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The use of coevolutionary information, i.e. the knowledge of amino acid or nucleotide interactions maintained through evolution in each protein family, has provided a framework to study structural biology in a predictive manner. Amino acid couplings, obtained from inference algorithms like Direct Coupling Analysis, have been fundamental to predict non-local interactions in protein three-dimensional structure, being now the core of state-of-the-art protein structure prediction algorithms. Coevolutionary information has had an impact in understanding conformational plasticity, complex prediction in molecular interactions and specificity in signal transduction and predicting the effect of mutations. In this seminar I will discuss new directions in the study of global models of sequence evolution, primarily focused on the integration of theory and experiment. I will present recent advances in my lab integrating the statistical mechanics of sequences to develop a model of sequence evolution called Sequence Evolution with Epistatic Contributions (SEEC) that unifies several statistical features of independent models by integrating epistatic contributions and context dependance in the formulation of evolutionary landscapes. We then demonstrate how this model can produce, in silico, evolved sequences that are functional, in vivo, even after a large number of mutational events proposed by the dynamics of the model.

Ancestral sequence reconstruction (ASR) is an important tool to understand how protein structure and function changed over the course of evolution. It essentially relies on models of sequence evolution that can quantitatively describe changes in a sequence over time. Such models usually consider that sequence positions evolve independently from each other and neglect epistasis: the context-dependence of the effect of mutations. On the other hands, the last years have seen major developments in the field of generative protein models, which learn constraints associated with structure and function from large ensembles of evolutionarily related proteins. Here, we show that it is possible to extend a specific type of generative model to describe the evolution of sequences in time while taking epistasis into account. We apply the developed technique to the problem of Ancestral Sequence Reconstruction (ASR): given a protein family and its evolutionary tree, we try to infer the sequences of extinct ancestors. Using both simulations and data coming from experimental evolution we show that our method outperforms state-of-the-art ones. Moreover, it allows for sampling a greater diversity of potential ancestors, allowing for a less biased characterization of ancestral sequences.