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Like-charge guanidinium pairing from molecular dynamics and ab initio calculations.Guanidinium can both Cause and Prevent the Hydrophobic Collapse of Biomacromolecules.Molecular mechanisms of ion-specific effects on proteins.Effects of End Group Termination on Salting-Out Constants for Triglycine.Ion specific effects of alkali cations on the catalytic activity of HIV-1 protease.A temperature-dependent implicit-solvent model of polyethylene glycol in aqueous solution.Specific interactions of ammonium functionalities in amino acids with aqueous fluoride and iodide.Effect of association with sulfate on the electrophoretic mobility of polyarginine and polylysine.Attractive interactions between side chains of histidine-histidine and histidine-arginine-based cationic dipeptides in water.Ion specificity at the peptide bond: molecular dynamics simulations of N-methylacetamide in aqueous salt solutions.Specificity of ion-protein interactions: complementary and competitive effects of tetrapropylammonium, guanidinium, sulfate, and chloride ions.Reversal of the hofmeister series: specific ion effects on peptides.The molecular origin of like-charge arginine-arginine pairing in water.Ion-specific interactions between halides and basic amino acids in water.Behavior of β-amyloid 1-16 at the air-water interface at varying pH by nonlinear spectroscopy and molecular dynamics simulations.Surface behavior of hydrated guanidinium and ammonium ions: a comparative study by photoelectron spectroscopy and molecular dynamics.Self-association of a highly charged arginine-rich cell-penetrating peptide.Beyond the Hofmeister Series: Ion-Specific Effects on Proteins and Their Biological Functions.Cation-specific effects on enzymatic catalysis driven by interactions at the tunnel mouth.Thermodynamic description of Hofmeister effects on the LCST of thermosensitive polymers.Lower critical solution temperature (LCST) phase behaviour of an ionic liquid and its control by supramolecular host-guest interactions.Tuning the critical solution temperature of polymers by copolymerization.An instant multi-responsive porous polymer actuator driven by solvent molecule sorption.Like-charged protein-polyelectrolyte complexation driven by charge patches.Arginine "Magic": Guanidinium Like-Charge Ion Pairing from Aqueous Salts to Cell Penetrating PeptidesRationalizing Polymer Swelling and Collapse under Attractive Cosolvent ConditionsThermodynamic Description of the LCST of Charged Thermoresponsive CopolymersGuanidinium Cations Pair with Positively Charged Arginine Side Chains in WaterCharacterization of the triple ion [ ( CH 3 ) 4 N + · PF 6 - · ( CH 3 ) 4 N + ] in the gas-phaseTwo Tryptophans Are Better Than One in Accelerating Electron Flow through a ProteinThermodynamics of N-Isopropylacrylamide in Water: Insight from Experiments, Simulations, and Kirkwood-Buff Analysis TeamworkHole Hopping Across a Protein-Protein InterfaceTuning the collapse transition of weakly charged polymers by ion-specific screening and adsorption
P50
Q30404399-3F71EE1F-B180-41F9-9451-D2810AD0A171Q33878923-8D3796E8-AD9B-483A-B121-5ABC8B9037E9Q34300136-61F9C79E-1F54-41F9-8FDB-20524D24A61CQ37503451-A7A3C799-9311-4942-B838-39E71ED5FF96Q42288628-D0056602-4D09-4D0C-8A8B-6371489C289AQ42696171-4F74A8F4-5222-44B5-9812-55206DD72F67Q42861353-4B465C25-CA04-4B4C-BABF-6A097420CA3EQ42931288-A9E3E087-416E-4FC6-857F-34FC53BB0725Q43029586-1FF67BCC-93CD-4286-B470-350E3E8D18B7Q43206395-9A3F75AC-849B-450A-B486-08190D350C65Q43285885-A27DFDE4-CF29-4194-9E9A-0852B456CB3BQ46038267-4E9FF093-DED6-4486-9811-1AD38949AA9EQ46056984-BFBD4D90-CDBD-4E44-923E-60C454FE910DQ46216296-91DDB173-D2E5-41FC-B032-E05F6F480A8AQ46334370-CBCE9A4D-C924-4642-A3FD-7ECEFD2D6E9AQ46887664-E332D247-20C8-44AD-878B-14A64B51B17FQ47407772-82A810A7-0A28-414E-AA85-B5EC95398857Q48345747-58557A4E-A69C-425E-BA1A-933917A1E2ABQ51032823-DFAE59F7-3453-4F46-8385-5FBFA663DDF4Q51051793-BA4E6E0C-B565-4455-A2F1-776ED4DB45D3Q52851577-D0F302EB-6842-4827-9D2D-D23F41B9C9F6Q52858182-081CC5FF-D084-4679-B136-3084688E8C4AQ52875772-C6A151D1-0DA5-49F6-9C61-6B1A7ED9DB28Q53578944-882ACE9C-49E7-4B60-938F-0A6B0AA35AE6Q57120945-53EAF485-0B3A-4DB5-8894-A9FB52123AC2Q57362219-C2F9AD39-1401-4FF6-875D-BB66B878A0B9Q57362321-4AC3A110-A5F2-4EA2-8113-21342C2F525FQ59706179-16F69B86-099D-4426-9DCE-90C1A5E6ED6DQ59706219-FF087A7E-53AF-4BCC-B0B9-C506825FB293Q61450546-19BFE649-C953-4123-AC5E-5C94DB161D62Q89969112-1DC6BD2D-4EC9-401B-9EF4-7002A6C52482Q91179846-EF3F87C5-BE53-471E-B8F8-5899846A2C67Q93235306-E6D89CB5-7E4D-4830-8E14-17E930BCC5C8
P50
description
Czech chemist
@en
Czech chemist
@en-ca
Czech chemist
@en-gb
Tšehhi keemik
@et
chimist ceh
@ro
chimiste tchèque
@fr
kimist çek
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químic txec
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químico checo
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químico checo
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name
Jan Heyda
@ast
Jan Heyda
@cs
Jan Heyda
@en
Jan Heyda
@es
Jan Heyda
@fr
Jan Heyda
@nl
Jan Heyda
@sk
Jan Heyda
@sl
type
label
Jan Heyda
@ast
Jan Heyda
@cs
Jan Heyda
@en
Jan Heyda
@es
Jan Heyda
@fr
Jan Heyda
@nl
Jan Heyda
@sk
Jan Heyda
@sl
prefLabel
Jan Heyda
@ast
Jan Heyda
@cs
Jan Heyda
@en
Jan Heyda
@es
Jan Heyda
@fr
Jan Heyda
@nl
Jan Heyda
@sk
Jan Heyda
@sl
P69
P106
P2038
P21
P31
P3829
P496
0000-0002-9428-9508
P569
1983-06-18T00:00:00Z