Contribution of hydrogen bonds to protein stability

Protein Science

Volumn 23, Issue 5, 2014, Pages 652-661

  Pace, C Nick ^a,b   Fu, Hailong ^a   Fryar, Katrina Lee ^b   Landua, John ^b   Trevino, Saul R ^c   Schell, David ^a   Thurlkill, Richard L ^d   Imura, Satoshi ^b   Scholtz, J Martin ^a,b   Gajiwala, Ketan ^e   Sevcik, Jozef ^f   Urbanikova, Lubica ^f   Myers, Jeffery K ^g   Takano, Kazufumi ^h   Hebert, Eric J ⁱ   Shirley, Bret A ^j   Grimsley, Gerald R ^b  

^a TEXAS A AND M UNIVERSITY   (United States)

^b TEXAS A AND M HEALTH SCIENCE CENTER   (United States)

^c HOUSTON BAPTIST UNIVERSITY   (United States)

^d UNIVERSITY OF LOUISIANA AT MONROE   (United States)

^e PFIZER INC   (United States)

^f INSTITUTE OF CHEMISTRY   (Slovakia)

^g DAVIDSON COLLEGE   (United States)

^h KYOTO PREFECTURAL UNIVERSITY   (Japan)

ⁱ ABBVIE INC   (United States)

^j Receptos   (United States)

more..

Author keywords

Conformational entropy; Hydrogen bonds; Hydrophobic bonds; Large proteins; Protein stability; Small proteins

Indexed keywords

MUTANT PROTEIN; RIBONUCLEASE SA; RIBONUCLEASE T1; UNCLASSIFIED DRUG; VILLIN HEADPIECE SUBDOMAIN PROTEIN; VLSE PROTEIN; WATER; ACTIN BINDING PROTEIN; BACTERIAL PROTEIN; PROTEIN; RIBONUCLEASE; RIBONUCLEASE SA3; VILLIN;

ARTICLE; BORRELIA BURGDORFERI; CRYSTAL STRUCTURE; HYDROGEN BOND; NONHUMAN; PRIORITY JOURNAL; PROTEIN CONFORMATION; PROTEIN STABILITY; PROTEIN STRUCTURE; WILD TYPE; CHEMICAL STRUCTURE; CHEMISTRY; ENTROPY; STREPTOMYCES AUREOFACIENS;

BACTERIAL PROTEINS; BORRELIA BURGDORFERI; ENTROPY; HYDROGEN BONDING; MICROFILAMENT PROTEINS; MODELS, MOLECULAR; PROTEIN CONFORMATION; PROTEIN STABILITY; PROTEINS; RIBONUCLEASE T1; RIBONUCLEASES; STREPTOMYCES AUREOFACIENS;

EID: 84901012002     PISSN: 09618368     EISSN: 1469896X     Source Type: Journal    
DOI: 10.1002/pro.2449     Document Type: Article

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