protein physics lecture 24
DESCRIPTION
PROTEIN PHYSICS LECTURE 24. PROTEINS AT ACTION: BIND TRANSFORM RELEASE . BIND: repressors. - turn - . Zn- fingers. DNA & RNA BINDING. Leu-zipper. BIND TRANSFORM BIND : Repressors. -BINDING-INDUCED DEFORMATION MAKES REPRESSOR ACTIVE, and IT BINDS TO DNA. - PowerPoint PPT PresentationTRANSCRIPT
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PROTEIN PHYSICS
LECTURE 24
PROTEINS AT ACTION:
BIND TRANSFORM RELEASE
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BIND: repressors
- turn -
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DNA & RNABINDING
Zn-fingers
Leu-zipper
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BIND TRANSFORM BIND: Repressors
-BINDING-INDUCED DEFORMATION MAKES REPRESSOR ACTIVE, and IT BINDS TO DNA
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BIND: Immunoglobulins
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Immunoglobulin
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BIND TRANSFORM RELEASE: ENZYMES
Note small active site
chymotrypsin
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Chymotrypsin catalyses hydrolysis of a peptide
Spontaneous hydrolysis: very slow
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Chymotrypsin
Chymotrypsin is one of the serine proteases. Chymotrypsin is selective for peptide bonds with aromatic or large hydrophobic side chains, such as Tyr, Trp, Phe and Met, which are on the carboxyl side of this bond. It can also catalyze the hydrolysis of easter bond. The main catalytic driving force for Chymotrypsin is the set of three amino acid known as catalytic triad. This catalytic pocket is found in the whole serine protease family.
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Properties of an Active SiteA shape that fits a specific substrate or substrates onlySide chains that attract the enzyme particular substrateSide chains specifically positioned to speed the reaction
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The Catalytic Triad
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chymotrypsin
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CHAIN CUT-INDUCED DEFORMATION MAKES ENZYME ACTIVE
Chymotripsin Chymotripsinogen
non-active cat. site
active cat. site
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SER-protease: catalysis
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Chymotrypsin Protein Hydrolysis
Stage #1
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Chymotrypsin Protein Hydrolysis
Stage #2
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Chymotrypsin Protein Hydrolysis
Stage #3
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Chymotrypsin Protein Hydrolysis
Stage #4
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Chymotrypsin Protein Hydrolysis
Stage #5
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Chymotrypsin Protein Hydrolysis
Stage #6
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Transition State Stabilization
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Chymotrypsin Kinetics
The initial "burst" in chymotrypsin-catalysed hydrolysis of the p-nitrophenyl acetate
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CHYMOTRYPSIN ACTIVE SITE with INHIBITOR
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Catalytic antibodies ABZYM = AntyBody enZYM
Antibodiesare
selectedto TS-likemolecule
Transition state (TS)
Preferentialbinding of TS:RIGID
enzyme
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A novel approach to drug delivery:
abzyme-mediated drug activation
Levi Blazer11/19/04
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Immunology ReviewImmunoglobulin GMonoclonal vs. polyclonal
http://www.path.cam.ac.uk/~mrc7/igs/img09.jpeg
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Monoclonal antibody production
Why monoclonal?
Don’t tell PETA Two forms of hybridoma preps:– Mouse Ascites– In vitro tissue culture.
http://ntri.tamuk.edu/monoclonal/mabcartoon.gif
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AbzymesCatalytic monoclonal antibodies: usually IgG, although in theory all Ig subclasses could be created.Created by immunizing an animal against a transition state analog (TSA) of the desired reaction. Any non-lethal TSA antigen that can be coupled to a carrier protein can potentially create a useful abzyme.
Ene
rgy
ΔG
Progress
Abzyme stabilization of transition state
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Abzymes – nearly endless possibilities
Acyl-transferCationic cyclizationDisfavored ring closureAldol/Michaels Hydride transferOxy-cope rearrangements
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AbzymesSpecific for a particular reactionBut - varied enough to accept a variety of substratesCan be produced for any non-lethal antigen.Easier to humanize
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Reactive immunization
A novel method to select and create the most catalytically active abzymes.Use an immunogen that will react a physiological pH or will bind covalently to a B-cell receptor.
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Reactive Immunization
Enaminone absorbs at 316 nm
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Overview of the old systemADEPT – Antibody directed enzyme prodrug therapyChemically modify a chemotherapy agent to make it minimally toxic.Prepare an antibody-enzyme conjugate that catalyzes the activation reaction Use a localized injection of conjugate to selectively activate drug in tumor tissue.
Chemotherapy agent
Inactivator:Removable throughenzyme/abzyme catalysis
TumorSuppression
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Benefits of ADEPT
Minimized toxicity = better!Localized activationPotentially lower required doses
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Problems with ADEPT
Immunological response to non-host enzyme (the antibody section can be humanized)
Conservation of active sites across speciesSelectivity of enzymeHard to engineer
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Mother Nature: Better than Reingold
Enzymes catalyze many reactions faster and with more specificity than synthetic catalysts.Problem: difficult to engineer an enzyme if there is no natural analog.Why not let Mother Nature do the design work for us? -- ABZYME! --
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Problems?
Antibodies bind molecules.How can you use this in humans?– Immune response– Diffusion– Protein stability– Side reactions? – Natural activation?
Cost!Ethical concerns.
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Methodology:synthesize prodrug with standard inactivator
Administer prodrug and catalytic antibody conjugate separately.
Administer catalytic antibody directly into Tumor.
Localized activation reduces unwanted toxicity
Normal Tissue Tumor
Y
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Doxorubicin activation
By abzyme 38C2
Topoisomerase I & II inhibitor
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Prodox synthesis
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Conclusions
Abzyme conjugated ADEPT:– Potentially more effective– Less toxic for non-cancerous cells– Sustainable for long periods of time due to
antibody half-life.