in astrocytes promotes astrocyte survival but induces potent neurotoxicity at distant sites via axonal transport

The human immunodeficiency virus (HIV)-Tat protein has been implicated in the neuropathogenesis of HIV infection. However, its role in modulating astroglial-neuronal relationships is poorly understood. Astrocyte infection with HIV has been associated with rapid progression of dementia. We thus initially transfected astrocytes with HIV proviral DNA and confirmed Tat production in these cells. Subsequently, using stably Tat-producing asytocyte cell lines, we observed that Tat promoted astrocyte survival by causing a prominent antioxidant effect and resistance to cell injury in these cells. Tat was released extracellularly where it could be taken up by other cells. Tat remained functionally active following uptake and caused long terminal repeat (LTR) transactivation in lymphocytic and astrocytic cell lines. Tat released from astrocytes caused mitochondrial dysfunction, trimming of neurites, and cell death in neurons. Tat neurotoxicity was attenuated by anti-Tat antibodies, kynurenate or heparan sulfate. The neurotoxic effects of Tat were caused at concentrations lower than that needed to cause LTR transactivation. When Tat-expressing cells were injected into the rat dentate gyrus, Tat was taken up by granule cells and transported along neuronal pathways to the CA3 region where it caused glial cell activation and neurotoxicity. The arginine-rich domain of Tat was essential for both the LTR transactivation and the neurotoxic properties of Tat. Thus HIV-Tat is a potent neurotoxin that may act at distant sites while at the same time it assures its production by preventing cell death in astrocytes where it is produced.     

河南HIV感染者的HIV-1B型株tat基因的克隆及序列分析

克隆河南人免疫缺陷病毒(HIV)感染HIV-1B型株tat基因完整编码框序列,并分析比较其编码产物的序列结构特点。使用重叠PCR技术,从河南省1名HIV-1感染外周血标本中扩增出to／基因第一和第二外显子并重组为完整的tat基因序列。获得的HIV-1B病毒株tat基因,第一外显子为263bp,第二外显子为214bp。将该基因编码产物与其他HW-1株Tat蛋白经DNA软件编辑并翻译成蛋白质,使用Clustal X1．81进行多序列对比分析发现,第一外显子编码产物的3个保守区域的氨基酸组成大致相同,只有少数氨基酸存在差异。由于Tat蛋白不同病毒株间有高度保守的Cys富集区、核心区和碱性氨基酸富集区,tat基因的克隆为研究其功能并以其为靶点设计和筛选抗艾滋病的药物奠定了基础。     

Selection of TAR RNA-binding chameleon peptides by using a retroviral replication system

The interaction between the arginine-rich motif (ARM) of the human immunodeficiency virus (HIV) Tat protein and TAR RNA is essential for Tat activation and viral replication. Two related lentiviruses, bovine immunodeficiency virus (BIV) and Jembrana disease virus (JDV), also require Tat ARM-TAR interactions to mediate activation, but the viruses have evolved different RNA-binding strategies. Interestingly, the JDV ARM can act as a "chameleon," adopting both the HIV and BIV TAR binding modes. To examine how RNA-protein interactions may evolve in a viral context and possibly to identify peptides that recognize HIV TAR in novel ways, we devised a retroviral system based on HIV replication to amplify and select for RNA binders. We constructed a combinatorial peptide library based on the BIV Tat ARM and identified peptides that, like the JDV Tat ARM, also function through HIV TAR, revealing unexpected sequence characteristics of an RNA-binding chameleon. The results suggest that a retroviral screening approach may help identify high-affinity TAR binders and may provide new insights into the evolution of RNA-protein interactions.     

Interaction of arginine-rich peptides with membrane-associated proteoglycans is crucial for induction of actin organization and macropinocytosis

Arginine-rich peptides, including octaarginine (R8), HIV-1 Tat, and branched-chain arginine-rich peptides, belong to one of the major classes of cell-permeable peptides which deliver various proteins and macromolecules to cells. The importance of the endocytic pathways has recently been demonstrated in the cellular uptake of these peptides. We have previously shown that macropinocytosis is one of the major pathways for cellular uptake and that organization of the F-actin accompanies this process. In this study, using proteoglycan-deficient CHO cells, we have demonstrated that the membrane-associated proteoglycans are indispensable for the induction of the actin organization and the macropinocytic uptake of the arginine-rich peptides. We have also demonstrated that the cellular uptake of the Tat peptide is highly dependent on heparan sulfate proteoglycan (HSPG), whereas the R8 peptide uptake is less dependent on HSPG. This suggests that the structure of the peptides may determine the specificity for HSPG, and that HSPG is not the sole receptor for macropinocytosis. Comparison of the HSPG specificity of the branched-chain arginine-rich peptides in cellular uptake has suggested that the charge density of the peptides may determine the specificity. The activation of the Rac protein and organization of the actin were observed within a few minutes after the peptide treatment. These data strongly suggest the possibility that the interaction of the arginine-rich peptides with the membrane-associated proteoglycans quickly activates the intracellular signals and induces actin organization and macropinocytotis.     

Development of a functional backbone cyclic mimetic of the HIV-1 Tat arginine-rich motif

We have used the backbone cyclic proteinomimetics approach to develop peptides that functionally mimic the arginine-rich motif (ARM) of the HIV-1 Tat protein. This consensus sequence serves both as a nuclear localization signal (NLS) and as an RNA binding domain. Based on the NMR structure of Tat, we have designed and synthesized a backbone cyclic ARM mimetic peptide library. The peptides were screened for their ability to mediate nuclear import of the corresponding BSA conjugates in permeabilized cells. One peptide, designated "Tat11," displayed active NLS properties. Nuclear import of Tat11-BSA was found to proceed by the same distinct pathway used by the Tat-NLS and not by the common importin alpha pathway, which is used by the SV40-NLS. Most of the Tat-derived backbone cyclic peptides display selective inhibitory activity as demonstrated by the inhibition of the nuclear import mediated by the Tat-NLS and not by the SV40-NLS. The Tat-ARM-derived peptides, including Tat-11, also inhibited binding of the HIV-1 Rev-ARM to its corresponding RNA element (Rev response element) with inhibition constants of 5 nm. Here we have shown for the first time (a) a functional mimetic of a protein sequence, which activates a nuclear import receptor and (b) a mimetic of a protein sequence with a dual functionality. Tat11 is a lead compound which can potentially inhibit the HIV-1 life cycle by a dual mechanism: inhibition of nuclear import and of RNA binding.     

Arginine-Rich Peptides Destabilize the Plasma Membrane, Consistent with a Pore Formation Translocation Mechanism of Cell-Penetrating Peptides

Recent molecular-dynamics simulations have suggested that the arginine-rich HIV Tat peptides translocate by destabilizing and inducing transient pores in phospholipid bilayers. In this pathway for peptide translocation, Arg residues play a fundamental role not only in the binding of the peptide to the surface of the membrane, but also in the destabilization and nucleation of transient pores across the bilayer. Here we present a molecular-dynamics simulation of a peptide composed of nine Args (Arg-9) that shows that this peptide follows the same translocation pathway previously found for the Tat peptide. We test experimentally the hypothesis that transient pores open by measuring ionic currents across phospholipid bilayers and cell membranes through the pores induced by Arg-9 peptides. We find that Arg-9 peptides, in the presence of an electrostatic potential gradient, induce ionic currents across planar phospholipid bilayers, as well as in cultured osteosarcoma cells and human smooth muscle cells. Our results suggest that the mechanism of action of Arg-9 peptides involves the creation of transient pores in lipid bilayers and cell membranes.     

Cellular uptake [correction of utake] of the Tat peptide: an endocytosis mechanism following ionic interactions

The cellular delivery of various biological compounds has recently been improved by conjugating them to short peptides known as protein transduction domains or cell penetrating peptides. These peptides include Tat, Antennapedia and arginine-rich peptides. The common feature of these peptides is their highly cationic nature. Up to now, the cellular uptake of about 50 different peptides and proteins coupled to Tat or Antennapedia peptides has been reported. The ability to deliver molecules into cells is not limited to peptide moieties, since oligonucleotides, peptide nucleic acids or other low molecular weight entities have been successfully internalized. Moreover, most of these examples have been accompanied by the expected biological response. More surprisingly, the uptake of large structures such as liposomes, phages, nanoparticles or adenoviruses has also been documented. Indeed the mechanism by which these very different entities could enter cells following a putative common pathway appeared more and more intriguing after each new reported example of cellular uptake mediated by these peptides. After a long period of uncertainty regarding the mechanism of entry, data from several groups now argue for an energy-dependent process of entry. The entry of most of these molecules is likely to be inhibited by low temperature incubation or in the presence of various drugs applied to inhibit the energy-dependent pathway of cell entry. Moreover, the binding of the highly cationic Tat peptide to various anionic membrane components probably initiates the first step of the cell internalization process.     

Membrane permeability commonly shared among arginine-rich peptides

Delivery of proteins and other macromolecules using membrane-permeable carrier peptides is a recently developed novel technology, which enables us to modulate cellular functions for biological studies with therapeutic potential. One of the most often used carrier peptides is the arginine-rich basic peptide derived from HIV-1 Tat protein [HIV-1 Tat (48-60)]. Using this peptide, efficient intracellular delivery of molecules including proteins, oligonucleic acids and liposomes has been achieved. We have demonstrated that these features were commonly shared among many arginine-rich peptides such as HIV-1 Rev (34-50) and octaarginine. Not only the linear peptides but also branched-chain peptides showed efficient internalization with an optimum number of arginines (approximately eight residues). The structural and mechanistic features of the translocation of these membrane-permeable arginine-rich peptides are reviewed.     

Probing the impact of valency on the routing of arginine-rich peptides into eukaryotic cells

Multivalency represents a critical parameter in cell biology responsible for the overall avidity of low-affinity interactions and the triggering of cellular events. Functions such as catalytic activity, cellular uptake, or localization are frequently linked to the oligomeric state of a protein. This study explores the impact of multivalency on the import and routing of peptides into cells. Specifically, cationic import sequences such as decaarginine, decalysine, and the HIV Tat peptide (GRKKRRQRRRAP, residues 48-59) as well as the nuclear localization sequence from SV40 large T-antigen were assembled into defined peptide oligomers by fusing them to the tetramerization domain of human p53 (residues 325-355, hp53(tet) domain). The resulting tetravalent peptides typically displayed between 10- and 100-fold enhancements in cellular import and intracellular routing properties in relation to their monomeric homologues. These peptides were not toxic to cells. Flow cytometry results and transfection assays indicated that tetravalent decaarginyl peptides (10R-p53(tet) and NLS-10R-p53(tet)) were the peptides most efficiently routed into cells. Their mechanism of import was subsequently examined on unfixed, viable cells using a combination of metabolic inhibitors, flow cytometry, and microscopy techniques. These studies revealed that tetravalent arginine-rich peptides bind to heparan sulfate on the cell surface, are internalized at 37 degrees C, but not at 4 degrees C, via a clathrin-mediated pathway, and accumulate into endosome-like acidic compartments. A fraction of these tetravalent peptides access the cytosol and accumulate in the nucleus of cells. This study concludes that the oligomerization of proteins harboring arginine-rich peptide chains may profoundly influence their ability to enter and be routed into cells.     

Inhibition of human immunodeficiency virus type 1 and type 2 Tat function by transdominant Tat protein localized to both the nucleus and cytoplasm.

We introduced various mutations into the activation and RNA binding domains of human immunodeficiency virus type 1 (HIV-1) Tat in order to develop a novel and potent transdominant Tat protein and to characterize its mechanism of action. The different mutant Tat proteins were characterized for their abilities to activate the HIV LTR and inhibit the function of wild-type Tat in trans. A Tat protein containing a deletion of the basic domain (Tat(delta)49-57) localized exclusively to the cytoplasm of transfected human cells was nonfunctional and inhibited both HIV-1 and HIV-2 Tat function in a transdominant manner. Tat proteins containing mutations in the cysteine-rich and core domains were nonfunctional but failed to inhibit Tat function in trans. When Tat nuclear or nucleolar localization signals were fused to the carboxy terminus of Tat(delta)49-57, the chimeric proteins localized to the nucleus or nucleolus, respectively, and remained capable of acting in a transdominant manner. Introduction of secondary mutations in the cysteine-rich and core domains of the various transdominant Tat proteins completely eliminated their abilities to act in a transdominant fashion. Our data best support a mechanism in which these transdominant Tat proteins squelch a cellular factor or factors that interact with the Tat activation domain and are required for Tat to function.     

HIV-1 transactivator protein Tat induces proliferation and TGF beta expression in human articular chondrocytes

The human immunodeficiency virus-1 (HIV-1) protein Tat binds to cell surface antigens and can regulate cellular responses. Tat has similar immunosuppressive effects as transforming growth factor-beta (TGF beta) and both inhibit lymphocyte proliferation. TGF beta is expressed by primary human articular chondrocytes and is their most potent growth factor. The present study analyzed the interactions of TGF beta and HIV Tat in the regulation of human articular chondrocytes. Synthetic or recombinant full-length Tat (1-86) induced chondrocyte proliferation and this was of similar magnitude as the response to TGF beta. Tat peptides that did not contain the RGD motif had similar chondrocyte stimulatory activity as full-length Tat. Among a series of Tat peptides, peptide 38-62 which contains the basic domain was the only one active, suggesting that this region is responsible for the effects on chondrocyte proliferation. Full-length Tat and peptide 38-62 synergized with TGF beta and induced proliferative responses that were greater than those obtained with any combination of the known chondrocyte growth factors. Further characterization of the interactions between Tat and TGF beta showed that Tat increased synthesis and TGF beta activity and TGF beta 1 mRNA levels. The stimulatory effects of Tat and peptide 38-62 on chondrocyte proliferation were reduced by neutralizing antibodies to TGF beta and by TGF beta antisense oligonucleotides. These results identify a virally encoded protein and a synthetic peptide derived from it as novel and potent chondrocyte growth stimuli which act at least in part through the induction of TGF beta.     

Cutting edge: a short polypeptide domain of HIV-1-Tat protein mediates pathogenesis.

HIV-1 encodes the transactivating protein Tat, which is essential for virus replication and progression of HIV disease. However, Tat has multiple domains, and consequently the molecular mechanisms by which it acts remain unclear. In this report, we provide evidence that cellular activation by Tat involves a short core domain, Tat21-40, containing only 20 aa including seven cysteine residues highly conserved in most HIV-1 subtypes. Effective induction by Tat21-40 of both NF-kappaB-mediated HIV replication and TAR-dependent transactivation of HIV-long terminal repeat indicates that this short sequence is sufficient to promote HIV infection. Moreover, Tat21-40 possesses potent angiogenic activity, further underscoring its role in HIV pathogenesis. These data provide the first demonstration that a 20-residue core domain sequence of Tat is sufficient to transactivate, induce HIV replication, and trigger angiogenesis. This short peptide sequence provides a potential novel therapeutic target for disrupting the functions of Tat and inhibiting progression of HIV disease.