What is DEMO-EM? |
How does DEMO-EM generate multi-domain protein structure predictions? |
In the second step, the model of each inividual domain (or the full-length protein if it is predicted as a signle-domain protein by FUpred) is generated by I-TASSER, which also can be locally installed.
In the third step, each of the individual domain models is independently fit into the density map by quasi-Newton searching to create initial full-length models.
In the fourth step, the initial full-length models are optimized by a two-round rigid-body replica-exchange Monte Carlo (REMC) simulation to minimize the density correlation score (DCS) between the density map and the full-length model. In the first round, domains are treated as particles where a quick REMC simulation is made to quickly adjust the individual domain positions based on the global model-density correlations. The second round of rigid-body REMC simulation is to fine-tune the domain poses with a more detailed energy force field.
In the fifth step, the lowest DCS model selected from the rigid-body assembly simulations undergoes a flexible assembly with atom-, segment-, and domain-level refinements using REMC simulation guided by the DCS and DomainDist predicted inter-domain distance profiles coupled with a knowledge-based force field, with the resulting decoy conformations clustered by SPICKER to obtain a centroid model.
In the last setp, the flexible assembly simulation is performed again for the full-atomic model with constraints from centroid models clustered by SPICKER adding to the energy, and the final model is created from the lowest energy model after side-chain repacking with FASPR and FG-MD.
Figure 1. Pipeline of DEMO-EM for multi-domain protein structruces modeling from cryo-EM density maps.
What are the performances of DEMO-EM server compared with other methods? |
Figure 2. (a) Mean and distribution of TM-score for models by DEMO-EM, MDFF, Rosetta, and MAINMAST using synthesized density maps, respectively. (b) Boxplot and distribution for RMSD of models by DEMO-EM, MDFF, Rosetta, and MAINMAST using synthesized density maps, respectively. (c) TM-score of full-length models constructed by DEMO-EM, MDFF, Rosetta, and MAINMAST using experimental density maps.
What are the output of the DEMO-EM server if you submit a seqeunce? |
How to interpret the output data generated by the DEMO-EM server? |
For each target, DEMO-EM reports the top five models ranked by the total energy. Since the top 5 models are ranked by the energy, it is possible that the lower-rank models have a higher CC-score or FSC-score. Although the first model has a higher CC-score or FSC-score and a better quality in most cases, it is not unusual that the lower-rank models have a better quality than the higher-rank models.
CC-score is the correlation and coefficient score between the experimental density and the density probed from a model.
FSC-score measures the normalised cross-correlation coefficient between the experimental volumes and the volumes probed from a model over corresponding shells in Fourier space.
TM-score is a recently proposed scale for measuring the structural similarity between two structures (see Zhang and Skolnick, Scoring function for automated assessment of protein structure template quality, Proteins, 2004 57: 702-710). The purpose of proposing TM-score is to solve the problem of RMSD which is sensitive to the local error. Because RMSD is an average distance of all residue pairs in two structures, a local error (e.g. a misorientation of the tail) will arise a big RMSD value although the global topology is correct. In TM-score, however, the small distance is weighted stronger than the big distance which makes the score insensitive to the local modeling error. A TM-score >0.5 indicates a model of correct topology and a TM-score<0.17 means a random similarity. These cutoff does not depends on the protein length.
Here the "Estimated TM-score" is an estimated value of TM-score over the correlation between TM-score and CC-score/FSC-score which is observed by a nonredundant training set.
How long does it take for DEMO-EM to generate the predictions for your protein? |
In addition, if you choose to use inter-domain distances predicted by deep learning or structural analogous multi-domain templates to guide the assembly, it will require much extra time to complete the job. Because the mutiple sequence alignment generation needs to detect a huge library, and the multi-domain templates identification needs to evaluate the whole multi-domain library.
However, it will cost less time if you provide the domain models since the program does not need to predict the domain bounaries and domain structruces.
How to cite DEMO-EM |
Funding support |
Contact information |
yangzhanglabumich.edu | (734) 647-1549 | 100 Washtenaw Avenue, Ann Arbor, MI 48109-2218