L4: Enzymology Flashcards
What are enzymes?
Proteins with catalytic properties in which they can accelerate the rates of chemical reactions
•Most enzymes exhibit absolute reaction specificity
Catalytic activity is dependent on multiple factors
•Proper protein structure and folding
•Available and appropriate substrate
•Sufficient enzyme (concentration and active sites)
•Optimal environmental conditions (temperature, pH)
Describe Protein Structure.
Primary structure
•Simplest level of structure; polypeptide sequence
Secondary structure
•Intra-polypeptide structures
•α helix, β pleated sheet
Tertiary structure
•Inter-sidechain structures due to –R group interactions
•Still within same overall polypeptide chain
Quarternary structure
•Inter-polypeptide structure from non-covalent interactions
Describe biological catalysis and models to characterize substrate binding.
Protein structure determines (in part) substrate selectivity:
- Active site(s) are relatively small compared to enzyme molecule
•Typically occur in clefts and crevices within protein
•Spatial arrangement in active site designed to complement intended substrate(s) - Models have been developed to characterize substrate binding
•“Lock and key” model describes spatial complementarity to promote enzyme specificity but does not explain stabilization of transition state
•Induced fit model enhances previous model by describing unique conformation of enzyme-substrate complex achieved only upon substrate binding
Describe energetics of catalysis in terms of free energy of activation (deltaG).
Enzymes accelerate reactions via decreasing free energy of activation (ΔG‡)
•ΔG‡ (also known as Gibbs free energy) refers to energy absorbed by substrate(s) required for conversion to product(s)
(see slide 8 figures)
List factors affecting enzymatic activity:
- pH
- Temperature
- Activators
- Inhibitors
- Salt and protein concentrations
Describe the effect of pH of enzyme catalysis.
Many enzymes display maximal catalytic activity between pH 7-8
•Reflects overall physiological pH when there are no underlying acid-base disorders
•pH extremes at either end can denature enzymes
Some enzymes have evolved to function at more extreme pH levels
•Pepsin is maximally active in acidic conditions (pH 1.5-2)
•Alkaline phosphatase is maximally active in alkaline conditions (pH 9-10)
pH conditions can be manipulated to achieve enzyme selectivity
•Enzyme isoform differentiation (LDH reaction influence by pH, see slide 10)
•Forcing reaction directions
Describe the effect of temperature on enzyme catalysis.
Enzymes generally have an optimal temperature of 37ºC
•Activity increases with temperature but denaturing will inevitably occur
Most analytical systems operate at 37ºC to reflect physiological conditions
•Reference methods for measured enzymes are developed at 37ºC
•Accurate temperature control on analytical systems is critical (+ 0.1ºC)
Temperature can be used to modulate enzymatic activity
•Cold storage for preservation
•Heat stability for isoform differentiation
Describe the effects of activators/cofactors.
Activators increase rate of enzyme reactions through promoting active state of enzyme and/or substrate
•Can be inorganic ions (cofactors) or organic molecules (coenzymes)
•Activators bind to apoenzyme to create holoenzyme
Many enzymes contain cofactors within their structure
•Mg2+ is essential for creatine kinase activity
Describe the effect of inhibitors on enzyme catalysis.
Enzyme inhibition can be reversible or irreversible
•Irreversible inhibition usually involves covalent bond between inhibitor and the enzyme; dissociation does not restore enzyme activity
•Sarin inhibition of cholinesterases
•Reversible inhibition involves equilibrium between inhibitor and enzyme; removal of inhibitor from the system will restore enzyme activity
Reversible inhibition can be categorized as competitive, noncompetitive and uncompetitive
•Competitive inhibitors competes with substrate for active site
•Noncompetitive inhibitors bind at a site distinct from active site (can occur with or without bound substrate)
•Uncompetitive inhibitors bind only to enzyme-substrate complex
Describe enzyme classification, including 6 enzyme classes.
Nomenclature of measured enzymes standardized by Enzyme Commission (EC) of International Union of Biochemistry
•Categorizes enzyme by class subclass sub-subclass enzyme number within sub-subclass
•Most enzymes are still referred to by their historical/practical names
Enzymes are generally classified into 1 of following 6 classes:
•Oxidoreductases: redox reactions
•Transferases: transfer of functional groups
•Hydrolases: hydrolysis reactions
•Lyases: group elimination to form double bonds
•Isomerases: isomerizations
•Ligases: bond formation coupled with ATP hydrolysis
Define isozymes and provide an example.
Isozymes – enzymes that catalyze the same reaction but have different amino acid sequences
•Isozymes generally fold to similar tertiary structures thus conferring similar affinities for and catalytic rates with substrates
•Some isozymes have completely different protein structures (cytoplasmic vs mitochondrial forms of CK and AST)
•Isozyme nomenclature is based on electrophoretic migration
•Furthest migration from the anode is designated isozyme 1
•Examples of clinically relevant isozymes: LDH, CK, amylase, ALP
Define isoforms and provide an example.
Isoforms – multiple forms of molecules (enzymes) due to post-translational modifications (PTMs)
- Multitude of PTMs can lead to many isoforms
- PTMs can be part of normal enzyme metabolism but can also arise pathologically
- PTMs will affect the physicochemical properties of the enzyme
- Affects catalytic activity and ability to detect analytically
Define macroenzymes and provide examples.
Macroenzymes – high molecular weight protein complexes derived from cross-linking via immunoglobulins or spontaneous polymerization
•Characterized by type of molecular complexing
•Type I: immunoglobulin bound enzymes
•Type II: polymerization, binding to lipoproteins or drugs
•Macroenzymes undergo slower clearance due to size and will accumulate in the circulation
•Clinically benign but can cause diagnostic conundrums as macroenzymes still retain catalytic activity
Provide strategies for macroenzymes.
Direct removal of macroenzyme
•PEG treatment
•Sepharose G resin (protein A)
•Ultrafiltration
Resolve macroenzyme from native enzyme
•Electrophoresis
•Size-exclusion chromatography
Measurement on multiple platforms
Urinary measurements
Define enzyme kinetics.
Enzyme kinetics are fundamental to understanding catalytic activity
•Knowledge of enzyme kinetics allows for development of activators/inhibitors as therapeutics
•Manipulation of enzyme kinetics is the core of enzyme-based assays in the clinical laboratory
•Enzyme kinetic theory based on the two-step process of a catalyzed reaction
