.. _publications: Publications ============ The following published works use MSMExplorer. To add your publication to the list, open an issue on GitHub with the relevant information or edit ``docs/papers.bib`` and submit a pull request. .. publications.bib lists the relevant publications .. publications_templ.rst defines how the publications will be displayed .. publications.rst is generated during sphinx build (see conf.py) and should not be edited directly! A Network of Conformational Transitions in the Apo Form of NDM-1 Enzyme Revealed by MD Simulation and a Markov State Model -------------------------------------------------------------------------------- * Kaifu Gao; Yunjie Zhao * *The Journal of Physical Chemistry B* **2017** * `doi: 10.1021/acs.jpcb.7b00062 `_ New Delhi metallo-β-lactamase-1 (NDM-1) is a novel β-lactamase enzyme that confers enteric bacteria with nearly complete resistance to all β-lactam antibiotics, so it raises a formidable and global threat to human health. However, the binding mechanism between apo-NDM-1 and antibiotics as well as related conformational changes remains poorly understood, which largely hinders the overcoming of its antibiotic resistance. In our study, long-time conventional molecular dynamics simulation and Markov state models were applied to reveal both the dynamical and conformational landscape of apo-NDM-1: the MD simulation demonstrates that loop L3, which is responsible for antibiotic binding, is the most flexible and undergoes dramatic conformational changes; moreover, the Markov state model built from the simulation maps four metastable states including open, semiopen, and closed conformations of loop L3 as well as frequent transitions between the states. Our findings propose a possible conformational selection model for the binding mechanism between apo-NDM-1 and antibiotics, which facilitates the design of novel inhibitors and antibiotics. tICA-Metadynamics: Accelerating Metadynamics by using kinetically selected collective variables -------------------------------------------------------------------------------- * Mohammad M. Sultan; Vijay S. Pande * *Journal of Chemical Theory and Computation* **2017** * `doi: 10.1021/acs.jctc.7b00182 `_ Metadynamics is a powerful enhanced molecular dynamics sampling method that accelerates simulations by adding history-dependent multidimensional Gaussians along selective collective variables (CVs). In practice, choosing a small number of slow CVs remains challenging due to the inherent high dimensionality of biophysical systems. Here we show that time-structure based independent component analysis (tICA), a recent advance in Markov state model literature, can be used to identify a set of variationally optimal slow coordinates for use as CVs for Metadynamics. We show that linear and nonlinear tICA-Metadynamics can complement existing MD studies by explicitly sampling the system’s slowest modes and can even drive transitions along the slowest modes even when no such transitions are observed in unbiased simulations. Transfer Learning from Markov Models Leads to Efficient Sampling of Related Systems -------------------------------------------------------------------------------- * Mohammad Muneeb Sultan; Vijay S. Pande * *The Journal of Physical Chemistry B* **2017** * `doi: 10.1021/acs.jpcb.7b06896 `_ We recently showed that the time-structure based independent component analysis method from Markov state model literature provided a set of variationally optimal slow collective variables for Metadynamics (tICA-Metadynamics). In this paper, we extend the methodology towards efficient sampling of related mutants by borrowing ideas from transfer learning methods in machine learning. Our method explicitly assumes that a similar set of slow modes and metastable states are found in both the wild type (base line) and its mutants. Under this assumption, we describe a few simple techniques using sequence mapping for transferring the slow modes and structural information contained in the wild type simulation to a mutant model for performing enhanced sampling. The resulting simulations can then be reweighted onto the full-phase space using Multi-state Bennett Acceptance Ratio, allowing for thermodynamic comparison against the wild type. We first benchmark our methodology by re-capturing alanine dipeptide dynamics across a range of different atomistic force fields, including the polarizable Amoeba force field, after learning a set of slow modes using Amber ff99sb-ILDN. We next extend the method by including structural data from the wild type simulation and apply the technique to recapturing the affects of the GTT mutation on the FIP35 WW domain.