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Overview of Protein Expression

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Introduction to Isotope Labeling of Proteins For NMR Overview of Protein Expression Expression systems are based on the insertion of a gene into a host cell for its – PowerPoint PPT presentation

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Title: Overview of Protein Expression


1
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Expression systems are based on the insertion of
    a gene into a host cell for its
  • translation and expression into protein .
  • Many recombinant proteins can be expressed to
    high
  • levels in E. coli systems.
  • most common choice for expressing labeled
  • proteins for NMR
  • Yeast (Pichia pastoris, Saccaromyces cerevisiae)
    is an
  • alternative choice for NMR protein samples
  • issues with glycosolyation of protein, which is
    not
  • a problem with E. coli.
  • choice between E. coli and yeast generally
    depend
  • on personal experience.
  • Insect cells (Baculovirus) and mammalian cell
    lines
  • (CHO) are very popular expression systems that
    are
  • currently not amenable for NMR samples
  • no mechanism to incorporate isotope labeling or
  • the process is cost prohibitive
  • 15N labeling in CHO cells can cost 150-250K!

2
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • First step of the process involves the insertion
    of the DNA coding region of the protein
  • of interest into a plasmid.
  • plasmid - small, circular pieces of DNA that are
    found in E. coli and many other bacteria
  • generally remain separate from the bacterial
    chromosome
  • carry genes that can be expressed in the
    bacterium
  • plasmids generally replicate and are passed on
    to daughter cells along with the
  • chromosome
  • Plasmids are highly infective, so many of the
    bacteria will take up the particles from
  • simple exposure.
  • Treating with calcium salts make membranes
    permeable and increase uptake of
  • plasmids
  • Plasmids used for cloning and expressing
    proteins are modified natural vectors
  • more compact and efficient
  • unnecessary elements removed
  • Some Common plasmids
  • pBR322
  • pUC19
  • pBAD

3
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Basic Features of a Plasmid

Defined region with restriction sites for
inserting the DNA
Gene that provides antibiotic resistance
(ampicillin resistance in this case)
replication is initiated
4
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Restriction Enzymes
  • Recognizes and cuts DNA only at
  • particular sequence of nucleotides
  • blunt end cleaves both ends
  • sticky ends cleaves only one strand
  • Complimentary strand from DNA insert will
    match sticky end and insert in plasmid
  • followed by ligation of the strands (T4 DNA
    Ligase)

5
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Restriction Enzymes
  • Very large collection of restriction enzymes
    that target different DNA sequences

6
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Restriction Enzymes
  • Restriction Map of plasmid showing the location
    where all restriction enzymes will
  • cleave.
  • allows determination of where how to insert a
    particular DNA sequence
  • want a clean insertion point, dont want to
    cleave plasmid multiple times

7
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Next step of the process involves getting E.
    coli to express the protein from the plasmid.
  • this occurs by the position of a promoter next
    to the inserted gene
  • two common promoters are
  • lac complex promoter
  • T7 promoter

lac complex promoter Transcription is simply
switched on by the addition of IPTG (isopropyl
ß-D-thiogalactoside) to remove LacI repressor
protein. IPTG binds LacI which no longer binds
the promoter region allowing transcription to
occur
8
Introduction to Isotope Labeling of Proteins For
NMR
Overview of Protein Expression
  • T7 promoter Again, transcription is switched on
    by the addition of IPTG to remove LacI repressor
    protein.
  • IPTG binds LacI which no longer binds the
    promoter region allowing transcription/production
    of T7 RNA polymerase to occur.
  • T7 RNA polymerase binds the T7 promoter in the
    plasmid to initiate expression of the protein
  • two-step process leads to an amplification of
    the amount of gene product - produce very high
    quantities of protein.

9
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Next step of the process involves growing the E.
    coli cells
  • Shake Flask
  • cells are place in a growth media that
    provides the
  • required nutrients to the cell
  • amino acids, vitamins, growth factors, etc
  • shake the flask at a constant temperature of 37O
  • keeps homogenous mixture
  • increases oxygen uptake
  • grow cells to proper density (OD 0.7 at 600nm)

LB Broth Recipe (Luria-Bertani) 10
g tryptone 5 g of yeast extract 10 g of NaCl
Cell growth in a Shake flask
10
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Next step of the process involves growing the E.
    coli cells
  • Bioreactors
  • more efficient
  • higher production volumes
  • can be 100s of liters in size
  • Can grow cells to a higher density
  • better control of pH
  • better control of oxygen levels
  • better control of temperature
  • better control of mixing
  • sterile conditions

14 liter bioreactor
11
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Next step is to harvest and lysis the cells and
    purify the protein
  • Now that E. coli is producing the desired
    protein, need to extract the protein from the
    cell and purify it.
  • the amount of protein that can be obtained from
    an expression system is highly variable and can
    range from mg to mg to even g quantities.
  • it depends on the behavior of the protein,
    expression level, method of fermentation and the
    amount of cells grown

over-expressed protein
Biotechnology Letters (1999) 12,1131
12
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Cell Lysis
  • A number of ways to lysis or break open a cell
  • Gentle Methods
  • Osmotic suspend cells in high salt
  • Freeze-thaw rapidly freeze cells in liquid
    nitrogen and thaw
  • Detergent detergents (DSD) solubilize cellular
    membranes
  • Enzymatic enzymatic removal of the cell wall
    with lysozyme
  • Vigorous Methods
  • Sonication sonicator lyse cells through shear
    forces
  • French press cells are lysed by shear forces
    resulting from forcing cell
  • suspension through a
    small orifice under high pressure.
  • Grinding hand grinding with a mortar and
    pestal
  • Mechanical homogenization - Blenders or other
    motorized devices to grind
    cells
  • Glass bead homogenization - abrasive actions of
    the vortexed beads break

  • cell walls

French Press
13
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Protein Purification - A large number of ways to
    purify a protein
  • protocols are dependent on the protein
  • chromatography is a common component of the
    purification
  • protocol where typically multiple columns are
    used
  • a) size-exclusion b) ion exchange
  • c) Ni column d) heparin
  • e) reverse-phase f) affinity column
  • dialysis for buffer exchange and removal of
    low-molecular weigh
  • impurities
  • To increase the ease of purifying a protein
    generally include a unique
  • tag sequence at the N- or C-terminus
  • HIS tag add 6 histidines to the N- or C-
    terminus
  • - preferentially binds Ni column
  • FLAG tag DYKDDDDK added to terminus
  • - preferentially binds M1 monoclonal antibody
    affinity
  • column
  • glutathione S-transferase (GST) tags fusion
    protein
  • - readily purified with glutathione-coupled
    column

14
Introduction to Isotope Labeling of Proteins For
NMR
  • Overview of Protein Expression
  • Some Common Problems
  • protein is not soluble and included in inclusion
    bodies
  • insoluble aggregates of mis-folded proteins
  • inclusion bodies are easily purified and can be
    solubilized using denaturing conditions
  • How to re-fold the Protein?
  • Finding a re-folding protocol may take
    significant effort (months-years?) and
  • involve numerous steps
  • something to be avoided if possible
  • protein is toxic to cell
  • find a different expression vector or use a
    similar protein from a different
  • organisim
  • proper protein fold
  • proper disulphide bond formation may need to
    re-fold the protein
  • presence of tag may inhibit proper folding may
    need to remove the tag
  • low expression levels
  • try different plasmid constructs

15
Introduction to Isotope Labeling of Proteins For
NMR
  • 13C and 15N Isotope Labeling of the protein
  • cells need to be grown in minimal media
  • use 13C glucose to achieve 100 uniformed 13C
    labeling of protein
  • use 15N NH4Cl to achieve 100 uniformed 15N
    labeling of protein
  • glucose and NH4Cl are sole source of carbon and
    nitrogen in minimal media

Journal of Biomolecular NMR, 20 7175, 2001.
16
Introduction to Isotope Labeling of Proteins For
NMR
  • 13C and 15N Isotope Labeling of the protein
  • Usually isotope labeling does not negatively
    impact protein expression
  • Some Common Problems with Isotope Labeling
    Problems
  • minimal media stresses cells
  • slower growth
  • typically lower expression levels
  • isotope labeling of All proteins
  • minimal isotope affect may affect
  • enzyme activities
  • isotope labeling of expressed protein may
  • affect protein properties
  • solubility?
  • proper folding?

1H-15N HSQC spectra of 13C,15N labeled protein
17
Introduction to Isotope Labeling of Proteins For
NMR
  • 13C and 15N Isotope Labeling of the protein
  • Can introduce specific amino acid labels
  • A variety of 13C and 15N labeled amino acids are
    commercial available
  • Add saturating amounts of 19 of 20 amino acids
    to minimal growth media
  • Add 13C and 15N labeled amino acid prior to
    protein expression
  • media is actually very rich and the cells grow
    very well
  • cells exclusively use the supplied amino-acids
    to synthesize proteins
  • all of the occurrences of the amino-acid are
    labeled in the protein
  • may be some additional labeled residues if the
    labeled amino
  • acid is a precursor in the synthesis of other
    amino acids.

1H-15N-HSQC of His, Tyr Gly labeled SH2-Domain
no mechanism to label one specific amino acid i.e
Gly-87
18
Introduction to Isotope Labeling of Proteins For
NMR
  • 13C and 15N Isotope Labeling of the protein
  • Can label specific segment in protein
  • use peptide splicing element intein (Protozyme)
  • inteins are insertion sequences which are
    cleaved off after translations
  • preceding and succeeding fragments are ligated ?
    extein

Protein of Interest
15N-labeled
J. Am. Chem. Soc. 1998, 120, 5591-5592
19
Introduction to Isotope Labeling of Proteins For
NMR
  • 13C and 15N Isotope Labeling of the protein
  • Can also label only one component of a complex
  • simply mix unlabeled and labeled components to
    form the complex
  • greatly simplifies the NMR spectra
  • only see 13C, 15N NMR resonances for labeled
    component of complex
  • can see interactions (NOEs) between labeled and
    unlabeled compoents

J. OF BIOL. CHEM. (2003) 278(27), 2519125206
20
Introduction to Isotope Labeling of Proteins For
NMR
  • 2H Labeling of the protein
  • simply requires growing the cells in D2O
  • severe isotope effect for 1H?2H
  • stresses the cell
  • E. coli needs to be acclimated to
  • D2O
  • pass cells into increasing
  • percentage of D2O
  • cell growth slows significantly in
  • D2O (18-60 hrs)
  • level of 2H labeling depends on the
  • percent D2O the cells are grown in
  • aromatic side-chains will be highly
  • protonated if 1H-glucose is used
  • exchange labile N2H to N1H by
  • temperature increase or chemical
  • denaturation of the protein

21
Introduction to Isotope Labeling of Proteins For
NMR
  • 2H Labeling of the protein
  • As we have seen, deuterium labeling a protein
    removes a majority of protons necessary for
    protein structure calculation
  • can introduce site specific protonation to
    regain some proton based distance
  • constraints
  • label the methyl groups of Leu, Ile, and Val by
    adding
  • to the growth media.
  • use 1H-glucose to generate 1H-aromatic
    side-chains

3,3-2H2-13C 2-ketobutyrate.
2,3-2H2-15N, 13C Val
Metabolic pathway for generating 1H-methyl-Ile
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