3 min readScientists ‘Resurrect’ Ancient Proteins to Inspire Molecular Engineering
Grenoble, France – A growing body of research on the use of ancestral protein resurrection has been published in recent years to address a variety of issues on protein evolution and protein engineering.
In a study published in Nature Communications, an International team of scientists has demonstrated the high potential of this evolutionary approach to endow new activities into ancient enzymes. Specifically, the study suggests a mechanism for the emergence of primordial enzymes and shows that resurrected ancestral enzymes make much better scaffolds for engineering of novel enzyme functions.
Enzyme activity is determined by the structure of a particular region of the protein called the active site. The generation of completely new active sites capable of enzyme catalysis is, arguably, one of the most fundamental unsolved problems in molecular biology.
Rational and modern design approaches to this problem have been developed, using complex computational methods but without conclusive results. Indeed, protein engineering studies often suggest that the emergence of completely new enzyme active sites is highly improbable.
Many years ago, Roy Jensen (currently at the University of Kansas Medical Center) proposed that primordial enzymes were capable of catalyzing a diversity of reactions. Based on this work, a team of scientists from the University of Granada (Spain), the University of Uppsala (Sweden), the “Instituto de Quimica Fisica Rocasolano” (Madrid, Spain), the Georgia Institute of Technology (USA) and with data collected at the ESRF, the European Synchrotron, located in Grenoble (France), explored and tested these notions using resurrected Precambrian β-lactamases as scaffolds for the engineering of completely new active sites.
Precambrian β-lactamases are proteins approximately 3 billion years old. If we simplify, the scientists did for these proteins what the scientists in Jurassic Park did for dinosaurs: bring ancient forms back to life, so that they can be studied to better understand how complexity in species comes about.
How is it possible to resurrect ancestral protein? Proteins are made from various combinations of amino acid building blocks, with a nearly endless variety of complexity and function. Researchers have compiled large databases full of the proteins sequences. By comparing today’s sequences to each other within an evolutionary framework, scientists can reasonably infer the sequence of an ancestral protein from which the modern versions descended using models of sequence evolution.
“The properties of these ancestral proteins (Precambrian β-lactamases) confer high structural stability and promiscuous enzymatic activity, meaning that they are capable of reacting with a variety of substances. These properties support the biotechnological potential of Precambrian protein resurrection because both high stability and enhanced promiscuity are desirable features in protein scaffolds for laboratory directed evolution and molecular design.” explains Valeria A. Risso, first author of the paper, from the University of Granada.
Using these resurrected Precambrian proteins, the team demonstrated that a new active site can be generated through a single hydrophobic-to-ionizable amino acid replacement that generates a partially buried group with perturbed physico-chemical properties.
“We have found that a minimalist design to introduce a de novo activity (catalysis of the Kemp elimination, a common benchmark in de novo enzyme design) fails when performed on modern β-lactamases but is highly successful when using the scaffolds of hyperstable/promiscuous Precambrian β-lactamases,” underlines Eric A. Gaucher, from the Institute for Bioengineering and Biosciences, Georgia Institute of Technology.
For their experiment, the team used three structural biology beamlines at the ESRF, the European Synchrotron in Grenoble (France): ID29, ID23-1, and the fully automated “hands-off” beamline MASSIF-1, as well as the Xaloc beamline at Alba, the Spanish synchrotron.
“Three-dimensional structural information derived from the data obtained at the ESRF was essential for the interpretation of the work, as it led to a high-resolution structure of the new active site and provided conclusive evidence of the role of protein re-organisation in the emergence of the new function,” explains Jose A. Gavira, corresponding author, from the University of Granada.
This study confirms the potential of ancestral reconstruction as a tool for protein engineering.
“We provide experimental and computational evidence that laboratory-resurrected ancestral enzyme will make much better scaffolds for new function engineering due to its high stability and dynamics features,” says Jose M. Sanchez-Ruiz.
The innovative combination of bioinformatics, computational biology, structural biology and biophysics allowed researchers to delve deep into evolutionary time, and change the course of an enzyme’s evolutionary potential.
“Learning more about primordial life, and how it can be re-manipulated, will open up a lot of new avenues for science, and shed light on the puzzle of how complex biological systems evolve at the most fundamental molecular level” underlines Lynn Kamerlin, corresponding author, from the Department of Cell and Molecular Biology, Uppsala University.
Article adapted from a European Synchrotron Radiation Facility news release.
Publication: Nature Communications (July 2017). Click here to view.