Directed Evolution

Directed evolution and protein engineering often utilize sequence information contained within homologs to guide the design of diverse libraries. Combinatorially capturing this information can require the production of 10⁶-10¹² variants in a library. The ability to cull the sequence information thus holds considerable value. We have developed a new evolutionary-guided approach for directed evolution and protein engineering, Reconstructing Evolutionary Adaptive Paths (REAP).

Experimental phylogenetics

Experimental evolution consists of evolving microorganisms in the laboratory in attempt to understand how genotype and phenotype are linked within functional/adaptive landscapes. We are using our resurrected elongation factor proteins inserted into E. coli as a system to study evolutionary trajectories in landscapes. In particular, we are testing whether replaying the ‘tape of life’ is repetitive and whether historical contingency funnels molecular trajectories.

Origin of the ribosomes and genetic code

The goal here consists of computationally reconstructing components of an ancient ribosome, resurrecting them in the laboratory, and assaying for their ability to participate in protein translation (peptidyltransferase activity) in combination with modern and ancient (or minimal) ribosomal RNA structures. We anticipate that this approach will enable us to computationally dissect and experimentally reassemble the ribosome in a manner that allows to understand the origins and early evolution of peptide synthesis.

Engineering proteins composed of unnatural amino acids

Our laboratory exploits models of molecular sequence evolution to guide us in our attempt to engineer novel biomolecular systems. For instance, our lab is engineering tRNAs and Elongation Factors biomolecules to participate in a synthetic, tunable protein translation system. The goal here is to generate peptides and proteins that are composed of amino acids different than the 20 canonical amino acids. This is a particularly exciting synthetic system to develop based on the biomolecular emergent properties we expect to generate.

Synthetic/Ancestral Genomes

We anticipate that the synthesis of recombinant, minimal and/or ancestral genomes will have a profound effect on our understanding of early life. As molecular reconstructionists, we are interested in constructing a complete ancestral biochemical pathway (e.g., operon), or even a complete ancestral genome? The ancestral reconstruction field would no longer be confined to single gene analysis. It is also quite possible that our understanding of what constitutes a sustaining minimal genome required to support life will be altered through ancestral reconstructions. In this way, homologous genes performing two different, but related, functions may share a single common ancestor that performed both of these functions, albeit with less efficiency or specificity.

Reconstruction and resurrection of ancient sequences

Ancestral sequence reconstruction (ASR) consists of inferring ancestral character states of DNA and protein sequences when analyzed within a phylogenetic context. Proposed by Linus Pauling in 1963 and first put into practice separately by Steve Benner and Allan Wilson in 1990, ASR provides a unique way to travel through time to understand paleoenvironments of ancient organisms, functional diversification of biomolecules and regulatory pathways. Our laboratory applies ASR to gene families such elongation factors, thioredoxins, ribosomal proteins, uricases, inter alia.