AI Article Synopsis
- Developed a new method to compute ensemble averages in systems with pairwise-additive interactions, addressing challenges posed by full enumeration which is complex and time-consuming.
- Improved efficiency of Markov Chain Monte Carlo (MCMC) algorithms by leveraging the structure of interaction energy, enhancing sampling in cases with strong energetic coupling.
- Validated the effectiveness of the new biased MCMC methods through tests on both synthetic and real-world systems, particularly focusing on calculating protonation ensemble averages and titration curves in proteins.
Article Abstract
In this work, we developed an efficient approach to compute ensemble averages in systems with pairwise-additive energetic interactions between the entities. Methods involving full enumeration of the configuration space result in exponential complexity. Sampling methods such as Markov Chain Monte Carlo (MCMC) algorithms have been proposed to tackle the exponential complexity of these problems; however, in certain scenarios where significant energetic coupling exists between the entities, the efficiency of the such algorithms can be diminished. We used a strategy to improve the efficiency of MCMC by taking advantage of the cluster structure in the interaction energy matrix to bias the sampling. We pursued two different schemes for the biased MCMC runs and show that they are valid MCMC schemes. We used both synthesized and real-world systems to show the improved performance of our biased MCMC methods when compared to the regular MCMC method. In particular, we applied these algorithms to the problem of estimating protonation ensemble averages and titration curves of residues in a protein.
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| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC8513769 | PMC |
| http://dx.doi.org/10.1109/icmla51294.2020.00037 | DOI Listing |
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