study and engineering of gene function: mutagenesis i. why mutagenize? ii. random mutagenesis,...

Study and engineering of gene function: mutagenesis

I. Why mutagenize?II. Random mutagenesis, mutant

selection schemesIII. Site-directed mutagenesis,

deletion mutagenesisIV. Engineering of proteinsV. Alterations in the genetic code

Course Packet: #30

Uses for mutagenesis

• Define the role of a gene--are phenotypes altered by mutations?

• Determine functionally important regions of a gene (in vivo or in vitro)

• Improve or change the function of a gene product

• Investigate functions of non-genes, eg. DNA regions important for regulation

Protein engineering-Why?

• Enhance stability/function under new conditions– temperature, pH, organic/aqueous

solvent, [salt]• Alter enzyme substrate specificity• Enhance enzymatic rate• Alter epitope binding properties

Enzymes: Biotech Cash Crops

From Koeller and Wang, “enzymes for chemical synthesis”, Nature 409, 232 - 240 (2001)

Obtaining useful enzymes

Random mutagenesis

• Cassette mutagenesis with “doped”oligos

• Chemical mutagenesis– expose short piece of DNA to mutagen,

make “library” of clones, test for phenotypes

• PCR mutagenesis by base misincorporation– Include Mn2+ in reaction– Reduce concentration of one dNTP

Random mutagenesis by PCR: the Green Fluorescent Protein

Screen mutants

Cassette mutagenesis (semi-random)

Strands synthesized individually, then annealed

Allows random insertion of any amino acid at defined positions

Translation of sequence

Random and semi-random mutagenesis: directed evolution

• Mutagenize existing protein, eg. error-prone PCR, doped oligo cassette mutagenesis

-- and/or --Do “gene shuffling”(Creates Library)

• Screen library of mutations for proteins with altered properties– Standard screening: 10,000 - 100,000

mutants– Phage display: 109 mutants

Gene shuffling: “sexual PCR”

Gene shuffling

For gene shuffling protocols you must have related genes in original pool: 1) evolutionary variants, or 2) variants mutated in vitro

Shuffling allows rapid scanning through sequence space:faster than doing multiple rounds of random mutagenesis and screening

Shuffling of one gene mutagenized in two ways

Gene shuffling--cephalosporinase from 4 bacteria

Single gene mutagenesis

Multiple gene shuffling

Screening by phage display: create library of mutant proteins fused to M13

gene III

Human growth hormone: want to generate variants that bind to hGH receptor more tightly

Random mutagenesis

Phage display:production of recombinant phage

The “display”

Phage display: collect tight-binding phage

The selection

Animation of phage display

http://www.dyax.com/discovery/phagedisplay.html

Site-directed mutagenesis:

primer extension method

Drawbacks:

-- both mutant and wild type versions of the gene are made following transfection--lots of screening required, or tricks required to prevent replication of wild type strand

-- requires single-stranded, circular template DNA

Alternative primer extension mutagenesis techniques

“QuikChangeTM” protocol

Advantage: can use plasmid (double-stranded) DNA

Destroys the template DNA (DNA has to come from dam+ host

Site-directed mutagenesis: Mega-primer

method

Megaprimer needs to be purified prior to PCR 2

Allows placement of mutation anywhere in a piece of DNA

A

B

Wild type template

First PCR

Second PCR

Domain swapping using “megaprimers” (overlapping PCR)

N- -C

Mega-primer

PCR 1

PCR 2

Domains have been swapped

Template 1

Template 2

PCR-mediated deletion mutagenesis

Target DNA

PCR products

Oligonucleotide design allows precision in deletion positions

Directed mutagenesis

• Make changes in amino acid sequence based on rational decisions

• Structure known? Mutate amino acids in any part of protein thought to influence activity/stability/solubility etc.

• Protein with multiple family members? Mutate desired protein in positions that bring it closer to another family member with desired properties

An example of directed mutagenesis

T4 lysozyme: structure known

Can it be made more stable by the addition of pairs of cysteine residues (allowing disulfide bridges to form?) without altering activity of the protein?

T4 lysozyme: a model for stability studies

Cysteines were added to areas of the protein in close proximity--disulfide bridges could form

More disulfides, greater stabilization at high T

Bottom of bar: melting temperature under reducing condtions

Top of bar: Melting temperature under oxidizing conditions

Green bars: if the effects of individual S-S bonds were added together

Stability can be increased - but there can be a cost in activity

The genetic code• 61 sense codons, 3 non-sense (stop) codons• 20 amino acids

• Other amino acids, some in the cell (as precursors to other amino acids), but very rarely have any been added to the genetic code in a living system

• Is it possible to add new amino acids to the code?• Yes...sort of

Wang et al. (2001) “Expanding the genetic code” Science 292, p. 498.

Altering the genetic code

Why add new amino acids to proteins?

• New amino acid = new functional group• Alter or enhance protein function

(rational design)• Chemically modify protein following

synthesis (chemical derivitization)– Probe protein structure, function– Modify protein in vivo, add labels and

monitor protein localization, movement, dynamics in living cells

How to modify genetic code?Adding new amino acids to the code--must bypass

the fidelity mechanisms that have evolved to prevent this from occurring

2 key mechanisms of fidelity

• Correct amino acid inserted by ribosome through interactions between tRNA anti-codon and mRNA codon of the mRNA in the ribosome

• Specific tRNA charged with correct amino acid because of high specificity of tRNA synthetase interaction

• Add new tRNA, add new tRNA synthetase

tRNA charging and usage

Charging: (tRNA + amino acid + amino acyl-tRNA synthetase)

Translation:(tRNA-aa + codon/anticodon interaction + ribosome)

• Chose tRNAtyr, and the tRNAtyr synthetase (mTyrRS) from an archaean (M.jannaschii)--no cross-reactivity with E. coli tRNAtyr and synthetase

• Mutate m-tRNAtyr to recognize stop codon (UAG) on mRNA

• Mutate m-TyrRS at 5 positions near the tyrosine binding site by doped oligonucleotide random mutagenesis

• Obtain mutants that can insert O-methyl-L-tyrosine at any UAG codon

Outcome

• Strategy allows site specific insertion of new amino acid--just design protein to have UAG stop codon where you’d like the new amino acid to go

• Transform engineered E. coli with plasmid containing the engineered gene

• Feed cells O-methyl tyrosine to get synthesis of full length gene

Utility of strategy

• Several new amino acids have been added to the E. coli code in this way, including phenyalanine derivatives with keto groups, which can be modified by hydrazide-containing fluorescent dyes in vivo– Useful for tracking protein localization,

movement, and dynamics in the cell

p-acetyl-L-phenylalanine

m-acetyl-L-phenylalanine

Some questions:

• What are the consequences for the cell with an expanded code?

• Do new amino acids confer any kind of evolutionary advantage to organisms that have them? (assuming they get a ready supply of the new amino acid…)

• Why do cells have/need 3 stop codons????