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Human Biochemistry [Option B] B7: Enzymes Objectives 7.1 – 7.7 Devin Vitello, Jess Plaskon, Erica Falvey, Ms. McLaughlin, Samantha Giffen, Sam Huddleston, Alex Sanfilippo. Objective B.7.1 Describe the characteristics of biological catalysts (enzymes). Devin Vitello.
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Human Biochemistry [Option B] B7: Enzymes Objectives 7.1 – 7.7 Devin Vitello, Jess Plaskon, Erica Falvey, Ms. McLaughlin, Samantha Giffen, Sam Huddleston, Alex Sanfilippo
Objective B.7.1 Describe the characteristics of biological catalysts (enzymes). Devin Vitello
Basic Characteristics of Enzymes • Catalysts • Speed up biological reactions by providing an alternate pathway for the reaction to occur • Lowers activation energy of reaction • Typically contain several hundred amino acids • Type of globular proteins • Single or multiple chains • Water soluble • 3D shape is called conformation • Conformation – determined by interactions between all its R groups and is essential for function • Tertiary and quaternary structure is critical to function • Well-defined tertiary structure makes them globular proteins and soluble in water • Some enzymes have more than one polypeptide so they also have a quaternary structure
Basic Characteristics of Enzymes (cont’d) • Contain an active site • Active site – area on enzyme where the substrate attaches • Can be affected by pH and temperature • Remains unchanged by reaction • Specific to a substrate • Exist in cytoplasm of cells • Control activity of cells at the molecular level • Some proteins need co-factors • Co-factors – non-protein molecules that bind for activity • Inorganic co-factors could be metal ions • Organic co-factors called coenzymes and could be vitamins
Substrate Specificity Low Specificity • Only a particular substrate will bind to the active site of the enzyme to initiate the reaction • Low specificity: • Enzyme only binds to one specific substrate • High specificity: • Enzyme binds to several related substrates Substrate A Enzyme 1 High Specificity Substrate A Substrate B Enzyme 2 Substrate C
Objective B.7.2 Compare inorganic catalysts and biological catalysts (enzymes). Jess Plaskon
Enzymes and Inorganic Catalysts • Not all catalysts are enzymes but all enzymes are catalysts • Both: • Increase rate of reaction • Cannot initiate a reaction • Provide alternate pathway • Decrease activation energy • Have no change in their composition • Create a product • Can be used repeatedly
Objective B.7.3 Describe the relationship between substrate concentration and enzyme activity. Erica Falvey
B.7.3 Describe the relationship between substrate concentration and enzyme activity. • As concentration increases, so does activity (to a point) • Since an enzyme can only process a certain quantity of substrate at once, the rate of reaction will eventually plateau • This occurs when all enzymes are saturated with substrate • Ultimately, this rate depends on how quickly the enzymes can process the substrates
B.7.3 Describe the relationship between substrate concentration and enzyme activity. A graph showing the effect of substrate concentration on enzymatic activity
B.7.3 Describe the relationship between substrate concentration and enzyme activity. • At low substrate concentrations, rate of reaction is proportional to substrate concentration • As substrate concentration increases, the rate decreases and is no longer proportional (as some active sites are occupied) • At high substrate concentrations, the rate is constant and independent of substrate concentration • The enzyme is saturated with substrate at this point
Objective B.7.4 Determine Vmax and the value of the Michaelis constant (Km) by graphical means and explain its significance. Ms. McLaughlin
Objective B.7.5 Describe the mechanism of enzyme action, including enzyme substrate complex, active site, and induced fit model. Samantha Giffen
Enzyme Characteristics • Basic mechanism by which enzymes catalyze a reaction starts with the binding of a substrate(s) to an active site • Binding of the substrate causes changes in the distribution of electrons in the chemical bonds of the substrate, ultimately leading to the reaction that forms the products • The enzyme and the substrate form a temporary binding to form the enzyme-substrate complex
Induced Fit Theory • Substrate is available to go into an active site, but it is not an exact fit • Active site of the enzyme changes shape to give a better fit • Note: Substrate does NOT change, active site does • Enzyme-Substrate Complex then forms • No chemical bonds are formed between the enzyme and active site • Catalyzed reaction takes place • Product(s) is released and enzyme returns to its original shape
Enzyme Substrate Complex • The enzyme is usually much bigger than the substrate • The binding in the complex depends on the R groups of the amino acids in the active site and can include hydrophobic interactions, dipole-dipole interactions, hydrogen bonds, and ionic attractions • The binding puts a strain on the substrate molecule, so facilitates the breaking and forming of bonds • Once the substrate has reacted, it no longer fits in the active site so it detaches • The enzyme is released unchanged and is able to catalyze another reaction
Enzyme + Substrate → Enzyme Substrate Complex → Enzyme + Product Main Idea All the reactions can be summarized using E for enzyme, S for substrate, and P for product: E+S E-S E-P E+P *All the reactions are equilibrium reactions so are reversible depending on the conditions.
Enzyme Specificity • Absolute- enzyme will only bind to one substrate • Group specific- enzyme will only react with substrates with similar functional groups, side chains, or positions on a chain • Bond specific- enzyme will only react with a specific chemical bond
Enzyme Specificity • The specificity of an enzyme depends on its tertiary and quaternary structure • The part of the enzyme that reacts with the substrate is the active site • Active site is specific to certain molecules • Groove or pocket in the enzyme where the substrate will bind • Not necessarily rigid • Can alter its shape to allow for a better fit (induced fit theory)
Review Questions • What is an enzyme-substrate complex and what is it used for? • What is the purpose of an active site and how does it work? • What is the induced fit model?
References • Neuss, G. (2007). Chemistry. Oxford, NY: Oxford University Press. • Ophardt, C.E. (2003). Mechanism of enzyme action. Retrieved from http://www.elmhurst.edu/~chm/vchembook/571lockkey.html
Objective B.7.6 Compare competitive inhibition and non-competitive inhibition. Sam Huddleston
The Basics • In equilibrium, an enzyme binds to a substrate in order to form an enzyme-substrate complex • The enzyme-substrate complex can dissociate or irreversibly convert the substrate to a product • Enzyme inhibition is a common goal for the pharmaceutical industry • All inhibitors cause the substrate to react at a lower rate than without the inhibitor
Competitive Inhibition • Competitive inhibitors bind at the active site of the enzymes to form an enzyme-inhibitor complex • The inhibitor blocks the active site, and the substrate cannot bind until the inhibitor detaches
Competitive Inhibition • Because the inhibitor and substrate compete for the same site, raising the substrate concentration can eventually overcome the inhibitor, and Vmax can be achieved • Although Vmax can be achieved, a competitive inhibitor raises Km, indicating that the attraction of the enzyme for the substrate is lower in the presence of the inhibitor • The effect of a competitive inhibitor in a Lineweaver-Burk plot is both to move the x-intercept and increase the slope
Non-competitive Inhibition • Non-competitive inhibitors bind at an allosteric site on the enzyme and leave the active site unblocked • When the inhibitor binds, the shape of the active site is changed so it cannot bind the substrate.
Non-competitive Inhibition • In a pure non-competitive system, the substrate has an equal attraction for both the enzyme-inhibitor complex and the enzyme • In a pure non-competitive system, the Km value is unchanged while the Vmax is lowered • Pure non-competitive inhibitors are virtually unknown
Examples of Non-competitive Inhibition • Metal ions (ex. Lead, mercury, silver, copper) • Cyanide • Penicillin blocks an enzyme in bacteria • Anti-cancer drugs block cell division in tumors
Remember! • Enzyme inhibition isn’t always a bad thing • At times, it’s necessary to control the activity of enzymes (especially in our bodies) • Our bodies will induce “negative feedback”
Possible Review Questions (?) • What is the main difference between competitive and non-competitive inhibition? • Which one is competitive, and which one is non-competitive in the following picture: Which one is this? Which one is this?
My Source Teipel, J. W.; Hill, R. L. J.(1968) Biol. Chem.243, 5679. Retrieved from:http://www.chm.davidson.edu/erstevens/Lineweaver/Lineweaver.html
Objective B.7.7 State and explain the effects of heavy-metal ions, temperature changes, and pH changes on enzyme activity. Alex Sanfilippo
Heavy Metals • Common Poisonous Heavy Metals: - Lead, Copper, Mercury, Silver • Non-competitive inhibitors • Prevent enzyme from functioning properly • Change shape of enzyme and active site • Do not interact with the enzyme at the active site • React with sulfhydral (-SH) groups • Found in cysteine • -SH -S(Metal) • Interaction between enzyme and inhibitor interferes with tertiary structure and side chains Enzyme and substrate cannot bind because of shape change
Temperature Change • Increase in temperature gives particles involved in reactions more energy • More reactants can reach activation energy Increases rate of enzyme catalyzed reactions • Optimum Temperature • Temperature at which rate of enzymatic reactions are the greatest • Excessive raise in temperature Enzymes denature • H-bonds break Disrupts tertiary structure • This leads to irreversible damage • Low temperature can deactivate an enzyme • But the damage is usually reversible
Temperature Change and Enzyme Activity in the Body • Optimum Temperature of Enzymes • Usually at core body temperature (37oC) • Enzymes denature at excessively high temperatures • Tertiary structure is disrupted permanently • Note: Covalent bonds are not broken – That’s what happens during digestion • Low temperature deactivates enzymes • So, any change of core body temperature of 2+ degrees (e.g. fever, hypothermia, etc.) can be fatal
pH Change • Optimal pH • Rate of enzyme catalyzed reaction reaches its maximum • Depends on pKa and pKb of R groups of amino acids • Especially at the active site • For example: • Pepsin’s optimal pH is 2 • Acidic environment • Stomach • Trypsin’s optimal pH is 8 • More alkaline environment in the intestines • pH change • Interferes with acidic and basic molecules in protein side chains Alters tertiary structure • Tertiary structure is disrupted Enzyme and substrate can’t bind
Sources Neuss, Geoffrey (2007). IB study guides: Chemistry. New York: Oxford University Press.