SCALED BIOSYSTEMS Research & Development of molecular systems for control of plant growth and morphogenesis mazura@sci.muni.cz Screening and characterization of novel β-glucosidases for target probing of plant hormone system Bioinformatics, E.coli transformation and screening, DNA isolation + (basic molecular biology techniques) Racionální design a řízená evoluce proteinů the Bigpicture Protein structure Protein Engineering the Bigpicture Protein Engineering the Bigpicture Biosystems 10E-10 → 10E7m Scale is important ! Protein Engineering Rational Design (Directed Mutagenesis) Random Mutagenesis/ Directed Evolution Improved Protein Protein Engineering Google: AdvGentech5.ppt Rational Design (Directed Mutagenesis) Bioinformatics Lliterature search: current knowledge in this area, data mining, identification of possible problems, look for collaborations material etc. DNA and AA sequence information: composition, similarity, physicochemical properties, motifs, experimental design for directed mutagenesis or directed evolution procedure 3D structure derived information: structure motifs, similarity, surfaces, canals and cavities, check and evaluation of aminoacids possible involved in misfolding HotSpot Wizard 1.7 Google: AdvGentech5.ppt Protein Engineering Protein Engineering What can be engineered in Proteins ? -> Folding (+Structure): 1. Thermodynamic Stability (Equilibrium between: Native ⇔ Unfolded state) 2. Thermal and Environmental Stability (Temperature, pH, Solvent, Detergents, Salt …..) Protein Engineering What can be engineered in Proteins ? -> Function: 1. Binding (Interaction of a protein with its surroundings) How many points are required to bind a molecule with high affinity? 1. Catalysis (a different form of binding – binding the transition state of a chemical reaction) Increased binding to the transition state ⇒ increased catalytic rates !!! Requires: Knowledge of the Catalytic Mechanism !!! -> engineer Kcat and Km Protein Engineering Factors which contribute to stability: 1. Hydrophobicity (hydrophobic core) 1. Electrostatic Interactions: -> Salt Bridges -> Hydrogen Bonds -> Dipole Interactions 1. Disulfide Bridges 1. Metal Binding (Metal chelating site) 1. Reduction of the unfolded state entropy with X → Pro mutations Protein Engineering Design of Thermal and Environmental stability: 1. Stabilization of α-Helix Macrodipoles 1. Engineer Structural Motifes (like Helix N-Caps) 1. Introduction of salt bridges 1. Introduction of residues with higher intrinsic properties for their conformational state (e.g. Ala replacement within a α-Helix) 1. Introduction of disulfide bridges 1. Reduction of the unfolded state entropy with X → Pro mutations Protein Engineering Rational Design (Directed Mutagenesis) Random Mutagenesis/ Directed Evolution Improved Protein Protein Engineering Mutagenesis Mutagenesis -> change in DNA sequence -> Point mutations or large modifications Point mutations (directed mutagenesis): - Substitution: change of one nucleotide (i.e. A-> C) - Insertion: gaining one additional nucleotide - Deletion: loss of one nucleotide Consequences of point mutations within a coding sequence (gene) for the protein Silent mutations: -> change in nucleotide sequence with no consequences for protein sequence -> Change of amino acid -> truncation of protein -> change of c-terminal part of protein -> change of c-terminal part of protein Codon Usage is different in different species Mutagenesis Comparison of cellular and invitro mutagenesis General strategy for directed mutagenesis Requirements: - DNA of interest (gene or promoter) must be cloned - Expression system must be available -> for testing phenotypic change Applications of directed mutagenesis Approaches for directed mutagenesis -> site-directed mutagenesis -> point mutations in particular known area result -> library of wild-type and mutated DNA (site-specific) not really a library -> just 2 species Protein Engineering -> Mutagenesis used for modifying proteins Replacements on protein level -> mutations on DNA level Assumption : Natural sequence can be modified to improve a certain function of protein This implies: • Protein is NOT at an optimum for that function • Sequence changes without disruption of the structure • (otherwise it would not fold) • New sequence is not TOO different from the native sequence (otherwise loss in function of protein) consequence -> introduce point mutations Rational Protein Design ⇒ Site –directed mutagenesis Requirements: -> Knowledge of sequence and preferable Structure (active site,….) -> Understanding of mechanism (knowledge about structure – function relationship) -> Identification of cofactors…….. Site-directed mutagenesis methods Site-directed mutagenesis methods – Oligonucleotide - directed method Site-directed mutagenesis methods – PCR based Protein Engineering Rational Design (Directed Mutagenesis) Random Mutagenesis/ Directed Evolution Improved Protein Protein Engineering The concept of laboratory-directed protein evolution is not new. Systematic approaches to directed evolution of proteins have been documented since the 1970s One early example is the evolution of the EbgA protein from Escherichia coli, an enzyme having almost no -galactosidase activity. Through intensive selection of a LacZ deletion strain of E. coli for growth on lactose as a sole carbon source, the wild-type EbgA was “evolved” as a -galactosidase sufficient to replace the lacZ gene function (Campbell, J.1973). Directed Evolution – Random mutagenesis -> based on the process of natural evolution - NO structural information required - NO understanding of the mechanism required General Procedure: 1. Generation of genetic diversity ⇒ Random mutagenesis 2. Identification of successful variants ⇒ Screening and seletion Protein Engineering Directed Evolution Successful directed evolution has four requirements: (i) the desired function should be physically feasible, (ii) the function should be biologically or evolutionary feasible, i.e., a mutational pathway must exist to get from an original protein to tailored protein through ever-improving variants, (iii) it should be possible to make libraries of mutants complex enough to contain rare beneficial mutations and (iv) a rapid screen or selection reflecting the desired function should be available (Arnold,1998) Approaches for directed random mutagenesis -> random mutagenesis -> point mutations in all areas within DNA of interest result -> library of wild-type and mutated DNA (random) a real library -> many variants -> screening !!! if methods efficient -> mostly mutated DNA General Directed Evolution Procedure Random mutagenesis methods Limitation of Directed Evolution 1. Evolutionary path must exist - > to be successful 1. Screening method must be available -> You get (exactly) what you ask for!!! -> need to be done in -> High throughput !!! Successful experiments involve generally less than 6 steps (cycles)!!! Why? 1. Sequences with improved properties are rather close to the parental sequence -> along a evolutionary path 2. Capacity of our present methods to generate novel functional sequences is rather limited -> requires huge libraries ⇒ Point Mutations !!! Typical Directed Evolution Experiment Evolutionary Methods • Non-recombinative methods: -> Oligonucleotide Directed Mutagenesis (saturation mutagenesis) -> Chemical Mutagenesis, Bacterial Mutator Strains -> Error-prone PCR • Recombinative methods -> Mimic nature’s recombination strategy Used for: Elimination of neutral and deleterious mutations -> DNA shuffling -> Invivo Recombination (Yeast) -> Random priming recombination, Staggered extention precess (StEP) -> ITCHY Evolutionary Methods Type of mutation – Fitness of mutants Type of mutations: ⇒ Beneficial mutations (good) ⇒ Neutral mutations ⇒ Deleterious mutations (bad) ⇒ Beneficial mutations are diluted with neutral and deleterious ones !!! Keep the number of mutations low per cycle -> improve fitness of mutants!!! Random Mutagenesis (PCR based) with degenerated primers (saturation mutagenesis) Random Mutagenesis (PCR based) with degenerated primers (saturation mutagenesis) Random Mutagenesis (PCR based) Error –prone PCR -> PCR with low fidelity !!! Achieved by: - Increased Mg2+ concentration - Addition of Mn2+ - Not equal concentration of the four dNTPs - Use of dITP - Increasing amount of Taq polymerase (Polymerase with NO proof reading function) Random Mutagenesis (PCR based) DNA Shuffling DNase I treatment (Fragmentation, 10-50 bp, Mn2+) Reassembly (PCR without primers, Extension and Recombination) PCR amplification Random Mutagenesis (PCR based) Family Shuffling Genes coming from the same gene family -> highly homologous -> Family shuffling Random Mutagenesis (PCR based) Staggered Extension Process (StEP) Sequence Homology-Independent Protein Recombination (SHIPREC) Truncation for the Creation of Hybrid EnzYmes (ITCHY) Directed Evolution Difference between non-recombinative and recombinative methods Non-recombinative methods recombinative methods -> hybrids (chimeric proteins) ...engineering proteins by circular permutation Protein engineering must not necessarily involve the substitution of amino acids. The reorganization of a proteins’ primary sequence can also change the catalytic properties. We are using a technique called circular permutation to explore the effects of termini relocation on catalysis, as well as protein stability & dynamics. ...engineering proteins by circular permutation lipase B from Candida antarctica, an important biocatalyst in asymmetric synthesis. Upon relocating the protein termini by circular permutation, we observe up to 175-fold enhanced catalytic performance while preserving the enzyme’s enantio-selectivity. Stefan Lutz group HTS (High throughput screening) SystemHTS (High throughput screening) System Screening methodsScreening methods • Genetic selection • Growth • Survival • Display technology • In-vitro display (cell-free translation) • Phage display • Cell surface display (Bacteria & Yeast) • Solid or liquid-phase assay Screening systemsScreening systems • FACS ( Fluorescence-activated cell sorter) • Digital image spectroscopy • Fluorescence detection technique Screening in E.coli Theoretical implications for mutant library construction (size of the library) Standard Modified Library size containing 95% of variants 12 53 Library size with 95% chance of being complete 17.4 77 Mutant library parameters calculated for our sample via standard equations and modified by introducing empirical coefficient. Number of transformants (L)=20 and number of possible sequence variants (V)=4. Slonomax HTS (High throughput screening) SystemHTS (High throughput screening) System Screening methodsScreening methods • Genetic selection • Growth • Survival • Display technology • In-vitro display (cell-free translation) • Phage display • Cell surface display (Bacteria & Yeast) • Solid or liquid-phase assay Screening systemsScreening systems • FACS ( Fluorescence-activated cell sorter) • Digital image spectroscopy • Fluorescence detection technique H T S H T S H T S Microfluidics for HTS Microfluidics for HTS Todd Thorsen lab High Content Analysis and High Content Screening High Content Analysis (HCA) and High Content Screening (HCS) are imaging based multi-parametric approaches of cell analysis at the single-cell level. Originally developed as a complementary technology to traditional biochemical high-throughput screening (HTS) in drug discovery, today High Content Screening is established in a far broader area of the life science space as an unbiased method of imaging multiple cellular samples. Miami Project High Content Screening Core The core technology in the HCS uses the Cellomics VTI ArrayScan with a Thermo Fisher robot to feed the scanner. This system can scan about thirty 96 well plates over night, acquiring 9 fields per well, with 3-4 colors. This is a lot of data. Functional Diversity parental enzymes Activity at high pH Activity at low pH Activity in organic solvent Thermostability Increased catalytic efficiency Stereoselectivity New substrate specificity Shuffle Functional expression Protein Engineering - Applications Engineering Stability of Enzymes – T4 lysozyme -> S-S bonds introduction Protein Engineering - Applications Engineering Stability of Enzymes – triosephosphate isomerase from yeast -> replace Asn (deaminated at high temperature) Protein Engineering - Applications Engineering Activity of Enzymes – tyrosyl-tRNA synthetase from B. stearothermophilus -> replace Thr 51 (improve affinity for ATP) -> Design Protein Engineering - Applications Engineering Ca-independency of subtilisin Saturation mutagenesis -> 7 out of 10 regions were found to give increase of stability Mutant: 10x more stable than native enzyme in absence of Ca 50% more stable than native in presence of Ca Protein Engineering - Applications Site-directed mutagenesis -> used to alter a single property Problem : changing one property -> disrupts another characteristics Directed Evolution (Molecular breeding) -> alteration of multiple properties Protein Engineering – Applications Directed Evolution Protein Engineering – Applications Directed Evolution Protein Engineering – Applications Directed Evolution GFP