Continuous tissue culture cell lines derived from chemically induced tumors of Japanese quail.
about
Molecular cloning and functional characterization of a new Cap'n' collar family transcription factor Nrf3Murine and human T-lymphocyte GATA-3 factors mediate transcription through a cis-regulatory element within the human T-cell receptor delta gene enhancerPoint mutations in the avian sarcoma/leukosis virus 3' untranslated region result in a packaging defectRNA dimerization defect in a Rous sarcoma virus matrix mutant.Myb and Ets proteins cooperate in transcriptional activation of the mim-1 promoterThe cytoplasmic domain of the cell adhesion molecule uvomorulin associates with three independent proteins structurally related in different speciesKeap1 represses nuclear activation of antioxidant responsive elements by Nrf2 through binding to the amino-terminal Neh2 domainTropomyosin is decreased in transformed cellsInteraction and functional collaboration of p300 and C/EBPbetaBach proteins belong to a novel family of BTB-basic leucine zipper transcription factors that interact with MafK and regulate transcription through the NF-E2 siteDistinct domains of MuSK mediate its abilities to induce and to associate with postsynaptic specializationsSmall Maf proteins heterodimerize with Fos and may act as competitive repressors of the NF-E2 transcription factorTranscription factor BACH1 is recruited to the nucleus by its novel alternative spliced isoformViral DNA synthesis defects in assembly-competent Rous sarcoma virus CA mutants.Analysis of cellular integration sites in avian sarcoma virus infected duck embryo cells.Molecular cloning of avian sarcoma virus closed circular DNA: structural and biological characterization of three recombinant clones.Unusual features of integrated cDNAs generated by infection with genome-free retroviruses.Accumulation of spliced avian retrovirus mRNA is inhibited in S-adenosylmethionine-depleted chicken embryo fibroblastsInterplay between the alpharetroviral Gag protein and SR proteins SF2 and SC35 in the nucleus.Molecular determinants of adaptation of highly pathogenic avian influenza H7N7 viruses to efficient replication in the human hostTransformation by v-Myb.Specific activation in jun-transformed avian fibroblasts of a gene (bkj) related to the avian beta-keratin gene familyAvian reticuloendotheliosis virus strain A and spleen necrosis virus do not infect human cells.Relationship between retroviral DNA-integration-site selection and host cell transcription.An Mpsi-containing heterologous RNA, but not env mRNA, is efficiently packaged into avian retroviral particles.Transcription factor cCP2 controls gene expression in chicken embryonic stem cells.trans-acting inhibition of genomic RNA dimerization by Rous sarcoma virus matrix mutantsIdentification of key residues in subgroup A avian leukosis virus envelope determining receptor binding affinity and infectivity of cells expressing chicken or quail Tva receptor.Characterization of endogenous avian leukosis viruses in chicken embryonic fibroblast substrates used in production of measles and mumps vaccinesEfficient hepatitis delta virus RNA replication in avian cells requires a permissive factor(s) from mammalian cellsRelationship between retroviral DNA integration and gene expressionDetailed mapping of the nuclear export signal in the Rous sarcoma virus Gag proteinRecombinants between endogenous and exogenous avian tumor viruses: role of the C region and other portions of the genome in the control of replication and transformationLow-molecular-weight RNAs and initiation of RNA-directed DNA synthesis in avian reticuloendotheliosis virus.Packaging cells for avian leukosis virus-based vectors with various host ranges.Interferon regulatory factor 4 contributes to transformation of v-Rel-expressing fibroblastsNuclear entry and CRM1-dependent nuclear export of the Rous sarcoma virus Gag polyprotein.Herpesvirus telomerase RNA (vTR) with a mutated template sequence abrogates herpesvirus-induced lymphomagenesis.Generation of targeted retroviral vectors by using single-chain variable fragment: an approach to in vivo gene delivery.Tripartite structure of the avian erythroblastosis virus E26 transforming gene.
P2860
Q54948940-982132D7-406F-4DAA-B4E3-2599440037E4Q54948941-E8DCFDB6-7378-497A-B3BD-608ABFAF80C5Q54948942-53980D5D-03DF-4B28-959C-85F82135B398Q54948944-6CEA150B-01BE-47B8-B249-7783B9B0B90BQ54948945-87E17076-D105-449A-AC3F-D5BF67FC1378Q54948946-D78241C4-024A-473E-A9F5-B117E3F21FE8Q54948947-4D965536-2020-46DA-A474-A8323258736BQ54948948-EA3CCBB3-2B35-46DC-AE9E-A054B3600A31Q54948949-44290643-44BD-4147-9738-3C741975EFD4Q54948950-1AC128CF-D586-4BB8-A6C5-341F72BFA8FEQ54948951-DD4EC3B2-61E5-43CC-BFEB-0D356C8985BBQ54948952-A355B44D-A27F-4E5E-AA6B-678AFED017FEQ54948953-94D16F00-55CE-40BE-B07B-8232FF8CE835
P1343
Q22008805-82BC6BD5-1964-4267-8A05-BE30AD074C36Q24300369-95E46123-5C79-4E26-A57A-461A747E8124Q24517443-56B61DDA-908E-41F1-9564-02928DE06E0CQ24524289-A63F0706-6DD9-4C69-A88C-903590886E26Q24563107-EE7BA52E-627E-4BCB-ADC2-81095C0E65DEQ24567493-ED6E5B2F-BD35-4224-993A-8FCD48D4DF73Q24609907-47294F8F-FE5D-41AC-A895-9C3E051A031FQ24619780-9B1B7EEA-0DD6-42B7-80F0-6B665CDFD2D1Q24644296-4FC51A8D-D6B7-468D-87DD-5148FE9CA04DQ24647985-ED3810F2-33B4-40BC-B816-40CFF6D5713DQ24680337-38139D51-4B61-4B09-A823-6A380590C126Q26781945-A19D8C55-44AA-42BA-A6D8-606161DEFBABQ28143317-5AA668E8-E6DE-44A1-8370-365CAA023CF3Q30327614-6EF626A3-FDAC-40DA-BC95-65D9779BC2D8Q30448882-62C363A6-ED4E-4B20-9F74-0D1F5E985803Q30449565-C431C8B4-F3C1-4A54-BDB7-F94D9194D6A5Q30450358-C872AFAB-1E5A-4631-BBF3-D4C349884576Q30452313-16972E0E-9BD6-4EFF-A2B0-CB6409B1A9E8Q30663968-FB362B5B-1C71-4D6C-8A1C-983D56B9B98CQ33614393-B48E4893-1E3A-48A5-AE64-DC5F6DCD6630Q33667366-91E62C2C-1F3B-4F45-8C60-BDCDE9CD5B17Q33719156-D80FA3C2-00BF-4069-9524-9CE01DA6EC89Q33795485-E1233C0B-9EAF-4237-A45D-9DB21DE8ECEFQ33819592-BF765E80-80B8-4174-A4CC-35092C1A5C28Q33822142-0EB02EBA-3730-4B5A-A6D3-377C80E6EFACQ33832816-44E3E3EB-A898-4642-B5FB-F0EF0C0225FAQ33834799-66DCFEE9-FA4A-4722-A23D-1B3DBB5472BBQ33835427-929530CF-4DCA-4F05-A22D-D624C0110809Q33851129-CF1DBB1F-E34B-4550-B12C-286D3C645DDAQ33852801-1D3C4016-D045-48C1-A453-3315DD0184E1Q33873964-8F9AC97C-DBAF-4F69-AC09-4EBA3B9D9E4CQ33883903-680A634E-1395-4660-A2D9-26CFB96BEC46Q33912163-8D44DE7C-7707-488C-9431-62DB10147755Q33914438-BA42F89B-9414-486B-A954-507F34059D65Q33937664-D343D4B0-A6E5-453B-8447-B6B4BE40E46FQ34012219-BA76FB00-3C89-4B27-86BE-86136905BFEEQ34021302-C2314EDA-C14F-4B38-9B33-CE7F110860E7Q34064216-101D1272-2A1C-4766-AE35-5929F72CAF31Q34066344-2334FBDC-FF4B-44AA-8598-15F64007A228Q34255156-B67161B3-C609-4A25-A96D-A7D5DF8E581D
P2860
Continuous tissue culture cell lines derived from chemically induced tumors of Japanese quail.
description
1977 nî lūn-bûn
@nan
1977年の論文
@ja
1977年論文
@yue
1977年論文
@zh-hant
1977年論文
@zh-hk
1977年論文
@zh-mo
1977年論文
@zh-tw
1977年论文
@wuu
1977年论文
@zh
1977年论文
@zh-cn
name
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@en
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@nl
type
label
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@en
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@nl
prefLabel
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@en
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@nl
P2093
P4510
P1433
P1476
Continuous tissue culture cell ...... uced tumors of Japanese quail.
@en
P2093
P304
P356
10.1016/0092-8674(77)90320-8
P407
P50
P577
1977-05-01T00:00:00Z