Science 11 January 1985: Vol. 227. no. 4683, pp. 171 - 173 DOI: 10.1126/science.2981427

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HIV-1 Tat Mediates Degradation of RON Receptor Tyrosine Kinase, a Regulator of Inflammation.

P. Kalantari, O. F. Harandi, P. A. Hankey, and A. J. Henderson (2008)
J. Immunol. 181, 1548-1555
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Crystal Structures of HIV-1 Tat-derived Nonapeptides Tat-(1-9) and Trp2-Tat-(1-9) Bound to the Active Site of Dipeptidyl-peptidase IV (CD26).

W. A. Weihofen, J. Liu, W. Reutter, W. Saenger, and H. Fan (2005)
J. Biol. Chem. 280, 14911-14917
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Bis-Anthracycline Antibiotics Inhibit Human Immunodeficiency Virus Type 1 Transcription.

O. Kutsch, D. N. Levy, P. J. Bates, J. Decker, B. R. Kosloff, G. M. Shaw, W. Priebe, and E. N. Benveniste (2004)
Antimicrob. Agents Chemother. 48, 1652-1663
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Stimulation of Tat-independent transcriptional processivity from the HIV-1 LTR promoter by matrix attachment regions.

S. Rampalli, A. Kulkarni, P. Kumar, D. Mogare, S. Galande, D. Mitra, and S. Chattopadhyay (2003)
Nucleic Acids Res. 31, 3248-3256
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HIV-1 Tat Protein-mediated Transactivation of the HIV-1 Long Terminal Repeat Promoter Is Potentiated by a Novel Nuclear Tat-interacting Protein of 110 kDa, Tip110.

Y. Liu, J. Li, B. O. Kim, B. S. Pace, and J. J. He (2002)
J. Biol. Chem. 277, 23854-23863
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Outcome of Simian-Human Immunodeficiency Virus Strain 89.6p Challenge following Vaccination of Rhesus Macaques with Human Immunodeficiency Virus Tat Protein.

P. Silvera, M. W. Richardson, J. Greenhouse, J. Yalley-Ogunro, N. Shaw, J. Mirchandani, K. Khalili, J.-F. Zagury, M. G. Lewis, and J. Rappaport (2002)
J. Virol. 76, 3800-3809
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Increased Level of Stromal Cell-Derived Factor-1 mRNA in Peripheral Blood Mononuclear Cells from Children with AIDS-related Lymphoma.

S. Sei, D. P. O'Neill, S. K. Stewart, Q.-e. Yang, M. Kumagai, A. M. Boler, M. A. Adde, S. L. Zwerski, L. V. Wood, D. J. Venzon, et al. (2001)
Cancer Res. 61, 5028-5037
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Development of lentiviral vectors for gene therapy for human diseases.

G. L. Buchschacher Jr and F. Wong-Staal (2000)
Blood 95, 2499-2504
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Human T-Cell Leukemia Virus Type 1 Tax Shuttles between Functionally Discrete Subcellular Targets.

M. Burton, C. D. Upadhyaya, B. Maier, T. J. Hope, and O. J. Semmes (2000)
J. Virol. 74, 2351-2364
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A Second Target for the Peptoid Tat/Transactivation Response Element Inhibitor CGP64222: Inhibition of Human Immunodeficiency Virus Replication by Blocking CXC-Chemokine Receptor 4-Mediated Virus Entry.

D. Daelemans, D. Schols, M. Witvrouw, C. Pannecouque, S. Hatse, S. van Dooren, F. Hamy, T. Klimkait, E. de Clercq, and A.-M. VanDamme (2000)
Mol. Pharmacol. 57, 116-124
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Human Immunodeficiency Virus Type 1 (HIV-1) Vpr Functions as an Immediate-Early Protein during HIV-1 Infection.

M. Hrimech, X.-J. Yao, F. Bachand, N. Rougeau, and E. A. Cohen (1999)
J. Virol. 73, 4101-4109
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The Basic Domain in HIV-1 Tat Protein as a Target for Polysulfonated Heparin-mimicking Extracellular Tat Antagonists.

M. Rusnati, G. Tulipano, C. Urbinati, E. Tanghetti, R. Giuliani, M. Giacca, M. Ciomei, A. Corallini, and M. Presta (1998)
J. Biol. Chem. 273, 16027-16037
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S-Adenosylhomocysteine Hydrolase Inhibitors Interfere with the Replication of Human Immunodeficiency Virus Type 1 through Inhibition of the LTR Transactivation.

D. Daelemans, J. A. Esté, M. Witvrouw, C. Pannecouque, H. Jonckheere, S. Aquaro, C.-F. Perno, E. D. Clercq, and A.-M. Vandamme (1997)
Mol. Pharmacol. 52, 1157-1163
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The N-terminal Structure of HIV-1 Tat Is Required for Suppression of CD26-dependent T Cell Growth.

S. Wrenger, T. Hoffmann, J. Faust, C. Mrestani-Klaus, W. Brandt, K. Neubert, M. Kraft, S. Olek, R. Frank, S. Ansorge, et al. (1997)
J. Biol. Chem. 272, 30283-30288
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Interaction of HIV-1 Tat Protein with Heparin. ROLE OF THE BACKBONE STRUCTURE, SULFATION, AND SIZE.

M. Rusnati, D. Coltrini, P. Oreste, G. Zoppetti, A. Albini, D. Noonan, F. d'A. di Fagagna, M. Giacca, and M. Presta (1997)
J. Biol. Chem. 272, 11313-11320
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HIV-1 Protein Expression from Synthetic Circles of DNA Mimicking the Extrachromosomal Forms of Viral DNA.

A. Cara, A. Cereseto, F. Lori, and M. S. Reitz Jr. (1996)
J. Biol. Chem. 271, 5393-5397
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The HIV-1 TAT Protein Induces the Expression and Extracellular Appearance of Acidic Fibroblast Growth Factor.

S. R. Opalenik, J. T. Shin, J. N. Wehby, V. K. Mahesh, and J. A. Thompson (1995)
J. Biol. Chem. 270, 17457-17467
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Molecular Targets of Gene Transfer Therapy for HIV Infection.

G. L. Buchschacher Jr (1993)
JAMA 269, 2880-2886
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Inhibition of HIV replication in acute and chronic infections in vitro by a Tat antagonist.

M. Hsu, A. Schutt, M Holly, L. Slice, M. Sherman, D. Richman, M. Potash, and D. Volsky (1991)
Science 254, 1799-1802
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Cutaneous T-Cell Lymphoma and Human Immunodeficiency Virus: The Spectrum Broadens.

P. L. Myskowski (1991)
Arch Dermatol 127, 1045-1047
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Rev is necessary for translation but not cytoplasmic accumulation of HIV-1 vif, vpr, and env/vpu 2 RNAs..

S J Arrigo and I S Chen (1991)
Genes & Dev. 5, 808-819
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Analysis of arginine-rich peptides from the HIV Tat protein reveals unusual features of RNA-protein recognition..

B J Calnan, S Biancalana, D Hudson, and A D Frankel (1991)
Genes & Dev. 5, 201-210
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Synergy between HIV-1 Tat and adenovirus E1A is principally due to stabilization of transcriptional elongation..

M F Laspia, A P Rice, and M B Mathews (1990)
Genes & Dev. 4, 2397-2408
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Molecular targets for AIDS therapy.

H Mitsuya, R Yarchoan, and S Broder (1990)
Science 249, 1533-1544
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A bulge structure in HIV-1 TAR RNA is required for Tat binding and Tat-mediated trans-activation..

S Roy, U Delling, C H Chen, C A Rosen, and N Sonenberg (1990)
Genes & Dev. 4, 1365-1373
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A cDNA for a protein that interacts with the human immunodeficiency virus Tat transactivator.

P Nelbock, P. Dillon, A Perkins, and C. Rosen (1990)
Science 248, 1650-1653
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Control of the interferon-induced 68-kilodalton protein kinase by the HIV-1 tat gene product.

S Roy, M. Katze, N. Parkin, I Edery, A. Hovanessian, and N Sonenberg (1990)
Science 247, 1216-1219
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Secondary structure is the major determinant for interaction of HIV rev protein with RNA.

H. Olsen, P Nelbock, A. Cochrane, and C. Rosen (1990)
Science 247, 845-848
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Inhibition of antigen-induced lymphocyte proliferation by Tat protein from HIV-1.

R. Viscidi, K Mayur, H. Lederman, and A. Frankel (1989)
Science 246, 1606-1608
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Human chromosome 12 is required for elevated HIV-1 expression in human-hamster hybrid cells.

C. Hart, C. Ou, J. Galphin, J Moore, L. Bacheler, J. Wasmuth, S. Petteway Jr, and G Schochetman (1989)
Science 246, 488-491
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Comparative analysis of the HTLV-I Rex and HIV-1 Rev trans-regulatory proteins and their RNA response elements..

S M Hanly, L T Rimsky, M H Malim, J H Kim, J Hauber, M Duc Dodon, S Y Le, J V Maizel, B R Cullen, and W C Greene (1989)
Genes & Dev. 3, 1534-1544
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Regulation of HIV and HTLV gene expression..

H Varmus (1988)
Genes & Dev. 2, 1055-1062
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Tat protein from human immunodeficiency virus forms a metal-linked dimer.

A. Frankel, D. Bredt, and C. Pabo (1988)
Science 240, 70-73
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A quantitative bioassay for HIV-1 based on trans-activation.

B. Felber and G. Pavlakis (1988)
Science 239, 184-187
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Expression of the art/trs protein of HIV and study of its role in viral envelope synthesis.

D. Knight, F. Flomerfelt, and J Ghrayeb (1987)
Science 236, 837-840
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Expression and characterization of the trans-activator of HTLV-III/LAV virus.

C. Wright, B. Felber, H Paskalis, and G. Pavlakis (1986)
Science 234, 988-992
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In vivo competition between a metallothionein regulatory element and the SV40 enhancer.

H Scholer, A Haslinger, A Heguy, H Holtgreve, and M Karin (1986)
Science 232, 76-80
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Replicative and cytopathic potential of HTLV-III/LAV with sor gene deletions.

J Sodroski, W. Goh, C Rosen, A Tartar, D Portetelle, A Burny, and W Haseltine (1986)
Science 231, 1549-1553
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Identification of HTLV-III/LAV sor gene product and detection of antibodies in human sera.

N. Kan, G Franchini, F Wong-Staal, G. DuBois, W. Robey, J. Lautenberger, and T. Papas (1986)
Science 231, 1553-1555
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Long-term cultures of HTLV-III--infected T cells: a model of cytopathology of T-cell depletion in AIDS.

D Zagury, J Bernard, R Leonard, R Cheynier, M Feldman, P. Sarin, and R. Gallo (1986)
Science 231, 850-853
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The action of oncogenes in the cytoplasm and nucleus.

R. Weinberg (1985)
Science 230, 770-776
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A Human T-Lymphotropic Retrovirus (HTLV-III) as the Cause of the Acquired Immunodeficiency Syndrome.

R. C. GALLO and F. WONG-STAAL (1985)
Ann Intern Med 103, 679-689
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The pX protein of HTLV-I is a transcriptional activator of its long terminal repeats.

B. Felber, H Paskalis, C Kleinman-Ewing, F Wong-Staal, and G. Pavlakis (1985)
Science 229, 675-679
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Infection of HTLV-III/LAV in HTLV-I-carrying cells MT-2 and MT-4 and application in a plaque assay.

S Harada, Y Koyanagi, and N Yamamoto (1985)
Science 229, 563-566
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cis- and trans-acting transcriptional regulation of visna virus.

J. Hess, J. Clements, and O Narayan (1985)
Science 229, 482-485
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Trans-activator gene of human T-lymphotropic virus type III (HTLV-III).

S. Arya, C Guo, S. Josephs, and F Wong-Staal (1985)
Science 229, 69-73
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Location of the trans-activating region on the genome of human T-cell lymphotropic virus type III.

J Sodroski, R Patarca, C Rosen, F Wong-Staal, and W Haseltine (1985)
Science 229, 74-77
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A transcriptional activator protein encoded by the x-lor region of the human T-cell leukemia virus.

J Sodroski, C Rosen, W. Goh, and W Haseltine (1985)
Science 228, 1430-1434
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Major glycoprotein antigens that induce antibodies in AIDS patients are encoded by HTLV-III.

J. Allan, J. Coligan, F Barin, M. McLane, J. Sodroski, C. Rosen, W. Haseltine, T. Lee, and M Essex (1985)
Science 228, 1091-1094
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Trans activation of the bovine leukemia virus long terminal repeat in BLV-infected cells.

C. Rosen, J. Sodroski, R Kettman, A Burny, and W. Haseltine (1985)
Science 227, 320-322
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More progress on the HTLV family.

J. Marx (1985)
Science 227, 156-157
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Sequence homology and morphologic similarity of HTLV-III and visna virus, a pathogenic lentivirus.

M. Gonda, F Wong-Staal, R. Gallo, J. Clements, O Narayan, and R. Gilden (1985)
Science 227, 173-177
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