abzymes, ribozymes
TRANSCRIPT
ABZYMES, ISOENZYMES, RIBOZYMES
B. C. Muthubharathi2016501012
Abzymes Antibodies/Enzymes Catmab (catalytic Monoclonal antibody) Abzymes = Antibody +Enzymes
Similarity and Differences
Enzymes - bind in high energy state Antibody - binds the complementary structure
in its ground state ability to bind with compounds with great
specificity and high affinity
1986 - 1st monoclonal catalytic antibodies (abzymes) against a chemically stable analog of the transition state of a reaction were obtained
Peter Schultz and Richard Lerner Having structural complementarity for the transition
state of an enzyme catalyzed reaction They bind strongly to the transition state with high
association constant, enhancing the reaction rate Abzymes reduce rotational entropy
Sources
Do not occur naturally in human Found in normal human ( Anti Vasoactive intestinal
peptide autoantibody which detect the level of vasoactive intestinal peptide)
Natural abzymes in Patients with ADBlood of Asthuma – Reduce the rotational entropyAutoimmune diseased person (SLE)
Protoabzymes Proteolytic activity Found in AD patients – Asthuma, Multiple sclerosis, Thyroiditis,
Myocarditis
DNA abzymesDNA hydrolyzing activityPowerful regulator of apoptosis ( pathogenic role is
not clear)Cytotoxicity mechanism in systemic autoimmune
disease & Tumors
Production
Antibody molecules are produced by the immune system to bind and neutralize foreign substances called antigens
Foreign proteins of bacteria , viruses and some chemical molecules act as antigens
Transition state – State corresponding to highest potential energy along this reaction coordinates
Transition state analog- Molecules which are more stable than the transition state itself, but they mimic their 3D structure
Antibody Antigen Neutralize antigen
Foreign protein / HaptenTSA act as a hapten at TS and elicit antibody production, Antibody
isolated from serum used as abzymes
Substrate Transition stateProduct
Transition analog
Reactions of abzymes
Amide hydrolysis Trans
esterificationPhoto cleavage
OxidationDecarboxyl
ationCyclization
Hydrolysis of enol ethers
Reduction of diketone
Hydrolysis of hydroxyester Hydroxyester forms cyclic intermediate during hydrolysis
Hydroxyester Cyclic intermediate lactone Phenol
Increasing the reaction rate
Anti cyclic intermediate antibody
Cyclic phosphonate ester (Ag)( Mimic cyclic intermediate)
Hydroxyester forms cyclic intermediate during hydrolysis
Hydroxyester Cyclic intermediate lactone Phenol
Increasing the reaction rate
Anti cyclic intermediate antibody
Cyclic phosphonate ester (Ag)( Mimic cyclic intermediate)
Hydrolysis of ester Ester –Tetrahedral intermediate
P- nitrophenylacetate Tetrahedral p- nitrophenyl phosphate Acetic acid
intermediate
Binding (Catalysis)
Antibodies against phosphate analog of ester
phosphate analog of ester(Mimic the tetrahedral intermediate)
Pyridoxal 5’-P dependet aminotransferase reactionD alanine +pyridoxal 5’-p Pyruvate + pyridoxamine 5’ –p
Catalyze
Ab raised
N- (5’ phosphopyridoxyl)- lysineCoupled with carrier protein
Biosynthesis of heme ( Metallation) Introduction of ferrous ion into protoporphyrin
Ferrochelatase Mechanism – Distortion of pyrole ring by 36 to create bent transition
state
Protoporphyrin Bent transition state
heme (product)
N methyl mesoporphyrin Ab complementary (TSA) to TS
Activation of anticancer drug by abzymesThymidylate synthase Building block of DNA
5- fluorodeoxyuridasine-5 phosphateAbzymes
5- fluorouracil (Anticancer drug)
ISOENZYMES Same reaction but differ in aminoacid sequences, kinetic
properties and electrophoretic mobility
ONTOGENETIC – Same species – Intraspecific variants PHYLOGENETIC – Different species - Interspecific variants
HOMOLOGUES – Similar molecular structure &catalytic propertyEg.Phospholipase D
ANALOGOUS - Different molecular structure but catalyzing same reaction
Eg. Phenylalanine transaminase
List of isoenzymesLactate dehydrogenaseHexokinaseCreatin phosphokinasePhosphorylaseAlkaline phosphataseCytochrome P450G - 6 – P dehydrogenaseGlutamate dehydrogenase
Differ in amino acid composition and kinetic behavior so, by using electrophoretic method, isoenzymes can be separated
LACTATE DEHYDROGENASE Tetramer / oligomer (Different polypeptide chain) Four polypeptide subunit 2 types(H- Heart, M- Muscle) H4, H3M, H2M2, HM3, M4 (Catalyze the same reaction) Pyruvate + NADH + H+ Lactate + NAD
H4 LDH1 Heart MuscleH3M LDH2 RBC, Brain Muscle, LiverH2M2 LDH3 Brain,
LeucocyteHeart, Liver
HM3 LDH4 Leucocyte Heart, RBC,BrainMuscle, Liver
M4 LDH5 Muscle, Liver Other tissues
Increased level
Decrerased levlel
Glycolysis Pyruvate Lactate Blood
LDHLDH5 (M4) work best in NAD+ - regenerating directionBecause, activate muscle tissue become anaerobicHEART TISSUE
AerobicLactate as fuelLactate Pyruvate Citric acidCycleLDH1(H4) inhibited by excess pyruvate
DIAGNOSTIC ENZYME ( increased level)Heart attack, Hemolytic anemia, Muscle damage, Muscular
dystrophy, Stroke, Lung tissues, Death, hepatitis
Hexokinase 4 Isoenzymes I, II, III, IV I – Fastest mobility towards anode IV – Slowest mobility towards anode (also called as
Glucokinase) I – Brain, Heart, Kidney II – Skeletal muscle, Adipose tissue III – Liver, Spleen IV – Liver
D- Glucose + ATP D – Glucose + ADP
ANGIOTENSIN CONVERTING ENZYME 2 ISOENZYME
Somatic isoenzymesGerminal isoenzymes
Somatic – Lung, Vascular endothelial cells, Renal epithelial cells, Testicular epithelial cells, Testicular epithelial cellsGerminal – Sperm Regulate the blood pressure
Creatine phosphokinase 2 isoforms
B- BrainM- Muscle
Catalyze phosphorylation of crreatineCreatine + ATP creatine phosphate
CPK I – BB - Brain, LungsCPK II – MB – HeartCPK III – MM- Skeletal muscle
RIBOZYMESRIBONUCLEIC ACIDNot proteinAntisense RNAmolecules8 natural ribozymes1989 nobel prize, Thomas CzechCatalytic RNA moleculesRibonucleic acid enzymes/ RNA enzymes,RNAzymesRNA metaloenzymes~40 to 50 nucleotides in length
Sid Altman Tom Cech
separate catalytic substrate-binding domains Hammerhead, Hairpin for Therapeutic purpose Hammerhead ribozymes are preferable Ability to more efficiently recognize, Bind to, and cleave a range of different mRNAs. By altering the substrate-binding domain, a ribozyme can be
engineered to specifically cleave any mRNA sequence Inhibit the expression of a variety of viral genes and
significantly inhibit the proliferation of numerous organisms
Mang Yu &Coworkers Use ribozymes to provide WBC with resistance to HIV infection
In cell culture, ribozymes inhibit the expression of(1) human cytomegalovirus transcriptional
regulatory proteins, resulting in a 150-fold decrease in viral growth;
(2) human herpes simplex virus type1 transcriptional activator, resulting in a reduction of around 1,000-fold in viral growth; and
(3) A reovirus mRNA encoding a protein required for viral proliferation Hammerhead – treat collagen-induced arthritis in mice
