Polymer-stimulated ligation: enhanced blunt- or cohesive-end ligation of DNA or deoxyribooligonucleotides by T4 DNA ligase in polymer solutions.
about
Hexamine cobalt chloride promotes intermolecular ligation of blunt end DNA fragments by T4 DNA ligaseFrom Structure-Function Analyses to Protein Engineering for Practical Applications of DNA LigaseThe statistical-mechanics of chromosome conformation captureRNA captor: a tool for RNA characterizationImpact of macromolecular crowding on DNA replication.Ultrasonic ligation for rapid high-efficiency subcloning in plasmid vectorsConstruction and analysis of a library for random insertional mutagenesis in Streptococcus pneumoniae: use for recovery of mutants defective in genetic transformation and for identification of essential genes.Increasing the efficiency of SAGE adaptor ligation by directed ligation chemistryEffect of polyethylene glycol on the supercoiling free energy of DNA.p lambda Zd39: a new type of cDNA expression vector for low background, high efficiency directional cloningSupramolecular ordering of DNA in the cholesteric liquid crystalline phase: an ultrastructural study.DNA ligases.Sensitive thyroid stimulating antibody (TSAb) assay using polyethylene glycol (PEG)--a review.Regions at the carboxyl end of bacteriophage phi 29 protein p6 required for DNA binding and activity in phi 29 DNA replication.Polymer-stimulated ligation: enhanced ligation of oligo- and polynucleotides by T4 RNA ligase in polymer solutionsCloning of eukaryotic protein synthesis initiation factor genes: isolation and characterization of cDNA clones encoding factor eIF-4A.Ligation with T4 RNA ligase of an oligodeoxyribonucleotide to covalently-linked cross-sectional base-pair analogues of short, normal, and long dimensions.Macromolecular crowding accelerates the cohesion of DNA fragments with complementary termini.Chloramphenicol-inducible gene expression in Bacillus subtilis is independent of the chloramphenicol acetyltransferase structural gene and its promoterTurbo cloning: a fast, efficient method for cloning PCR products and other blunt-ended DNA fragments into plasmids.End-joining long nucleic acid polymersA novel methyl-binding domain protein enrichment method for identifying genome-wide tissue-specific DNA methylation from nanogram DNA samples.Construction of a circular single-stranded DNA template containing a defined lesionIonic strength and magnesium affect the specificity of Escherichia coli and human 8-oxoguanine-DNA glycosylases.Surface-directed DNA condensation in the absence of soluble multivalent cationsStructural complexity of the symbiotic plasmid of Rhizobium leguminosarum bv. phaseoli.Induction of base damages representing a high risk site for double-strand DNA break formation in genomic DNA by exposure of cells to DNA damaging agents.Analysis of the 3' UTR of the ART3 and ART4 gene by 3' inverse RACE-PCR.An improved protocol for genomic sequencing and footprinting by ligation-mediated PCR.Purification of the gam gene-product of bacteriophage Mu and determination of the nucleotide sequence of the gam gene.Effects of temperature on excluded volume-promoted cyclization and concatemerization of cohesive-ended DNA longer than 0.04 Mb.Blunt-ended ligation can be used to produce DNA ladders with rung spacing as large as 0.17 Mb.Mutations in the adenovirus major late promoter: effects on viability and transcription during infection.Molecular cloning using polymerase chain reaction, an educational guide for cellular engineering.A single amino acid alteration in the initiation protein is responsible for the DNA overproduction phenotype of copy number mutants of plasmid R6K.Effect of the 21-bp repeat upstream element on in vitro transcription from the early and late SV40 promoters.Efficient DNA ligation by selective heating of DNA ligase with a radio frequency alternating magnetic field.Novel methods for genetic transformation of natural Bacillus subtilis isolates used to study the regulation of the mycosubtilin and surfactin synthetases.A hairpin plastid genome in barley.Mode of replicon fusion mediated by the duplicated insertion sequence IS21 in Escherichia coli.
P2860
Q24624213-C6455776-AC86-437D-8FF1-900523D135D4Q26778289-BC87703E-C549-4508-AE9C-C9F31F04A3EDQ28298852-4FEBC966-F981-44FE-8529-E27863EE705EQ28477749-73A0F07C-92E8-42A6-A509-3208FF0C223CQ30428470-7CDBE1F1-E8D5-4DD9-A979-55D4C1AA7A68Q30502177-CA080C42-8604-43EC-925D-B4ED0C7D80D4Q30678058-A598CC8D-7B30-4547-AFD8-F3810D5E8340Q31091673-BEFA4FEA-27DA-447B-B5A8-DBD429789FFCQ31623204-4527E6B1-3C80-4728-BF41-ED7C13FD7901Q33320919-0B9CDE95-307D-4047-A913-1785170052D7Q34019283-4E529B7B-9D4A-44A6-AFFB-93A970BF2584Q34748871-EEC855FD-C45F-4C97-98AF-A61D54C3D34EQ35012650-C94010F6-EAED-4AF8-BE30-5613DEE060A2Q35232445-542B22F8-CCF6-4B11-921A-7CF7680E25B9Q35461666-A6BD3D7C-74B3-4F24-8DB3-DB98C86ABEB1Q35561547-A1198A3C-840C-47F3-A2E3-A5AAEB4ACDF2Q35912665-89AA0F1A-8C36-4123-9520-512B6AAB47C6Q36139037-A75E1101-5613-4CD8-8B82-F517FEA5A918Q36285419-781A4558-9AC7-499D-9818-85D727994C28Q36777947-C546719E-0943-4FB6-A993-6A9BE09C81F5Q36868489-EABB3EB7-DC22-4C46-A035-E25697FB897BQ36923012-02DD3560-AFAF-4EC3-BC4E-883FD80A9505Q37237225-2F76AEFB-242A-4F5D-92C0-42C8DD0487F1Q38290028-414B5494-D13B-4C23-8456-E580775D04F7Q39722523-60D90190-36A0-49EF-B45C-9AE1B6C5127FQ39941185-C2C6F74A-BF49-465E-8019-3532B7ECE85BQ40124888-EC29DC99-BF44-4EA4-B5CC-78ABB96E72DEQ40393924-586C7386-5EA2-49E8-82E6-42B2F9252724Q40407652-2B49C6E7-7658-456B-A680-4A7B222E2C08Q40418427-4B0A6702-9D8D-4AC3-935B-6618E85DFC7EQ40504308-B74DF9F9-62E7-4D7A-A93E-D19226BF6252Q40516880-925DEEA3-AADA-4A6F-9DFF-239F7052563BQ40658747-D0FD8F34-FC0C-48D3-89CC-E0C5D666311DQ41282411-714132EE-AAF7-42C2-9DF4-E6B4849C0133Q41414446-A1E85172-13AE-4FEC-ABFA-D2BCC8308DAEQ41582020-40715E2F-A06A-44C4-98E3-82093FF7B249Q41682555-77B0D7B4-5C03-4BE2-B9AD-1FEE0B9529BDQ41811250-50146E10-3391-444C-8467-C31259C72A19Q42574015-0EBA5FA7-706E-432A-892B-68039D7B0289Q42959994-998355ED-9900-4863-901B-8671BFD03DD3
P2860
Polymer-stimulated ligation: enhanced blunt- or cohesive-end ligation of DNA or deoxyribooligonucleotides by T4 DNA ligase in polymer solutions.
description
1983 nî lūn-bûn
@nan
1983年の論文
@ja
1983年論文
@yue
1983年論文
@zh-hant
1983年論文
@zh-hk
1983年論文
@zh-mo
1983年論文
@zh-tw
1983年论文
@wuu
1983年论文
@zh
1983年论文
@zh-cn
name
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@ast
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@en
type
label
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@ast
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@en
prefLabel
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@ast
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@en
P2860
P356
P1476
Polymer-stimulated ligation: e ...... A ligase in polymer solutions.
@en
P2093
Pheiffer BH
Zimmerman SB
P2860
P304
P356
10.1093/NAR/11.22.7853
P407
P577
1983-11-01T00:00:00Z