Enantiorecognition in a multi-component environment

被引:0
|
作者
Mazurkiewicz, Joanna [1 ,2 ]
Stanek, Ewa [2 ,3 ]
Maximiano, Pedro [4 ]
Ferreira, Tiago H. [4 ]
Karpiel, Marta [1 ,2 ]
Buda, Szymon [1 ]
Kalinowska-Tluscik, Justyna [1 ]
Simoes, Pedro N. [4 ]
Reva, Igor [4 ]
Kaczor, Agnieszka [1 ]
机构
[1] Jagiellonian Univ, Fac Chem, 2 Gronostajowa Str, PL-30387 Krakow, Poland
[2] Jagiellonian Univ, Doctoral Sch Exact & Nat Sci, 11 Lojasiewicza Str, PL-30348 Krakow, Poland
[3] Jagiellonian Univ, Jagiellonian Ctr Expt Therapeut JCET, 14 Bobrzynskiego Str, PL-30348 Krakow, Poland
[4] Univ Coimbra, Dept Chem Engn, CERES, R Silvio Lima, P-3030790 Coimbra, Portugal
来源
PHYSICAL CHEMISTRY CHEMICAL PHYSICS | 2025年 / 27卷 / 09期
关键词
MOLECULAR-ORBITAL METHODS; BASIS-SET; APPROXIMATION; ASTAXANTHIN; ENERGIES; DYNAMICS; BINDING; BOVINE;
D O I
10.1039/d5cp00022j
中图分类号
O64 [物理化学(理论化学)、化学物理学];
学科分类号
070304 ; 081704 ;
摘要
We demonstrate that enantiopreference in the binding of S,S over R,R astaxanthin (AXT) to albumin manifests itself only for racemic (but not enantiopure) carotenoids. The observed enantioselectivity is rationalized using chiroptical spectroscopies supported by molecular docking, molecular dynamics and quantum-chemical calculations. These methods offer a plausible explanation for the observed enantiopreference, as they reveal a unique binding mode of the (3S,3 ' S)-AXT form with the protein in contrast to multiple (random) possibilities for albumin binding with the (3R,3 ' R)-AXT, and also a higher interaction energy of the latter enantiomer with the protein.
引用
收藏
页码:4905 / 4914
页数:10
相关论文
共 50 条
  • [41] Modelling of Compressible Multi-Component Two-Phase Flow with Multi-Component Navier Boundary Condition
    Wang, Junkai
    He, Qiaolin
    COMMUNICATIONS IN COMPUTATIONAL PHYSICS, 2024, 36 (04) : 1053 - 1089
  • [42] The multi-component TA hierarchy and its multi-component integrable couplings system with six arbitrary functions
    Xia, TC
    You, FC
    CHAOS SOLITONS & FRACTALS, 2005, 26 (02) : 605 - 613
  • [43] Incorporating hysteresis in a multi-phase multi-component NAPL modelling framework; a multi-component LNAPL gasoline example
    Lari, Kaveh Sookhak
    Davis, Greg B.
    Johnston, Colin D.
    ADVANCES IN WATER RESOURCES, 2016, 96 : 190 - 201
  • [44] at]Effects of Component Commonality in Multi-Component Inventory Models
    Vu Tung Dang
    Nagen Nagarur
    OPSEARCH, 2000, 37 (4) : 294 - 315
  • [45] Multi-Component V2X Applications Placement in Edge Computing Environment
    Shaer, Ibrahim
    Haque, Anwar
    Shami, Abdallah
    ICC 2020 - 2020 IEEE INTERNATIONAL CONFERENCE ON COMMUNICATIONS (ICC), 2020,
  • [46] Multi-component Models for Object Detection
    Gu, Chunhui
    Arbelaez, Pablo
    Lin, Yuanqing
    Yu, Kai
    Malik, Jitendra
    COMPUTER VISION - ECCV 2012, PT IV, 2012, 7575 : 445 - 458
  • [47] Kinetic effects of multi-component nucleation
    Kurasov, V
    PHYSICA A-STATISTICAL MECHANICS AND ITS APPLICATIONS, 2005, 353 : 159 - 216
  • [48] Architecture of multi-component copolymer brushes
    Ishizu, K
    Tsubaki, K
    Satoh, J
    Uchida, S
    DESIGNED MONOMERS AND POLYMERS, 2002, 5 (01) : 23 - 38
  • [49] Antimicrobial properties of a multi-component alloy
    Anne F. Murray
    Daniel Bryan
    David A. Garfinkel
    Cameron S. Jorgensen
    Nan Tang
    WLNC Liyanage
    Eric A. Lass
    Ying Yang
    Philip D. Rack
    Thomas G. Denes
    Dustin A. Gilbert
    Scientific Reports, 12
  • [50] Manufacturing processes of multi-component gearwheels
    R. Meissner
    T. Benkert
    M. Hiller
    M. Liewald
    W. Volk
    Forschung im Ingenieurwesen, 2017, 81 : 265 - 269
12345