Directed Evolution

Jonathan Sun University of Illinois at Urbana Champaign BIOE 506 February 15, 2010 Directed Evolution http://www.sliceofscifi.com/wp-content/uploads/2008/02/nc_evolution_080103_ms.jpg

Outline • Introduction • Motivation • Methods • Applications • Conclusions University of Illinois

Evolution • Darwin => natural selection • 1970 – John Maynard Smith • Evolution is a walk from one functional protein to another in the landscape of all possible sequences • “Fitness” of protein based on favorability for reproduction or based on experimenter in artificial selection Romero and Arnold: Exploring Protein Fitness Landscapes by Directed Evolution University of Illinois

Picture (not many more to come) • Screening criteria is important • Stability can be used instead of improvement • Allows for functionally neutral mutations Romero and Arnold: Exploring Protein Fitness Landscapes by Directed Evolution University of Illinois

What is Directed Evolution? • An engineering strategy used to improve protein functionality through repeated rounds of mutation and selection • First used in the ‘70s • Around .01-1% of all random mutations estimated to be beneficial • Based off natural evolution processes, but in a much quicker timescale University of Illinois

Another (more direct?) Method • Rational design – modify protein function based on understanding consequences of certain changes • We are still relatively ignorant as to how a protein’s gene sequence encodes functionality • Directed evolution avoids this problem by creating libraries of variants possessing desired properties University of Illinois

Why is it Needed? • Biotechnology – increased demand for specific properties that don’t necessarily occur naturally • Can be used to improve existing proteins’ functionality • Can be applied as far as the ideas come – enzymes and catalysts to pharmaceuticals or crops University of Illinois

Successful Directed Evolution • Desired function should be/have: • Physically feasible • Biologically or evolutionarily feasible • Libraries of mutants complex enough to contain rare beneficial mutations • Rapid screen to find desired function • Increases understanding of protein function and evolution – disconnects protein from natural context University of Illinois

Basic Method • A parent gene is selected • Mutations/diversity are induced (mutagenesis or recombination) • Selection criteria applied • Repeat with new parent genes selected Bloom and Arnold: In the light of directed evolution: Pathways of adaptive protein evolution University of Illinois

Random Mutagenesis • Traditional method • Point mutation based – error prone PCR • Frequency of beneficial mutations very low • Multiple mutations virtually impossible to come out positive University of Illinois

DNA Shuffling • Recombination used to create chimeric sequences containing multiple beneficial mutations • “Family shuffling” of homologous genes • “Synthetic shuffling” – oligonucleotides combined to create full-length genes • Whole-genome shuffling – accelerated phenotypic improvements • Drawback – high homology required University of Illinois

RACHITT • Random Chimeragenisis on Transient Templates • Small DNA fragments hybridized on a scaffold to create a chimeric DNA fragment • Incorporates low-homology segments University of Illinois

Even More Methods • Assembly of Designed Oligonucleotides (ADO) • Mutagenic and Unidirectional Reassembly (MURA) • Exon Shuffling • Y-Ligation-Based Block Shuffling • Nonhomologous Recombination – ITCHY, SCRATCHY, SHIPREC, NRR • Combining rational design with directed evolution University of Illinois

ADO • Nonconserved regions with conserved parts as linkers • PCR with dsDNA without primers • Full length genes in expression vector • Creates large diversity of active variants without codon bias for parental genes University of Illinois

MURA • Random fragmentation of parental gene • Reassembled with unidirectional primers for specific restriction site • Generates N-terminally truncated DNA shuffled libraries University of Illinois

Exon Shuffling • Similar to natural splicing of exons • Chimeric oligos mixed together, controlling combination of which exons to be spliced • Protein pharmaceuticals based on natural human genes – less immune response University of Illinois

Nonhomologous Recombination • Creation of new protein folds • Structures not present in nature – useful for evolution of multifunctional proteins • Incremental truncation for the creation of hybrid enzyme (ITCHY) – two genes in expression vector with unique restriction sites, blunt end digestion, ligated ->SCRATCHY • Nonhomologous random recombination – potentially higher flexibility in fragment size and crossover frequency University of Illinois

A Combination • Rational design with directed evolution • Success depends on ability to predict fitness of a sequence • Computationally demanding • Kuhlman et al created a new protein fold • Focuses library diversity for directed evolution University of Illinois

Directed Evolution in Action • Has been applied to improve polymerases, nucleases, transposases, integrases, recombinases • Applications in genetic engineering, functional genomics, and gene therapy • Optimized fluorescent proteins and small-molecule probes for imaging and techniques like FRET University of Illinois

The Case of a Fluorescent Protein • dsRED – parent protein evolved to have better solubility and shorter maturation time dsRed mCherry University of Illinois

Biochemical Catalysts • Useful in industry because of high selectivity and minimal energy requirements • Need for high availability at low costs • Active and stable under process conditions – not naturally occuring • Some reaction enzymes still yet to be identified and produced University of Illinois

Application to Enzymes • Improve stability and activity of biochemical catalysts • Can modify pH or temperature dependence • Substrate specificity or catalytic activity • MANY applications: • Proteolytic – Subtilisin in detergents • Cellulolytic and esterases – biofuel production • Cytochrome P450 superfamily – catalyze hydroxilation • Whole metabolic pathway evolution University of Illinois

Whole Metabolic Pathways • Closer to natural compound production • Single enzyme activity upregulation does not necessarily lead to increase in final product • Different methods: • Whole genome shuffling • Key enzymes targeted • Naturally expressed operons targeted • Target gene regulation factors University of Illinois

Pharmaceuticals • Therapeutic proteins • Antibodies – natural somatic recombination • Vaccines – improved effectiveness, less side effects • Viruses – gene therapy and vaccine development University of Illinois

Agriculture • Plants with increased tolerance for herbicides or expression of toxins • Golden rice • Expresses elevated beta-carotene (Vitamin A precursor) • Directed evolution - 23 times more insecond version • Not approved for distribution http://en.wikipedia.org/wiki/Golden_rice University of Illinois

Conclusions • Directed evolution can be a powerful tool taking advantage of nature’s power to improve upon itself • Used in a wide variety of applications for protein improvement – stability, activity, substrate specificity, etc • Potential for genetically engineering improved drugs or crops • Ultimately, combining tools will lead to better understanding and applications University of Illinois

Thank You! Questions? University of Illinois

Directed Evolution

Directed Evolution

Presentation Transcript

Directed graphs

Directed Consultation

Directed Reading

Directed Numbers

Directed Analysis

Directed Evolution

Directed Evolution of a Genetic Circuit

Directed Annotations

DIRECTED DIFFUSION

Protein Engineering and Directed Evolution

Directed Graphs

Directed Numbers

Directed Energy

DIRECTED

Directed Consultation

Directed Teaching

Directed Graphs

DIRECTED DIFFUSION

Directed Buy

Directed Graphs