From rwoods%!at!%biop.ox.ac.uk Fri Dec 3 07:54:00 1993 Received: from lmb.biop.ox.ac.uk for rwoods -x- at -x- biop.ox.ac.uk by www.ccl.net (8.6.4/930601.1506) id HAA01009; Fri, 3 Dec 1993 07:44:21 -0500 From: Received: by biop.ox.ac.uk (MX V3.3 VAX) id 12365; Fri, 03 Dec 1993 12:44:19 +0000 Date: Fri, 03 Dec 1993 12:43:46 +0000 To: cletner |-at-| remcure.bmb.wright.edu CC: chemistry $#at#$ ccl.net Message-ID: <00976762.8199B820.12365 %-% at %-% biop.ox.ac.uk> Subject: RE: RE:Protein force fields Dear Chuck, As it happens I have just reviewed the Rao and Teeter paper for our journal club. I chose the paper for 3 reasons: a) It was being presented to biochemists, b) I am a computational chemist, c) I liked the practicality of the approach. Martha Teeter is a crystalographer who has a long standing interest in proteins related to a-purothionin (eg crambin which she also solved), but has limited access to computing facilities (Microvax II). She clearly wants to find a method that gives a good guess for solving protein structures by x-ray methods. The paper presents a VERY rudimentary MD simulation using the AMBER UA force field, in vacuo, with much of the structure constrained. This is a very simple and unsophysticated approach, and in some ways it is perhaps pleasantly surprising that it worked. However, there are a few notable points: 1) This is a purely anecdotal report. 2) Alpha-PT is highly homologous to Crambin and so a very good guess for the MM/MD calculations was already available. 3) The MD was performed on a very small subset of the atoms (6 out of 46 residues only). 4) Because of the particular nature of this protein (and its homologs) the ends of the critical loop-region could be assumed to be in the correct conformation, therefore extensive conformational restraints could be invoked. 5) The authors report that an unconstrained MD simulation (epsilon=1,in vacuo) resulted in [hydrogen] bond breaking, but apparently did not test the stability with (epsilon=4) which they went on to use for the partial MD. 6) Although the authors refer to a 2ps equilibration period, there PE data clearly shows equilibration was not reached until about 30 ps. This is unimportant in context of their analysis, but without continuing the trajectory for a longer period it is not possible to say how stable their loop conformation really is. The results are however interesting, particularly the sequential nature of the changes in the backbone conformation. I think that if the system can be modelled based on similar high homology the UA approach looks very interesting, but it is very system dependant. It worked in this case but I think solvation would have to be considered for more general studies. Hope this sparks other comments and answers some of your questions, Best wishes, Rob Woods Robert J. Woods, Ph.D. Glycobiology Institute Department of Biochemistry University of Oxford South Parks Road Oxford, OX1 3QU England