|Dr. Thomas A. Halgren|
|Merck and Co., Inc.|
|P.O. Box 2000|
|Rahway, NJ 07065|
The test molecules for this validation suite consist of 698 structures derived from the Cambridge Structural Database maintained by the Cambridge Crystallographic Data Center (which graciously gave permission for their use), plus 55 additional structures for small molecules and ions. The native CSD structures were modified by assigning single and multiple bonds, affixing formal ionic charges where appropriate, and adding hydrogens to complete the valence. The resultant structures were minimized to a rms gradient of 0.000001 kcal/mol/A on the MMFF94 energy surface, and were then systematically distorted and re-minimized, and then distorted and re-minimized again. The distortion/re-minimizaton steps were taken to reduce the likelihood that any final conformation represents a very shallow local minimum on the MMFF94 surface, as a molecular-mechanics optimizer might conceivably convert such a conformation to a different local minimum and falsely imply a problem with the implementation of MMFF94 being tested.
The validation suite was constructed to test all entries in the MMFF*.PAR parameter files as well as all default-parameter and empirical-rule procedures. The MMFF94 parameter files can be accessed via an Internet browser at http://journals.wiley.com (select "Journal of Computational Chemistry", then "Supplementary Material", then "Volume 17", then the hyperlink for page 490) or at ftp://ftp.wiley.com/public/journals/jcc/suppmat/17/490. The parameter files can also be accessed by ftp at email@example.com; cd to public/journals/jcc/suppmat/17/490.
In addition to input molecular structure files, this test suite provides
output files from computer runs made using Merck's OPTIMOL molecular-mechanics
program and BatchMin version 5.5 from Columbia University.
Note: some files are quite large. Before downloading, you may want to check the sizes listed at the end of this document. You may want to retrieve the compressed tar achive of these files, MMFF94.tar.gz, (6 MBytes) and unpack it with a:
gunzip -c MMFF94.tar.gz | tar xvof -command under UNIX.
Input structure files are provided in two formats: mol2, from Tripos, and mmd, the designation used at Merck for BatchMin dat files. We chose these file formats because they are in fairly widespread use and because they allow explicit single and multiple bonds to be designated. For the convenience of the user, the mol2 files are presented in two versions. One of these -- MMFF94_dative.mol2 -- uses dative bonding at sulfur in sulfonamides and similar compounds. This representation treats a sulfonamide as having four single bonds to a tetracoordinate +2 sulfur, two of which come from formally negative terminal oxygen atoms. This is the native representation for OPTIMOL, the host program for MMFF. In contrast, the native BatchMin representation features two double bonds from formally neutral oxygen atoms to a formally neutral sulfur, for a (hypervalent) total of six bonds to sulfur. This hypervalent bonding pattern is used in the MMFF94_hypervalent.mol2 and MMFF94.mmd files in the test suite.
Thus, the following files comprise the input molecular structure data:
|MMFF94.mmd (hypervalent representation only)|
In addition, a MMFF94.dative_molecules file is included that lists the names of the molecules (129 in number) for which the mol2 files provide contrasting dative and hypervalent structures. (For the mmd file, the molecule names begin in column 11 of the header cards, immediately following the left square bracket.) Finally, a MMFF94.titles file gives short titles for all of the molecules in the test set.
The MMFF94.energies file contains records that list the molecule name, the total MMMFF94 energy computed by OPTIMOL, and the BatchMin 5.5 energy. It should be noted that the BatchMin calculations used a locally modified version of the mmff_setup co-process in which mmff_setup was enhanced to handle the full range of hypervalent -> dative bonding conversions encountered in the test suite; some cases were not properly accomodated in the distributed BatchMin 5.5 and 6.0 code, but all should be properly handled beginning with BatchMin 6.5 (these internal bonding conversions are needed because the mmff-setup code, which was derived from OPTIMOL, assumes dative bonding). In all cases, no cutoffs on nonbonded interactions were employed and a unit dielectric constant was used. As comment records in the MMFF94.energies file indicate, the OPTIMOL and BatchMin total energies agree to within 0.0001 kcal/mol in all but 15 instances; the largest difference is about 0.0035 kcal/mol. The 15 cases are ones in which a positive or negative formal charge is shared among three atoms of the same MMFF atom type (e.g., the three nitrogens of a guanidinium group); the single-precision division by 3 in the BatchMin run produces a less precise final partial atomic charge and a less accurate total MMFF94 energy.
The MMFF94_bmin.log file contains BatchMin 5.5 output, obtained on a sgi R10000 processor, for single-point energy calculations on input structures read from the MMFF94.mmd file. This log file partitions the total energy into components such as bond stretching, angle-bending, torsion, van der Waals, and electrostatic. It provides the next level of information beyond the simple compilation of total energies found in the MMFF94.energies file.
Finally, the MMFF94_opti.log file contains the output from an OPTIMOL run that employed as input an internal Merck-format data file, MMFF94.ffd, that contains the same information as does the file MMFF94_dative.mol2 (indeed, the mol2 file was created from it). This log file provides by far the greatest amount of validation information. For each molecule, an initial list section gives the symbolic and numeric MMFF94 types for each atom, together with the MMFF94 formal charge (usually zero) and partial atomic charge (the last of which is also provided in the input data files). Next, the total energy and the energy components (bond stretching, ...) are listed. Also shown is the total rms gradient (kcal/mol/A). This quantity is typically small, as befits an energy- minimized structure, but is not zero because the stored coordinates have too little numerical precision. Finally, the analyze section exhaustively lists all interactions of a given type (i.e., all bond-stretching interactions, all angle-bending interactions, ...), and reports both the force-field parameters and the strain energy for the interaction. The notation should be obvious for the most part, but it should be noted that the listed FF CLASS indices are the quantities called bond-type index, angle-type index, etc., in the 1996 J. Comp. Chem. papers (see References). For nonbonded interactions, only pair-wise terms for which the van der Waals repulsion energy is at least 0.01 kcal/mol are listed. Each nonbond output line includes the separate vdW attraction and repulsion components, the Coulombic interaction energy, and the Buffered 14-7 R* and Eps parameters produced by the MMFF combination rules; this data should be more than sufficient to validate an implementation of the MMFF94 nonbonded potential. One cautionary note: eqs.(3) and (4) in the fifth MMFF paper were typeset incorrectly; their counterparts in the first four MMFF papers, however, are correct. The OPTIMOL run was made on a R4000 processor.
To validate a MMFF94 implementation, it would certainly make sense to choose a subset of the test suite, to convert the mol2 or mmd input data to another format if necessary, and then to begin by computing and comparing total energies to those listed in the MMFF94.energies file; if and when differences are found, the component energies can then be compared to those listed in the MMFF94_bmin.log or MMFF94_opti.log files. Examination of the detailed interaction listings in the OPTIMOL log file might then be needed to diagnose a problem. Ultimately, the entire test set should be checked. It is the implementer's choice as to whether to use a dative- or hypervalent-bonding representation for affected compounds, or to support both formats.
We have two requests. The first is that any implementation of MMFF94 be identified simply as MMFF94, and that the name Merck not be used in product literature or in any other way. This is a trademarking issue that our lawyers understand better than I; they are quite adamant about it.
The second request is that any implementation of MMFF94 be explicitly characterized by its authors as to whether it is: (1) complete, or (2) partial. An implementation should not be labeled complete unless it is applicable to all 753 molecules in the test suite and produces total and component energies that match those posted here to within numerical precision. For a partial implementation, published descriptions and product literature should state the degree to which the implementation is applicable to the molecules in the test suite and the degree to which it produces authentic results for those members of the test-suite to which it is applicable; a clear statement should also be made as to whether or not the MMFF94 functional form has been fully implemented, as well as whether or not the MMFF94 step-down equivalencing protocol for default parameter assigmnent is fully utilized and whether or not the MMFF94 empirical-rule procedures for parameter generation are faithfully employed.
While a legal agreement permits the posting of this public-access validation suite, it prohibits Merck from providing assistance in the development, testing, and implementation of MMFF to any third-party commercial software development company other than academic developers of software. As a matter of courtesy, however, we would appreciate hearing from parties that implement MMFF94 as to how they characterize the completeness and accuracy of their implementation of MMFF94.
Paper 6 describes the derivation and performance of the MMFF94s variant of MMFF94. This variant and the rationale for it are briefly described in papers 1, 3, and 4. A companion MMFF94s validation suite will be provided when this manuscript is published (whether in J. Comp. Chem. or elsewhere) and the MMFF94s parameters have passed into the public domain.
Paper 7 compares the abilities of MMFF94, MMFF94s, CFF95, CVFF, MSI CHARMm, AMBER*, OPLS*, MM2*, and MM3* (1) to reproduce experimental and theoretical values for conformational energies, and (2) to produce realistic values and trends for intermolecular-interaction energies and geometries in hydrogen-bonded complexes. Some results are also presented for CHARMM 22.
File name Size in Bytes MMFF94.dative_molecules 1,080 MMFF94.energies 27,405 MMFF94.mmd 2,358,140 MMFF94.titles 53,463 MMFF94_bmin.log 1,168,907 MMFF94_dative.mol2 1,643,541 MMFF94_hypervalent.mol2 1,643,541 MMFF94_opti.log 24,706,195