| Literature DB >> 24189232 |
Robert D Oeffner1, Gábor Bunkóczi, Airlie J McCoy, Randy J Read.
Abstract
The estimate of the root-mean-square deviation (r.m.s.d.) in coordinates between the model and the target is an essential parameter for calibrating likelihood functions for molecular replacement (MR). Good estimates of the r.m.s.d. lead to good estimates of the variance term in the likelihood functions, which increases signal to noise and hence success rates in the MR search. Phaser has hitherto used an estimate of the r.m.s.d. that only depends on the sequence identity between the model and target and which was not optimized for the MR likelihood functions. Variance-refinement functionality was added to Phaser to enable determination of the effective r.m.s.d. that optimized the log-likelihood gain (LLG) for a correct MR solution. Variance refinement was subsequently performed on a database of over 21,000 MR problems that sampled a range of sequence identities, protein sizes and protein fold classes. Success was monitored using the translation-function Z-score (TFZ), where a TFZ of 8 or over for the top peak was found to be a reliable indicator that MR had succeeded for these cases with one molecule in the asymmetric unit. Good estimates of the r.m.s.d. are correlated with the sequence identity and the protein size. A new estimate of the r.m.s.d. that uses these two parameters in a function optimized to fit the mean of the refined variance is implemented in Phaser and improves MR outcomes. Perturbing the initial estimate of the r.m.s.d. from the mean of the distribution in steps of standard deviations of the distribution further increases MR success rates.Entities:
Keywords: Phaser; maximum likelihood; molecular replacement
Mesh:
Year: 2013 PMID: 24189232 PMCID: PMC3817694 DOI: 10.1107/S0907444913023512
Source DB: PubMed Journal: Acta Crystallogr D Biol Crystallogr ISSN: 0907-4449
Figure 1(a) Number of MR calculations as a function of the number of residues in their respective MR targets. (b) Fraction of MR calculations with a target belonging to certain SCOP classes as a function of the number of residues in the target. (c) Histogram of the number of MR models used in MR calculations.
Figure 2Fraction of correct placements of the only/first component in the asymmetric unit as a function of TFZ by polar and nonpolar space group. Polar space groups accounted for one quarter of the test cases in our database, while the 1% of test cases that were in space group P1 were excluded from this analysis.
Figure 3Scatter plot of VRMS against sequence identity for correct MR solutions: 10 921 data points. The red line represents (5) in Phaser. (a) All data, (b) data for models of less than 100 residues, (c) data for models of between 400 and 500 residues.
Figure 4(a) Fit of the eVRMS (light blue surface) and the Chothia and Lesk r.m.s.d. in (4) (pale yellow surface) to the refined VRMS values of 10 921 MR solutions. The effective limits of eVRMS (sequence identity, number of residues) are eVRMS (100%, 15) = 0.362 Å and eVRMS (15%, 1500) = 2.53 Å. (b) Fit of the eVRMS (light blue surface) and eVRMS ± 1σ surfaces to the refined VRMS values of 10 921 MR solutions.
Figure 5(a) Histogram of VRMS/eVRMS for the 10 921 correct solutions in the MR database. The distribution is approximately Gaussian. (b) Frequency distribution of VRMS/eVRMS for the four major SCOP classes computed for models ranging from 100 to 300 residues in length.
Average translation-function Z-scores (TFZ) for 3375 cases for the VRMS estimates derived from the Chothia and Lesk e.r.m.s.d. as given by (5) and the eVRMS given by (6) and perturbed by σ(VRMS/eVRMS) values, where eVRMS± = eVRMS[1 ± nσ(VRMS/VRMS)]
| Chothia and Lesk e.r.m.s.d. | eVRMS−1σ | eVRMS−½σ | eVRMS | eVRMS+½σ | eVRMS+1σ |
|---|---|---|---|---|---|
| 〈TFZ〉 = 6.28 | 〈TFZ〉 = 6.37 | 〈TFZ〉 = 6.47 | 〈TFZ〉 = 6.48 | 〈TFZ〉 = 6.43 | 〈TFZ〉 = 6.34 |
Matrix of results from 3375 borderline cases solved with the five different estimates of the VRMS against cases not solved with the five different estimates, where eVRMS± = eVRMS[1 ± nσ(VRMS/VRMS)]
Diagonal elements are the total number of solved calculations of the borderline cases with a particular estimate. Off-diagonal values are the number of calculations solved with the ith estimate (row) that cannot be solved with the jth estimate (column).
| eVRMS+1σ | eVRMS+½σ | eVRMS | eVRMS−½σ | eVRMS−1σ | Chothia and Lesk e.r.m.s.d. | |
|---|---|---|---|---|---|---|
| eVRMS+1σ | 2840 | 80 | 123 | 139 | 151 | 63 |
| eVRMS+½σ | 57 | 2863 | 74 | 95 | 111 | 81 |
| eVRMS | 92 | 66 | 2871 | 64 | 85 | 82 |
| eVRMS−½σ | 122 | 101 | 78 | 2857 | 45 | 133 |
| eVRMS−1σ | 171 | 154 | 136 | 82 | 2820 | 182 |
| Chothia and Lesk e.r.m.s.d. | 105 | 146 | 155 | 192 | 204 | 2798 |
Mean and standard deviation of the ratio of VRMS to eVRMS as a function of SCOP class
The results for the total four SCOP classes only include proteins for which a SCOP class was assigned.
| All-α | All-β | α+β | α/β | Total four SCOP classes | |
|---|---|---|---|---|---|
| VRMS/eVRMS | 1.089 | 0.946 | 0.990 | 1.019 | 0.997 |
| σ(VRMS/eVRMS) | 0.187 | 0.167 | 0.157 | 0.168 | 0.172 |