Redrawing the Ramachandran plot after inclusion of hydrogen-bonding constraints

被引:71
|
作者
Porter, Lauren L. [1 ]
Rose, George D. [1 ]
机构
[1] Johns Hopkins Univ, TC Jenkins Dept Biophys, Baltimore, MD 21218 USA
来源
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA | 2011年 / 108卷 / 01期
基金
美国国家科学基金会;
关键词
protein folding; hydrogen bonding; beta-turns; helix nucleation; ISOLATED-PAIR HYPOTHESIS; UNFOLDED PROTEINS; BACKBONE; DYNAMICS; SEQUENCE; TURNS; WATER; STEREOCHEMISTRY; CONFORMATIONS; SPECTROSCOPY;
D O I
10.1073/pnas.1014674107
中图分类号
O [数理科学和化学]; P [天文学、地球科学]; Q [生物科学]; N [自然科学总论];
学科分类号
07 ; 0710 ; 09 ;
摘要
A protein backbone has two degrees of conformational freedom per residue, described by its phi,psi-angles. Accordingly, the energy landscape of a blocked peptide unit can be mapped in two dimensions, as shown by Ramachandran, Sasisekharan, and Ramakrishnan almost half a century ago. With atoms approximated as hard spheres, the eponymous Ramachandran plot demonstrated that steric clashes alone eliminate 3/4 of phi,psi-space, a result that has guided all subsequent work. Here, we show that adding hydrogen-bonding constraints to these steric criteria eliminates another substantial region of phi,psi-space for a blocked peptide; for conformers within this region, an amide hydrogen is solvent-inaccessible, depriving it of a hydrogen-bonding partner. Yet, this "forbidden" region is well populated in folded proteins, which can provide longer-range intramolecular hydrogen-bond partners for these otherwise unsatisfied polar groups. Consequently, conformational space expands under folding conditions, a paradigm-shifting realization that prompts an experimentally verifiable conjecture about likely folding pathways.
引用
收藏
页码:109 / 113
页数:5
相关论文
共 50 条
  • [41] HYDROGEN-BONDING PROPERTIES OF FLUOROALCOHOLS
    MEDDA, T
    MUKHERJEE, S
    PALIT, SR
    INDIAN JOURNAL OF CHEMISTRY, 1975, 13 (09): : 910 - 912
  • [42] HYDROGEN-BONDING AND ANESTHETIC POTENCY
    YOKONO, S
    SHIEH, DD
    GOTO, H
    ARAKAWA, K
    JOURNAL OF MEDICINAL CHEMISTRY, 1982, 25 (07) : 873 - 876
  • [43] Electrochemistry of hydrogen-bonding systems
    Moon, Kwangyul
    Philip, Ivy
    Sun, Hao
    Kaifer, Angel E.
    JOURNAL OF SOLID STATE ELECTROCHEMISTRY, 2007, 11 (12) : 1635 - 1641
  • [44] HYDROGEN-BONDING DISSOCIATION IN POLYAMIDES
    SCHROEDER, LR
    COOPER, SL
    BULLETIN OF THE AMERICAN PHYSICAL SOCIETY, 1976, 21 (03): : 414 - 414
  • [45] HYDROGEN-BONDING IN CRYSTALLINE ARYLAZONAPHTHOLS
    MONAHAN, AR
    FLANNERY, JB
    CHEMICAL PHYSICS LETTERS, 1972, 17 (04) : 510 - 513
  • [46] HYDROGEN-BONDING OF THE AMMONIUM ION
    BROWN, RJC
    JOURNAL OF MOLECULAR STRUCTURE, 1995, 345 : 77 - 81
  • [47] Hydrogen-bonding in polymer blends
    Kuo, Shiao-Wei
    JOURNAL OF POLYMER RESEARCH, 2008, 15 (06) : 459 - 486
  • [48] HYDROGEN-BONDING IN CELLULAR COHESION
    JONES, MN
    FEBS LETTERS, 1976, 62 (01) : 21 - 24
  • [49] HYDROGEN-BONDING IN LIQUID METHANOL
    MATSUMOTO, M
    GUBBINS, KE
    ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY, 1990, 199 : 230 - PHYS
  • [50] MODELS FOR HYDROGEN-BONDING IN POLYSACCHARIDES
    JEFFREY, GA
    BIOMEDICAL AND BIOTECHNOLOGICAL ADVANCES IN INDUSTRIAL POLYSACCHARIDES, 1989, : 447 - 458
12345