Alba shapes the archaeal genome using a delicate balance of bridging and stiffening the DNA.
about
DNA bridging and looping by HMO1 provides a mechanism for stabilizing nucleosome-free chromatin.The Arginine Pairs and C-Termini of the Sso7c4 from Sulfolobus solfataricus Participate in Binding and Bending DNATranscriptional Repressor TrmBL2 from Thermococcus kodakarensis Forms Filamentous Nucleoprotein Structures and Competes with Histones for DNA Binding in a Salt- and DNA Supercoiling-dependent Manner.Effect of temperature on the intrinsic flexibility of DNA and its interaction with architectural proteins.Single-molecule studies on the mechanical interplay between DNA supercoiling and H-NS DNA architectural properties.Chromatin structure and dynamics in hot environments: architectural proteins and DNA topoisomerases of thermophilic archaea.Single-molecule study on histone-like nucleoid-structuring protein (H-NS) paralogue in Pseudomonas aeruginosa: MvaU bears DNA organization mode similarities to MvaTInteractions of archaeal chromatin proteins Alba1 and Alba2 with nucleic acidsMechanochemical regulations of RPA's binding to ssDNA.TrmBL2 from Pyrococcus furiosus Interacts Both with Double-Stranded and Single-Stranded DNA.Diverse architectural properties of Sso10a proteins: Evidence for a role in chromatin compaction and organization.Mechanosensing of DNA bending in a single specific protein-DNA complex.Biochemical and structural insights into RNA binding by Ssh10b, a member of the highly conserved Sac10b protein family in Archaea.Single-molecule observation of DNA compaction by meiotic protein SYCP3.Abundant Lysine Methylation and N-Terminal Acetylation in Sulfolobus islandicus Revealed by Bottom-Up and Top-Down Proteomics.Transcription Regulation in Archaea.Fibrin Networks Support Recurring Mechanical Loads by Adapting their Structure across Multiple Scales.NQO-Induced DNA-Less Cell Formation Is Associated with Chromatin Protein Degradation and Dependent on A0A1-ATPase in Sulfolobus.An Alba-domain protein contributes to the stage-regulated stability of amastin transcripts in Leishmania.Mechanics, thermodynamics, and kinetics of ligand binding to biopolymers.Mechanism of environmentally driven conformational changes that modulate H-NS DNA-bridging activity.Backbone and side-chain (1)H, (15)N and (13)C resonance assignments of two Sac10b family members Mvo10b and Mth10bTQQA from archaea.Accurate nanoscale flexibility measurement of DNA and DNA-protein complexes by atomic force microscopy in liquid.Prespacer processing and specific integration in a Type I-A CRISPR system.Programming the mechanics of cohesive fiber networks by compression.Proteomic Analysis of Methanonatronarchaeum thermophilum AMET1, a Representative of a Putative New Class of Euryarchaeota, "Methanonatronarchaeia".Probing DNA-DNA Interactions with a Combination of Quadruple-Trap Optical Tweezers and Microfluidics.Versatile Quadruple-Trap Optical Tweezers for Dual DNA Experiments.Sliding sleeves of XRCC4-XLF bridge DNA and connect fragments of broken DNA.Lysine acetylation of the Mycobacterium tuberculosis HU protein modulates its DNA binding and genome organization.Transfer-matrix calculations of the effects of tension and torque constraints on DNA-protein interactionsStructure and function of archaeal histones
P2860
Q27933525-6E6329CC-5A1E-48B0-ABA2-E78ED74E7D26Q28469469-48C70891-C7C7-437E-9393-74838D095927Q30381213-DEE2C97D-5426-4C90-811A-7E837DB102BFQ33746195-003538BD-0CD9-4DBF-9B13-EDD99B9A85CBQ33983666-B0B2FA90-8443-453C-BA68-99A246842202Q34358876-BADEFA18-8FC8-4DE0-B09F-F66BA901F6B4Q34457585-86A2153F-BFA0-49A6-9DA1-F6DC3C521524Q34612887-864090E7-15B1-42CE-A54A-F80DAFAE91B0Q35193716-B6403249-D09E-49A6-A761-068415151328Q36026700-A6A6F73A-53B3-44C5-BFA2-F6B408B991A3Q37086763-661BEC1B-127C-4108-9A38-C1320FBBACECQ37393849-7CC8EF7B-818F-442B-9093-D12D01209EEAQ37488472-04C0A5F8-2FB2-444F-AC6C-2614623DC001Q37696795-FB4E6565-9A67-46F6-8DD4-F97CEBAF7A24Q38385366-27708F5A-E20E-4035-8D78-29434DFA079FQ38823441-237BA086-BA44-4634-9070-BABCA87947C3Q39296836-EA64061B-1677-44CF-9DD2-4CDE0F15E441Q41419035-B1ADDA7D-C150-422D-A946-D5E0B70A2936Q42224474-7CD0616D-CD88-41BB-B5BF-3E44A3098F3FQ42292724-F12796D1-1B74-46BC-AFC8-2482048244E3Q42380111-6F528EC7-589E-4727-B3E4-E4FBE7066F20Q43031914-24634775-6F62-45B1-A5D8-2123E18EF78FQ47160782-D0C90CD8-72BF-4578-89D9-797289167C98Q47307199-0DEEE57B-AEEF-45E7-B486-5EEA23BD03E6Q47618791-95EB9793-C0B5-4664-8314-18D7DB7445EFQ48184962-0DBEE82C-2B10-4902-888F-F0CBC3C5A1CDQ51065419-45DF28BD-8083-4624-ACAF-EE2CC42D3745Q51327281-08D34731-53BB-4A07-AF96-BF925020A5FBQ51629423-136BCA8F-F9B8-4B42-838B-B703C7203E75Q54252132-B249F2D8-EE91-47C0-8EDB-173BE3F56F99Q56672978-AFC826C6-8380-424B-A2A8-091D0F717AF2Q58286649-BBCD7BD9-7FA8-49A6-9E23-743A170AB15D
P2860
Alba shapes the archaeal genome using a delicate balance of bridging and stiffening the DNA.
description
2012 nî lūn-bûn
@nan
2012年の論文
@ja
2012年論文
@yue
2012年論文
@zh-hant
2012年論文
@zh-hk
2012年論文
@zh-mo
2012年論文
@zh-tw
2012年论文
@wuu
2012年论文
@zh
2012年论文
@zh-cn
name
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@ast
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@en
type
label
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@ast
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@en
prefLabel
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@ast
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@en
P2093
P2860
P50
P356
P1476
Alba shapes the archaeal genom ...... idging and stiffening the DNA.
@en
P2093
Daan Vorselen
Gijs J L Wuite
Maarten C Noom
Rosalie P C Driessen
P2860
P2888
P356
10.1038/NCOMMS2330
P407
P577
2012-01-01T00:00:00Z