Title :
Parallel constrained minimization for interactive protein modeling
Author_Institution :
Supercomput. Center, Gen. Atomics, San Diego, CA, USA
Abstract :
A coarse-grain parallel algorithm for nonlinear constrained minimization allows interactive modeling of electrostatic interactions in proteins. The constrained minimization problem is the basis of a graphical protein modeling system called Sculpt. While a user interactively changes a protein structure or explores protein-drug interaction, Sculpt maintains protein properties such as bond lengths and non-bonded atom separation. Between screen updates, Sculpt finds a focal energy minimum that satisfies constraints specifying ideal bond lengths and angles. This paper shows a parallel algorithm that models electrostatic interactions in 3500-atom proteins at two updates per second on an eight-processor SGI Challenge, a 7.2-times improvement over the sequential algorithm. These results are demonstrated through applications of Sculpt in biochemistry and drug design.<>
Keywords :
biology computing; bond angles; bond lengths; computer graphics; digital simulation; interactive systems; macromolecular configurations; minimisation; parallel algorithms; pharmaceutical industry; proteins; SGI Challenge; Sculpt; biochemistry; coarse-grain parallel algorithm; drug design; electrostatic interactions; focal energy minimum; graphical modeling system; ideal bond angles; ideal bond lengths; interactive protein modeling; nonbonded atom separation; nonlinear constrained minimization; protein-drug interaction; screen updates; user interaction;
Conference_Titel :
System Sciences, 1994. Proceedings of the Twenty-Seventh Hawaii International Conference on
Conference_Location :
Wailea, HI, USA
Print_ISBN :
0-8186-5090-7
DOI :
10.1109/HICSS.1994.323578
