TY - JOUR
T1 - Principles of Protein Stability and Their Application in Computational Design
AU - Goldenzweig, Adi
AU - Fleishman, Sarel J.
N1 - The authors thank Amnon Horovitz and Rina Rosenzweig for discussions on the role of cooperativity and chaperones in protein folding and Ingemar André, Dan Tawfik, and Nicholas Schafer for critical reading of the manuscript. Research in the Fleishman laboratory is supported by a Starter's Grant from the European Research Council (335439), the Israel Science Foundation through its Center of Excellence in Structural Cell Biology (1775/12) and its India-Israel Joint Research Program (2281/15), by IgC Bio Ltd., and by a charitable donation from Sam Switzer and family.
PY - 2018/6
Y1 - 2018/6
N2 - Proteins are increasingly used in basic and applied biomedical research. Many proteins, however, are only marginally stable and can be expressed in limited amounts, thus hampering research and applications. Research has revealed the thermodynamic, cellular, and evolutionary principles and mechanisms that underlie marginal stability. With this growing understanding, computational stability design methods have advanced over the past two decades starting from methods that selectively addressed only some aspects of marginal stability. Current methods are more general and, by combining phylogenetic analysis with atomistic design, have shown drastic improvements in solubility, thermal stability, and aggregation resistance while maintaining the protein's primary molecular activity. Stability design is opening the way to rational engineering of improved enzymes, therapeutics, and vaccines and to the application of protein design methodology to large proteins and molecular activities that have proven challenging in the past.
AB - Proteins are increasingly used in basic and applied biomedical research. Many proteins, however, are only marginally stable and can be expressed in limited amounts, thus hampering research and applications. Research has revealed the thermodynamic, cellular, and evolutionary principles and mechanisms that underlie marginal stability. With this growing understanding, computational stability design methods have advanced over the past two decades starting from methods that selectively addressed only some aspects of marginal stability. Current methods are more general and, by combining phylogenetic analysis with atomistic design, have shown drastic improvements in solubility, thermal stability, and aggregation resistance while maintaining the protein's primary molecular activity. Stability design is opening the way to rational engineering of improved enzymes, therapeutics, and vaccines and to the application of protein design methodology to large proteins and molecular activities that have proven challenging in the past.
UR - http://www.scopus.com/inward/record.url?scp=85048869721&partnerID=8YFLogxK
U2 - 10.1146/annurev-biochem-062917-012102
DO - 10.1146/annurev-biochem-062917-012102
M3 - مقالة
SN - 0066-4154
VL - 87
SP - 105
EP - 129
JO - Annual Review of Biochemistry
JF - Annual Review of Biochemistry
ER -