Genetic Recombinations Leading to Production of Active Bacteriophage from Ultraviolet Inactivated Bacteriophage Particles.
about
The properties of x-ray inactivated bacteriophage. I. Inactivation by direct effectMultiplicity reactivation of reovirus particles after exposure to ultraviolet lightDeoxyribonucleic acid repair in bacteriophageStudies on host-virus interactions in the chick embryo-influenza virus system. VI. Evidence for multiplicity reactivation of inactivated virusWidespread recombination, reassortment, and transmission of unbalanced compound viral genotypes in natural arenavirus infectionsEffect of particle aggregation on the survival of irradiated vaccinia virus.The transcription factor titration effect dictates level of gene expression.Effect of transcription factor resource sharing on gene expression noiseStatistical mechanical model of coupled transcription from multiple promoters due to transcription factor titration.On the Interpretation of Multi-Hit Survival Curves.Unity of the Vegetative Pool in Phage-Infected BacteriaCross Reactivation of Genetic Loci of T2 Bacteriophage after Decay of Incorporated Radioactive Phosphorus.Partial replicas of UV-irradiated bacteriophage T4 genomes and their role in multiplicity reactivation.The Mechanism of Genetic Recombination in Phage.Ultraviolet mutagenesis in bacteriophage T-4. I. Irradiation of extracellular phage particles.A critical test of the recombination theory of multiplicity reactivation.Mutual exclusion between related phages.Classification of bacterial viruses: characteristics of the T5 species and of the T2, C16 speciesResistance to ultraviolet light as an index to the reproduction of bacteriophage.Characterization of some pneumococcal bacteriophages.Inactivation of bacteriophage T4 by ethyl methanesulfonate: influence of host and viral genotypesGenetic control of capsid length in bacteriophage T4. I. Isolation and preliminary description of four new mutantsClassification of bacterial viruses: characteristics of the T1,D20 species of coli-dysentery phages.Genetic studies on capsid-length determination in bacteriophage T4. I. Isolation and partial characterization of second-site revertants of a gene 23 mutation affecting capsid length.The phage mating theory, with lessons for yeast geneticists.Chromatin staining of bacteria during bacteriophage infectionSalvador Luria and Max Delbrück on Random Mutation and Fluctuation Tests.Partial reactivation of chlorine-treated echovirus.Intracellular localization and effects on cell division of a plasmid blocked in deoxyribonucleic acid replication.ISOLOGOUS INTERFERENCE WITH ULTRAVIOLET AND X-RAY IRRADIATED BACTERIOPHAGE T2.HOMOLOGOUS INHIBITION, TOXICITY, AND MULTIPLICITY REACTIVATION WITH ULTRAVIOLET-IRRADIATED VACCINIA VIRUS.Some biological properties of bacteriophages S13 and theta X-174.Variation in influenza viruses.The synthesis of nucleic acid by virus-infected bacteriaA preliminary study of the bacteriophages of Pseudomonas aeruginosa.The nucleus of Saccharomyces; a cytological study of a frozen-dried polyploid series.The relation between the synthesis of deoxyribonucleic acid and the synthesis of protein in the multiplication of bacteriophage T2.Reactivation of non-infective virus in a cortisone-injected host.
P2860
Q24630813-0B203B37-D361-4482-91A2-81A9F09869ADQ24651304-2D5AF6BC-1BE1-41CC-9CB7-E353AF99C814Q24655117-CD6A0435-5E6B-4301-827F-A76FFC55A8BBQ24680939-9D11B160-6F52-4BA8-8A64-A2858850E6E5Q27319869-5C91AA4E-2649-4F57-A01C-D05698EFAA11Q30450939-73B2BED2-4423-4963-90F3-480AF633AE25Q30582620-57D0401F-ACE2-44B4-B90C-D8224F46821FQ33621017-E8D277AD-E8E3-47C0-B776-D56FF953AEA0Q33707494-1B4369D8-7CD7-484B-90ED-E7E9F29D939EQ33710289-1B17AAF7-1983-4617-AB30-B8F582912505Q33713678-AB8995A1-7B70-4224-A3F6-BCCBF552A13FQ33714205-F541EBA3-D908-4580-BA84-9BAC19BF3257Q33923888-39C8BFD2-80BD-4EDC-97B4-9E4C9C9C307BQ33975555-156A56F5-129D-4C80-8F66-F800EB85ACFBQ35179727-D28AFFD1-70AD-49AF-9B56-ED8021C6E4B4Q35212304-97CBA52E-30D7-4397-9E53-AE5AFBFCA617Q35212321-23BF58A5-8DB7-4AB7-B541-F9D025DE4EE1Q35214536-595B629F-3EED-4B36-A213-ED3000E8D595Q35222617-1CC66D24-1FFB-4A41-ACD5-D44B29C97029Q36545134-68B749A5-C4B6-4D64-BDE7-434A66720CBDQ36584264-A8924489-C3AD-4FEA-81A0-9FAFAC9B8AE4Q36592466-D5E7B5F3-C6CC-4022-ACB7-5EFC6B6F21E9Q36622509-77D29B23-A473-453C-91DE-481CEC2C2197Q36923355-8F7F2638-2920-4678-9183-DE4596BAA989Q37270134-1C6154CF-D9A6-48D1-98C3-A84946E71BCFQ37380236-E1237C14-C7AB-480A-84F0-759F919BCA75Q38942172-B1475977-ECF4-4FAE-93F9-10CA5069EE9CQ39255329-B48B8C60-C031-43AD-936C-96898CBFF208Q39989046-B07448C7-73E4-4463-AAB6-0934FD01114BQ40248869-A87D7CDF-ED19-4A14-AC47-8D5C158C849CQ40254793-3B19334B-C4B4-43EF-B6C3-ECA7AF200404Q40314269-A4CA49A8-6A05-4341-BD8E-F77704F7994EQ41007305-5D995716-0573-4A8E-B41E-4F17D57B4C5AQ41007459-97910651-9754-4E4E-8361-D531EF629C73Q41943038-84A73163-AF14-416B-BA4B-37C821967A89Q42036154-85380D66-6C37-402E-B473-AE2B5A270E45Q42132600-BBC7BCBB-B546-4349-BA17-45359ACC2827Q42821850-3672E04D-D66F-4078-9D9A-3320B04481D9
P2860
Genetic Recombinations Leading to Production of Active Bacteriophage from Ultraviolet Inactivated Bacteriophage Particles.
description
1949 nî lūn-bûn
@nan
1949 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
1949 թվականի մարտին հրատարակված գիտական հոդված
@hy
1949年の論文
@ja
1949年論文
@yue
1949年論文
@zh-hant
1949年論文
@zh-hk
1949年論文
@zh-mo
1949年論文
@zh-tw
1949年论文
@wuu
name
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@ast
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@en
type
label
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@ast
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@en
prefLabel
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@ast
Genetic Recombinations Leading ...... vated Bacteriophage Particles.
@en
P2860
P1433
P1476
Genetic Recombinations Leading ...... ivated Bacteriophage Particles
@en
P2093
P2860
P304
P407
P577
1949-03-01T00:00:00Z