Reversal of charge selectivity in transmembrane protein pores by using noncovalent molecular adapters. - Wikidata - awgldk - TriplyDB

Reversal of charge selectivity in transmembrane protein pores by using noncovalent molecular adapters.

Reversal of charge selectivity in transmembrane protein pores by using noncovalent molecular adapters.

http://www.wikidata.org/entity/Q35667285

about

Single-nucleotide discrimination in immobilized DNA oligonucleotides with a biological nanopore Recognizing a single base in an individual DNA strand: a step toward DNA sequencing in nanopores Obstructing toxin pathways by targeted pore blockage Molecular bases of cyclodextrin adapter interactions with engineered protein nanopores Molecular Architecture and Functional Analysis of NetB, a Pore-forming Toxin from Clostridium perfringens Functional truncated membrane pores.All-d-Enantiomer of β-Amyloid Peptide Forms Ion Channels in Lipid Bilayers.Encapsulating a single G-quadruplex aptamer in a protein nanocavity Interactions of peptides with a protein pore.Ion channels and bacterial infection: the case of beta-barrel pore-forming protein toxins of Staphylococcus aureus.An aspartate ring at the TolC tunnel entrance determines ion selectivity and presents a target for blocking by large cations.Prolonged residence time of a noncovalent molecular adapter, beta-cyclodextrin, within the lumen of mutant alpha-hemolysin pores.Modeling and simulation of ion channels.Stochastic sensing on a modular chip containing a single-ion channel.Ion selectivity of alpha-hemolysin with beta-cyclodextrin adapter. II. Multi-ion effects studied with grand canonical Monte Carlo/Brownian dynamics simulations.Ion selectivity of alpha-hemolysin with a beta-cyclodextrin adapter. I. Single ion potential of mean force and diffusion coefficient Channel-forming bacterial toxins in biosensing and macromolecule delivery Ion permeation through the alpha-hemolysin channel: theoretical studies based on Brownian dynamics and Poisson-Nernst-Plank electrodiffusion theory Field-dependent effect of crown ether (18-crown-6) on ionic conductance of alpha-hemolysin channels Imaging alpha-hemolysin with molecular dynamics: ionic conductance, osmotic permeability, and the electrostatic potential map Capturing single molecules of immunoglobulin and ricin with an aptamer-encoded glass nanopore.Single molecule sensing by nanopores and nanopore devices Temperature-independent porous nanocontainers for single-molecule fluorescence studies.Electroosmotic enhancement of the binding of a neutral molecule to a transmembrane pore Sequence-dependent gating of an ion channel by DNA hairpin molecules.Ca2+ selectivity of a chemically modified OmpF with reduced pore volume.Functional engineered channels and pores (Review).Steric selectivity in Na channels arising from protein polarization and mobile side chains.Vibrio cholerae cytolysin is composed of an alpha-hemolysin-like core.Single-molecule investigation of G-quadruplex using a nanopore sensor.Nucleobase Recognition by Truncated α-Hemolysin Pores.Model-based prediction of the alpha-hemolysin structure in the hexameric state.Method of creating a nanopore-terminated probe for single-molecule enantiomer discrimination.Single-molecule detection of folding and unfolding of the G-quadruplex aptamer in a nanopore nanocavity.Using ion channel-forming peptides to quantify protein-ligand interactions.Ion channel models based on self-assembling cyclic peptide nanotubes.Base-excision repair activity of uracil-DNA glycosylase monitored using the latch zone of α-hemolysin.Aptamer-encoded nanopore for ultrasensitive detection of bioterrorist agent ricin at single-molecule resolution.Engineered voltage-responsive nanopores.Towards functional bionanomaterials based on self-assembling cyclic peptide nanotubes.

P2860

Q24642095-D9717EB6-36D8-4EFC-9504-81B2877ADB13 Q24678934-B8F80FC5-E2F3-41DE-9808-BF5A2D9776A4 Q26827489-2C947F58-2D4D-48BB-AFD8-F00EEE1B2F55 Q27660599-B4976FB3-AAFC-4C61-BDD9-DDF12881C05F Q27675492-D4D6CE7F-3E7E-4A9B-B5A4-025C99744389 Q30153442-ADFF25AB-B70C-4C08-8418-3B9DA6231C48 Q30155354-406CCEBB-8DC6-43B4-BAA9-38FA9D16FACA Q30157660-6902D236-E2A5-4A16-989E-17ED40761B45 Q30160230-B524894B-BDC4-41BA-8E79-3355F8BEE8F4 Q30164517-5A27C7BD-B8C0-41EB-940C-E6DB8F5237FA Q30165354-D84ED100-DADA-4ED4-AC7D-BE0B5349F91E Q30167810-4C73EF64-1B71-4FBB-999A-A597BD3E541D Q30443341-457DF5D6-3873-4954-86F6-F93AA4B491F8 Q30483163-99899BEB-BAB4-4566-A3AF-FB6B3B7AACDF Q33746942-6B0A7F2F-0543-4ADF-A748-12ED28A31FA7 Q33761288-22CBF0FB-DB7D-4349-A53C-26935DA37924 Q34101821-624926B4-1A37-4D08-92AF-BC6AE0D7DA98 Q34187301-9E88A9CB-775D-4868-AB4D-D1C967626586 Q34187663-A02D9BB0-2533-464E-B74B-ECFCE750033A Q34190556-B194AF89-3B93-4EAA-A5C1-242A723CFC98 Q34436743-169B01D4-C1D7-4CAA-A344-146634C8AE09 Q34436749-DFCAEC77-0226-4FB3-8018-1B13B7015CE7 Q34679999-15D6338F-FEF3-42BE-9539-88ECF9E77F75 Q34788623-42C698AE-D096-472C-90E3-0E6C5B08F6D9 Q35225466-206515AF-9748-4AAE-990E-B2B4A39D6BA1 Q35606677-06F2BB47-4E50-472A-9602-F3BFAAD81ED2 Q35889039-44FD4290-9C75-4C92-887A-EA832536FD87 Q35963392-F9211F1F-9434-4185-9CF3-93047744AD6D Q36559789-AE12C974-60FF-4F08-8873-0D8AAA904E3E Q36611086-BE3FCBD3-E5BE-479D-B12C-3AFDDB07835C Q36793928-497B44F5-4120-4BB4-AB1C-8960D8355C72 Q36838918-981FC546-5116-4840-B50D-51FF4474CE3E Q37096780-1BC8E5FB-A929-45F5-BA98-03CE9FEE23D9 Q37108469-506D42C0-7F78-402A-8278-1FC17E711424 Q37217062-595D68D1-62B8-40E7-829E-9364251CCD65 Q37402188-E4C20857-26DD-483D-B525-FF14A06E1EF7 Q37528111-AC1D52EC-8891-4A73-AB3A-86E244E06762 Q37645179-B2B2A837-E9DC-447B-A7EB-D50EA00FA86C Q37697552-5B584BB4-BF08-4D6C-896D-C10D8D0DE670 Q37737076-DD9D2961-E6F7-49AD-9447-25CAC6034215

P2860

Reversal of charge selectivity in transmembrane protein pores by using noncovalent molecular adapters.

http://www.wikidata.org/entity/Q35667285

description

2000 nî lūn-bûn

@nan

2000年の論文

@ja

2000年論文

@yue

2000年論文

@zh-hant

2000年論文

@zh-hk

2000年論文

@zh-mo

2000年論文

@zh-tw

2000年论文

@wuu

2000年论文

@zh

2000年论文

@zh-cn

name

Reversal of charge selectivity ...... oncovalent molecular adapters.

@ast

Reversal of charge selectivity ...... oncovalent molecular adapters.

@en

type

label

Reversal of charge selectivity ...... oncovalent molecular adapters.

@ast

Reversal of charge selectivity ...... oncovalent molecular adapters.

@en

prefLabel

Reversal of charge selectivity ...... oncovalent molecular adapters.

@ast

Reversal of charge selectivity ...... oncovalent molecular adapters.

@en

P1433

Q35667285-C9B216F7-37F7-4F13-8DD3-A2BCC2A67084

P1476

Q35667285-DA63578E-37B2-4272-B4C5-DEF59DAC5AE3

P2093

Q35667285-115F5BEC-454B-48F6-987F-E50823FEFC61

Q35667285-536365EA-F4C0-4A6F-865E-8D0098BDAE52

Q35667285-747ECE16-2593-456C-9BC5-81C2E58E0595

Q35667285-8195955D-FFE1-4FBC-8C53-AC40ECAAD3D3

Q35667285-A59ADE7E-4098-4A8D-86B7-875D7708B0D5

Q35667285-A70418F6-0E13-488D-AD29-C3D8911A3A4A

P2860

Q35667285-0E1E9F38-34CD-48F0-89F8-C47FF8140FE0

Q35667285-110D50A2-50F4-421A-8FAD-54F8ABE0A24A

Q35667285-135F0A67-585E-4C2A-9D99-734662113184

Q35667285-139BA651-C657-4867-9A05-D2A50DB38A0D

Q35667285-17D48F07-7258-4D0A-91E3-57BBA4532633

Q35667285-1A20913F-B1EB-4578-835A-93492006F8A8

Q35667285-2DCCE1D1-F619-4313-A050-AA4041D2788B

Q35667285-3017CE91-2F24-4EB1-B735-FBAD39ECE196

Q35667285-390CBDCE-1A04-476E-9AAF-0391FF582324

Q35667285-3E029463-8DBE-4E6B-88E6-DFF864EA7A60

P304

Q35667285-D8F1E3FD-8385-4A5F-9309-A36CAE312657

P31

Q35667285-96AB58BC-93AD-4896-9B82-7BB37999DD09

P356

Q35667285-C9BCB021-6E38-48A6-91A9-0C0530941888

P407

Q35667285-9C31A88A-AF75-4947-AFF4-FB7D322B1FC0

P433

Q35667285-BDDE1261-3C67-42EE-9B0F-B56893C0235A

P478

Q35667285-CA740CF7-A52B-4EC0-9784-1CD6D7E85BFA

P50

Q35667285-E4F1CD8C-935D-456E-84B4-171885F27986

P577

Q35667285-EBB1EEBB-A1FA-48E6-AD99-B6AD4717FBEB

P5875

Q35667285-C23AD1E3-C09C-4A56-99AE-31D0804C14CE

P698

Q35667285-CEBDD45F-2E5F-4F44-916E-BC9476C2910B

P921

Q35667285-90134B5E-AB23-455B-B902-364CD16A17E1

P932

Q35667285-CCD3FE8C-B846-4073-9049-77176EDDD7FF

P356

P1433

Proceedings of the National Academy of Sciences of the United States of America

P1476

Reversal of charge selectivity ...... oncovalent molecular adapters.

@en

P2093

G Vigh

http://www.w3.org/2001/XMLSchema#string

J B Vincent

http://www.w3.org/2001/XMLSchema#string

L Q Gu

http://www.w3.org/2001/XMLSchema#string

M Dalla Serra

http://www.w3.org/2001/XMLSchema#string

O Braha

http://www.w3.org/2001/XMLSchema#string

S Cheley

http://www.w3.org/2001/XMLSchema#string

P2860

The Structure of the Potassium Channel: Molecular Basis of K+ Conduction and Selectivity

Characterization of individual polynucleotide molecules using a membrane channel

Structure of staphylococcal alpha-hemolysin, a heptameric transmembrane pore

Crystal structure of the anthrax toxin protective antigen

A functional protein pore with a "retro" transmembrane domain.

General and specific porins from bacterial outer membranes.

Designed membrane channels and pores.

Mechanisms of solute transport through outer membrane porins: burning down the house.

Progress and prospects in permeation.

Ionic hopping defended.

P304

3959-3964

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1073/PNAS.97.8.3959

http://www.w3.org/2001/XMLSchema#string

P407

P433

8

http://www.w3.org/2001/XMLSchema#string

P478

97

http://www.w3.org/2001/XMLSchema#string

P50

P577

2000-04-01T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

12556687

http://www.w3.org/2001/XMLSchema#string

P698

10760267

http://www.w3.org/2001/XMLSchema#string

P921

transmembrane protein

P932

18124

http://www.w3.org/2001/XMLSchema#string