Human T-cell lymphotropic virus type III shares sequence homology with a family of pathogenic lentiviruses.
about
Regulation of the visna virus long terminal repeat in macrophages involves cellular factors that bind sequences containing AP-1 sitesSequences in the visna virus long terminal repeat that control transcriptional activity and respond to viral trans-activation: involvement of AP-1 sites in basal activity and trans-activationVisna virus exhibits a complex transcriptional pattern: one aspect of gene expression shared with the acquired immunodeficiency syndrome retrovirusVisna virus as an in vitro model for human immunodeficiency virus and inhibition by ribavirin, phosphonoformate, and 2',3'-dideoxynucleosidesActivities of (-)-carbovir and 3'-azido-3'-deoxythymidine against human immunodeficiency virus in vitroHuman immunodeficiency virus env expression becomes Rev-independent if the env region is not defined as an intronA morphometric study of bone marrow megakaryocytes in foals infected with equine infectious anemia virus.Molecular cloning of feline immunodeficiency virus.Nucleotide sequence and transcriptional activity of the caprine arthritis-encephalitis virus long terminal repeatBroader HIV-1 neutralizing antibody responses induced by envelope glycoprotein mutants based on the EIAV attenuated vaccine.Nucleotide sequence analysis of feline immunodeficiency virus: genome organization and relationship to other lentiviruses.Relocation of a protease-like gene segment between two retrovirusesCleavage of the HIV replication primer tRNALys,3 in human cells expressing bacterial anticodon nucleaseEmergence of aminoglycoside resistance genes aadA and aadE in the genus CampylobacterExpression of HIV in lymph node cells of LAS patients. Immunohistology, in situ hybridization, and identification of target cellsStability of RNA stem-loop structure and distribution of non-random structure in the human immunodeficiency virus (HIV-I).Identification of a hypervariable region in the long terminal repeat of equine infectious anemia virus.Equine infectious anemia virus derived from a molecular clone persistently infects horses.The visna virus long terminal repeat directs expression of a reporter gene in activated macrophages, lymphocytes, and the central nervous systems of transgenic mice.Change in host cell tropism associated with in vitro replication of equine infectious anemia virus.Separate epitopes in the envelope of visna virus are responsible for fusion and neutralization: biological implications for anti-fusion antibodies in limiting virus replication.Role of the host immune response in selection of equine infectious anemia virus variantsThe visna virus genome: evidence for a hypervariable site in the env gene and sequence homology among lentivirus envelope proteins.Current issues in developing a strategy for dealing with the acquired immunodeficiency syndrome.Infection of the central nervous system by human immunodeficiency virus. Role of the immune system in pathogenesis.Molecular biology and pathogenesis of animal lentivirus infections.Characterization of variable regions in the envelope and S3 open reading frame of equine infectious anemia virus.Purification and characterization of recombinant equine infectious anemia virus reverse transcriptase.Molecular biology and virus-host interactions of lentiviruses.Experience with visna virus in Iceland.Cystatins in health and disease.Bovine immunodeficiency virus: a lentiviral infection.Photosensitization is required for inactivation of equine infectious anemia virus by hypericin.
P2860
Q24634385-E65B6530-6AB5-4F2A-8064-02CE2F4728F1Q24645645-1F229D62-1ECF-4FCF-B3BD-FFE1FAC790ECQ24648639-CFBDFE56-BFBA-4A9D-B9B3-6700E4E74C7BQ24676814-621CCFC4-FED5-4E59-84CE-9F1EA18D36E9Q28335926-06819F8C-6625-46C5-BCD6-712A40A1AF8CQ30452134-FF110755-BD77-4F82-8AC2-3578DC2888B9Q33496855-D1AB776B-9B9B-4A02-B24D-7F566C40FA0AQ33848465-8FCE9260-1313-4655-A19C-005E9EB2B00DQ33927006-56C3F2F6-A29C-41EF-B2B0-5963AFAFBA7DQ34133986-0F283AF5-EA0E-4C9B-8B88-249CBC8042EDQ34313909-6E272472-41BD-4894-B84A-B2FC2306C1CAQ34617236-8C4683EC-28E6-4293-B096-7F6404278E42Q34751283-7B9E54E5-493D-49DB-9511-9BEC21FF50B3Q35264706-B99F71B5-48D8-4531-9718-F3C320E7FD0BQ35819163-0F2C15D9-2828-42F0-BBBE-E6EF14F3B81BQ36008291-25AAD4FB-DA70-470A-8D74-9E3C0B1158D3Q36682900-C6671FD6-9E35-4A11-BB9E-FBF5EBF9A2D7Q36795686-103E600D-C88B-462F-82FA-AE766763B038Q36827163-B2F79AB4-7C9E-475E-8D56-C9612B257E7BQ36828029-2BA96D2F-C0A0-443A-AE3A-29158CA8E999Q36878228-B4EB295C-252B-43A6-8A3D-8F3E660528B0Q36919966-AAA9BAAD-EEE2-4E24-AC47-2D9B1546D037Q36920774-9A1B44C7-79D5-4E7F-91C0-C9CA28703E21Q37410532-02BB0558-A2A7-439F-BA4D-5F3257103BE2Q39550559-49222CBE-0D72-43B3-B294-1220C4148788Q39820667-2FA3D109-E1A6-4631-A350-2AE690ADA23CQ40106270-7B2E7A0A-5C66-4849-8344-C334DD4709BFQ40115966-24ADB49D-A9CC-4070-A39F-C477F188D602Q40671323-072AE019-8FFF-4088-9764-2B9969AAA66FQ40671405-48ACF6DF-EF30-4428-B35F-1A51A057DFCFQ41161690-6799351B-CBB7-469A-8F18-A0820166E50CQ41812731-2AB9DA3A-3CE0-4276-BCEF-C1479550D77EQ43467158-1CF5F6E3-B261-4B53-8BF0-083B0CEB42A0
P2860
Human T-cell lymphotropic virus type III shares sequence homology with a family of pathogenic lentiviruses.
description
1986 nî lūn-bûn
@nan
1986年の論文
@ja
1986年論文
@yue
1986年論文
@zh-hant
1986年論文
@zh-hk
1986年論文
@zh-mo
1986年論文
@zh-tw
1986年论文
@wuu
1986年论文
@zh
1986年论文
@zh-cn
name
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@ast
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@en
type
label
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@ast
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@en
prefLabel
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@ast
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@en
P2093
P2860
P356
P1476
Human T-cell lymphotropic viru ...... ly of pathogenic lentiviruses.
@en
P2093
F Wong-Staal
J E Clements
R V Gilden
P2860
P304
P356
10.1073/PNAS.83.11.4007
P407
P50
P577
1986-06-01T00:00:00Z