TY - JOUR
T1 - Bridging the protein sequence-structure gap by structure predictions
AU - Rost, Burkhard
AU - Sander, Chris
PY - 1996
Y1 - 1996
N2 - The problem of accurately predicting protein three-dimensional structure from sequence has yet to be solved. Recently, several new and promising methods that work in one, two, or three dimensions have invigorated the field. Modeling by homology can yield fairly accurate three-dimensional structures for approximately 25% of the currently known protein sequences. Techniques for cooperatively fitting sequences into known three-dimensional folds, called threading methods, can increase this rate by detecting very remote homologies in favorable cases. Prediction of protein structure in two dimensions, i.e. prediction of interresidue contacts, is in its infancy. Prediction tools that work in one dimension are both mature and generally applicable; they predict secondary structure, residue solvent accessibility, and the location of transmembrane helices with reasonable accuracy. These and other prediction methods have gained immensely from the rapid increase of information in publicly accessible databases. Growing databases will lead to further improvements of prediction methods and, thus, to narrowing the gap between the number of known protein sequences and known protein structures.
AB - The problem of accurately predicting protein three-dimensional structure from sequence has yet to be solved. Recently, several new and promising methods that work in one, two, or three dimensions have invigorated the field. Modeling by homology can yield fairly accurate three-dimensional structures for approximately 25% of the currently known protein sequences. Techniques for cooperatively fitting sequences into known three-dimensional folds, called threading methods, can increase this rate by detecting very remote homologies in favorable cases. Prediction of protein structure in two dimensions, i.e. prediction of interresidue contacts, is in its infancy. Prediction tools that work in one dimension are both mature and generally applicable; they predict secondary structure, residue solvent accessibility, and the location of transmembrane helices with reasonable accuracy. These and other prediction methods have gained immensely from the rapid increase of information in publicly accessible databases. Growing databases will lead to further improvements of prediction methods and, thus, to narrowing the gap between the number of known protein sequences and known protein structures.
KW - homology modeling
KW - interresidue contacts
KW - knowledge-based mean-force potentials
KW - multiple alignments
KW - secondary structure
KW - solvent accessibility
KW - threading
KW - transmembrane helices
UR - http://www.scopus.com/inward/record.url?scp=0029902780&partnerID=8YFLogxK
U2 - 10.1146/annurev.bb.25.060196.000553
DO - 10.1146/annurev.bb.25.060196.000553
M3 - Review article
C2 - 8800466
AN - SCOPUS:0029902780
SN - 1056-8700
VL - 25
SP - 113
EP - 136
JO - Annual Review of Biophysics and Biomolecular Structure
JF - Annual Review of Biophysics and Biomolecular Structure
ER -