about
Mathematical and computational modeling in biology at multiple scalesMolecular simulations of glycolipids: Towards mammalian cell membrane modelsHydrocarbons Are Essential for Optimal Cell Size, Division, and Growth of CyanobacteriaExchange pathways of plastoquinone and plastoquinol in the photosystem II complex.CHARMM all-atom additive force field for sphingomyelin: elucidation of hydrogen bonding and of positive curvature.Solvent-Free, Highly Coarse-Grained Models for Charged Lipid Systems.The power of coarse graining in biomolecular simulations.Interactions of borneol with DPPC phospholipid membranes: a molecular dynamics simulation study.Multiscale computational models in physical systems biology of intracellular trafficking.Lipid clustering correlates with membrane curvature as revealed by molecular simulations of complex lipid bilayersMembrane-mediated regulation of the intrinsically disordered CD3ϵ cytoplasmic tail of the TCR.Mechanisms of recognition and binding of α-TTP to the plasma membrane by multi-scale molecular dynamics simulations.Dissipative Particle Dynamics Simulations for Phospholipid Membranes Based on a Four-To-One Coarse-Grained Mapping Scheme.HBP Builder: A Tool to Generate Hyperbranched Polymers and Hyperbranched Multi-Arm Copolymers for Coarse-grained and Fully Atomistic Molecular Simulations.Perspective on the Martini model.Ganglioside-Lipid and Ganglioside-Protein Interactions Revealed by Coarse-Grained and Atomistic Molecular Dynamics Simulations."Martinizing" the Variational Implicit Solvent Method (VISM): Solvation Free Energy for Coarse-Grained Proteins.Structural basis for plant plasma membrane protein dynamics and organization into functional nanodomains.Aggregation of lipid-anchored full-length H-Ras in lipid bilayers: simulations with the MARTINI force field.Tight cohesion between glycolipid membranes results from balanced water-headgroup interactions.Experimental and molecular dynamics characterization of dense microemulsion systems: morphology, conductivity and SAXS.Computational Lipidomics of the Neuronal Plasma Membrane.Prediction of Thylakoid Lipid Binding Sites on Photosystem II.Multiscale simulations for understanding the evolution and mechanism of hierarchical peptide self-assembly.Lipid self-assembly and lectin-induced reorganization of the plasma membrane.Cholesterol enhances influenza binding avidity by controlling nanoscale receptor clustering.Implicit-solvent dissipative particle dynamics force field based on a four-to-one coarse-grained mapping scheme.The glycolipid GM1 reshapes asymmetric biomembranes and giant vesicles by curvature generation.Lipid-Protein Interactions Are Unique Fingerprints for Membrane Proteins.Histo-blood group antigen-binding specificities of human rotaviruses are associated with gastroenteritis but not with in vitro infection
P2860
Q28082151-2D9DCD8D-5F32-4086-BB4F-4726B4901A33Q28084686-3A71D97C-DB76-4AD4-802C-9D4C31615D94Q28596129-6ED89985-36F0-4EF9-9965-0B7F72398947Q30851421-52132295-7373-426C-B57D-AC8F65A6E516Q33990999-6602D53B-735D-4660-84E4-6EB17296A890Q34337372-4B537ECC-0721-4CBE-8CAC-62BFB65A30D2Q34443159-2426271C-5B9D-4347-9DF4-A63F4DB2B48FQ34685390-906AEBCD-827A-4607-9D94-2930C237AE7AQ35106771-29D7A124-C3D4-45C2-85EC-B31E672BBEFEQ35362110-E2636187-B516-4B78-9E78-01721BD19EBFQ35687020-056CDAC0-F2B2-4175-8309-EBBC58D975E6Q35803641-131DD0B1-266E-45E9-A6E0-D70F91A41C87Q36005993-EDBAB73A-5141-4934-B439-6187969F6CA8Q36910973-6B1A8B74-88A1-4041-81BD-7640C76C5EFAQ38109488-D5FA1FB1-6F48-4CCB-9831-2EA1F93E5EC6Q38290275-407E6684-E4C5-47B9-8346-F7EDB0ABCD3BQ38671138-FC586682-FE06-4D6F-9050-28E9B8BD2784Q41189772-65264908-401D-44A6-B151-59B91A9F0DF0Q41960466-61A49C76-1E01-45C0-8ACB-BD3DC1BE9C4AQ42292691-A7E41060-09F1-46CD-B0BA-8FD0AD8755F5Q43978152-F0E9E789-2AAF-47C8-A459-0C730BFD6971Q46555719-D89FEBC8-A24A-4B46-BB76-5F91D8489103Q47270636-8FEE453A-AACF-4D78-B977-3F33D4BC082EQ50627548-337B4C8D-1EB6-4357-BA97-E6A2B8411CB0Q54199238-F61D85CD-FC26-4568-9D62-4942CE6D6130Q54259338-87680DEB-235F-4442-9A2F-329B6AEEE7C1Q55016246-69EA0546-483C-47B6-8E5F-2D4DF05A2789Q55285479-D7FCB587-3115-4B32-8578-2AF2A2DE1B71Q55432297-1712D814-C928-4942-A7D1-4F4FB9D36D30Q58699643-87C16D78-2D03-47FC-9ED4-8FC448932E9F
P2860
description
2013 nî lūn-bûn
@nan
2013 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2013 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2013年の論文
@ja
2013年論文
@yue
2013年論文
@zh-hant
2013年論文
@zh-hk
2013年論文
@zh-mo
2013年論文
@zh-tw
2013年论文
@wuu
name
Martini Force Field Parameters for Glycolipids.
@ast
Martini Force Field Parameters for Glycolipids.
@en
type
label
Martini Force Field Parameters for Glycolipids.
@ast
Martini Force Field Parameters for Glycolipids.
@en
prefLabel
Martini Force Field Parameters for Glycolipids.
@ast
Martini Force Field Parameters for Glycolipids.
@en
P2093
P356
P1476
Martini Force Field Parameters for Glycolipids
@en
P2093
Alex H de Vries
César A López
Floris J van Eerden
Zofie Sovova
P304
P356
10.1021/CT3009655
P577
2013-02-05T00:00:00Z