MCAT Biochemistry Lesson 3: Enzyme Kinetics

What are the similarity(s) and difference(s) between the following: (1) Competitive inhibitors (2) Uncompetitive inhibitors (3) Non-competitive inhibitors (4) Mixed inhibitors

Competitive inhibitors resemble the substrate and will bind to directly to the enzyme's active site (Substrate and inhibitor compete for the active site!- Often the inhibitor has higher affinity for the active site but increase concentration of substrate allows it to mathematically compete for substrate). Uncompetitive inhibitors bind at an allosteric site of the enzyme while the substrate is already bound to the enzyme (UN = ES, 2 letters on each side). When substrates bind to enzyme a conformational change happens creating a space for uncompetitive inhibitor to bind. Inhibitor creates Enzyme Substrae Inhibitor complex which blocks activity of enzyme. Non-competitive inhibitors have equal affinity for the enzyme and the enzyme-substrate complex (NON = E or ES, 3 letters on each side). In Non comepetive inhibition the enzyme already has allosteric site before substrate even binds. Inhibitor binds at the allosteric site. Kcat (turnover number) gets lowered. Mixed inhibitors have different affinity for the enzyme and enzyme-substrate complex (just like NON, but it is uneven/mixed). This causes Km to be either increased or decreased but doesn't remain the same like non competitive

Describe enzyme regulation via reversible covalent modification:

Covalent addition of a group that regulate enzyme activity (ex. addition of a phoshpahte group via kinase)

What is methylation?

Covalent addition of a methyl group

What is acetylation?

Covalent addition of an acetyl group Ex. Addition of an acetyl group to a lysine can make it lose its charge which can disrupt any sort of electrostatic interactions that may occur such as that between DNA and histones. Makes DNA loosely bind to histones instead of tight

These are the two steps of enzyme catalysis: E + S => ES => E + P What are the respective reaction rate formulas?

E + S => ES => E + P Rate1 = k1 [E][S] Rate2 = k2 [ES]

Describe enzyme regulation via Isoenzyme:

Enzymes that differ in aa sequence but carry out same reaction. They not only differ in aa sequence an 3d structure but also differ in enzyme kinetics (such as vmax and km)

True or false? Adding more catalyst after a catalytic amount has already been added will increase the rate of reaction.

False. Adding more catalyst after a catalytic amount has already been added will NOT AFFECT the rate of reaction. You only need a small amount ("a catalytic amount") of catalyst for it to do its job. Adding more will not do anything. Pretty much saying that if all substrate has been converted to product, adding more enzyme won't do anything

*CRB* True or false? UV Spectroscopy is typically used to determine the concentration of proteins in a sample because it requires little decontamination.

False. UV Spectroscopy is typically used to determine the concentration of proteins in a sample, but it is very sensitive to contaminatints in the sample!

Draw the percent saturation curves of Hemoglobin and Myoglobin. How do they differ?

Hemoglobin has a sigmoidal "S" shaped curve because it exhibits positive-cooperative binding. Myoglobin has a hyperbolic curve since it exhibits non-cooperative binding.

*CRB* What type of binding is occuring if Hill's Coefficient is equal to 1?

If Hill's Coefficient is equal to 1, then the enzyme exhibits Non-Cooperative Binding.

Describe enzyme regulation via enzyme concentration:

If you control the amount of transcription on a specific gene that encodes for an enzyme then we can control how much of an enzyme is in a cell and in turn you can regulate activity of or functionality level of an enzyme

How do we increase rate of reaction?

Increase substrate or enzyme concentration Note that rate of reaction is dependent on the constant K and the concentration of the enzyme and substrate Such as K1 [E][S]

*CRB* Compare how drastically increasing and decreasing pH can differently cause Denaturation.

Increasing pH will cause deprotonation of key residues in the active site and affect hydrogen bonding of the secondary structure. Decreasing pH could protonate key residues in the active site, also affecting the hydrogen bonding of the secondary structure, and could also protonate the Cystines, breaking all disulfide bonds.

What is the equation for the enzyme turnover number (Kcat)? Kcat is also known as catalytic constant

Kcat = Vmax/ [E]T Vmax is the maximum velocity of the enzyme [E]T is the concentration of the enzyme. unit: 1/sec Kcat is how many units of substrate an enzyme can convert to products in 1 sec at maximum speed Note from this equation: Vmax= Kcat*[E]

Does Kcat change with competitive inhibition?

No. Recall Kcat= Vmax/[e]total Vmax does not change and the total of active enzymes is still the same so no change in Kcat

*CRB* Match each of the following types of Gel Electrophoresis with their descriptions. I. Polyacrylamide Gel. II. Native PAGE III. SDS-PAGE (A) Can only give mass-to-charge ratios, so could have decreased separation of proteins with different masses or charges. This does NOT denature the protein. (B) The typical medium used for protein electrophoresis. (C) Uses a Detergent to break all noncovalent interactions, including affecting the charges of proteins. They are only separated based on size.

Note that PAGE stands for Polyacrylamide Gel Electrophoresis I. Polyacrylamide Gel - (B) The typical medium used for protein electrophoresis. II. Native PAGE - (A) Can only give mass-to-charge ratios, so could have decreased separation of proteins with different masses or charges. This does NOT denature the protein. III. SDS-PAGE - (C) Uses a Detergent to break all noncovalent interactions, including affecting the charges of proteins. They are only separated based on size.

What is the difference between positive-cooperative binding vs negative-cooperative binding?

Positive-cooperative binding is when substrate binding INCREASES the affinity for subsequent substrates. Negative-cooperative binding is when substrate binding DECREASES the affinity for subsequent substrates.

Write the *rate law* for the following reaction: A+B -> AB

Rate= k [A][B] Rate is the change in concentration per unit time. k is the rate constant (depends on environment of the reaction). [A] and [B] are the concentrations of reactants A and B. Rate law very important Note if A and B had any subscripts, they would be presented as exponents in rate law

Competitive, uncompetitive, non-competitive, and mixed inhibitors are examples of?

Reversible inhibitors

Describe enzyme regulation via proteolytic cleavage:

Some enzymes in our body exist in an inactivated form called zymogens and require some kind of cleavage in order to become activated. ALot of digestive enzymes utilize this method

What is an example of an irreversible inhibitor?

Suicide inhibitors that cancels enzymes activity.. and can bind via covalent bonds and non covalent bonds Once suicide inhibitors are bound, the enzyme will never be active again

Describe, or draw, how the Lineweaver-Burke plot will look for a competitive inhibitor compared to the uninhibited enzyme.

The Lineweaver-Burke plot for a competitive inhibitor will have the same y-intercept as the uninhibited enzyme, but a less negative x-intercept. This illustrates that the Km increased, but the Vmax did not change.

Describe, or draw, how the Lineweaver-Burke plot will look for a mixed inhibitor with respect to no inhibitor.

The Lineweaver-Burke plot for a mixed inhibitor will have an increased y-intercept and an increased or decreased x-intercept.

Describe, or draw, how the Lineweaver-Burke plot will look for a non-competitive inhibitor compared to the uninhibited enzyme.

The Lineweaver-Burke plot for a noncompetitive inhibitor will have the same x-intercept, but a higher y-intercept and slope. This indicates that the Km did not change, but the Vmax decreased.

Describe, or draw, how the Lineweaver-Burke plot will look for an uncompetitive inhibitor compared to the uninhibited enzyme..

The Lineweaver-Burke plot for an uncompetitive inhibitor will be parallel to the uninhibited enzyme's plot with a higher y-intercept and a more negative x-intercept. This indicates a decreased Vmax and a decreased Km.

Write out the Michaelis-Menten equation. What do each of the variables mean?

The Michaelis-Menten equation is a very important equation when talking about enzyme kinematics and is shown in the picture. V is the reaction velocity (rate of reaction progression per unit time) *Don't worry about knowing how to derive this equation. Just memorize it and understand each variable.*

What does the enzyme turnover number (Kcat) really mean?

The enzyme turnover number (Kcat) basically tells us how many substrates a single enzyme can turn into product in one second at its maximum speed.

What is the rate of the reaction? Also what is the rate of product formation?

The speed the reaction goes at. Rate of product formation: It is equal to rate of concentration of product/ time Rate of reactant formation would be equal to -d[A]/t where d= delta

During labor, the baby's head is pushed downward and results in increased pressure on the cervix. This contraction stimulates receptor cells which send a chemical signal to the brain, causing an increased release of oxytocin. The release of oxytocin stimulates further contractions. These contractions stimulate further oxytocin release until the baby is born. What kind of feedback loop is this? Positive or Negative?

This feedback loop is an example of a positive feedback loop because oxytocin acts as an activator, amplifying the system to perform more contractions.

Blood pressure must be high enough to pump blood throughout the body, but not high enough to cause damage. While the heart is pumping, baroreceptors detect the pressure of the blood going through arteries. If the pressure is too high, the baroreceptors will send an electrochemical signal to the brain via the glossopharyngeal nerve. The brain then sends a chemical signal to the heart to decrease the pressure. Is this an example of a positive or negative feedback loop?

This is an example of a negative feedback loop because the output (chemical signal to decrease blood pressure) inhibits the input (high blood pressure detected by baroreceptors).

*CRB* True or false? In isoelectric focusing, the proteins are loaded near the Anode, where there is a low pH and the proteins will be protonated and positively charged.

True. In isoelectric focusing, the proteins are loaded near the Anode, where there is a low pH and the proteins will be protonated and positively charged.

*CRB* True or false? Kcat values between enzymes are somewhat constant, with many having between 101 and 103 products per enzyme per second as their Kcat.

True. Kcat values between enzymes are somewhat constant, with many having between 101 and 103 products per enzyme per second as their Kcat.

True or False? If you wanted to compare which enzymes are better at speeding up reactions, you could compare the catalytic efficiency of the enzymes.

True. You can rate enzymes by calculating their catalytic efficiency, which is (Kcat/Km); the higher the catalytic efficiency, the better the enzyme is at speeding up reactions for that specific substrate.

How does the michealis- menten curve look with a uncompetitive inhibitor? And explain

Vmax decreases because the amount of enzymes turning stuff into product is decreased (less active enzymes) Km (affinity of substrate to active site)- when inhibitor binds it prevetns the already bound substrate from leaving the active site increasing the affinity of the substrate fro the active site of the enzyme which in turn decreases Km value. Another way to look at it is since Vmax decreases, we need to bind a lower amount of substrate so that we reach half of the enzymes max velocity

How does the michealis- menten curve look with a non- competitive inhibitor? And explain

Vmax lowered because the number of active enzymes decrease Km remains constant because even though inhibitor may bind to allosteric site changing the shape of the active site (which changes efficiency of the enzyme) it does not change likelihood that a substrate will still bind to active site

How does the michealis- menten curve look with a competitive inhibitor? ANd explain

Vmax wont change because eventually all inhibitors will be replaced with substrate. Km changes because the competitive inhibitor is pretty much fighting for a spot against the substrate so the affinity of the active site for substrate decreases a bit Km change essentially means we need more substrate to make enzyme reach half its velocity capacity

Based on Arrhenius equation, how is the rate of reaction increased? *insert image here*

When enzymes do their job of lowering the activation energy, that makes the rate constant larger which then makes the rate of the reaction faster. When it comes to the frequency factor (A), enzymes bring substrates together real close in a microrenvironment which increases the frequency of collisions so A can also increase which increases the rate constant.

For the Lineweaver-Burke plot, what is the formula for the y intercept, and x intercept?

Y intercept: 1/Vmax X intercept: -1/Km

Does Kcat change with non-competitive inhibition?

Yes it is lowered because once enzyme binds to inhibitor, the inhibitor changes the shape of the active site so that active site is no longer complementary to a particular substrate and once substrate binds to Enzyme Inhibitor complex that fit will not be perfect so the ability for active site to transform into that product will not be as high

What is a zeroth vs first order vs second order reaction?

Zeroth: Where changing concentration of reactants does not affect rate of reaction at all First order is where the rate is directly proportional to the concentration of the reactant-- SO doubling the reactant doubles the rate of reaction Second order is where e for example you would double the reactant and the rate of reaction will quadruple...etc. For example for a reaction with A+ B-->C , doubling both will quadruple the rate of rxn or a reaction with 2A---> B, doubling it will quadruple rate of reaction. Note for A+ B-->C

What is glycosylation?

adding a carbohydrate to a protein

What type of inhibitor does not change the Vmax value? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(A) Competitive Competitive inhibitor does not change the Vmax value because if enough substrates are added, it will outcompete the inhibitor and be able to run the reaction at maximum velocity.

Which type of inhibitor will increase Km without affecting the Vmax? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(A) Competitive Competitive inhibitors will increase Km (decrease affinity for the substrate), but leave Vmax unchanged because if enough substrate is added, it will outcompete the inhibitor and the reaction will still run at maximum velocity.

Increasing the substrate concentration will only be able to overcome the inhibitory effects of what kind of inhibitor? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(A) Competitive Increasing the substrate concentration will only be able to overcome the inhibitory effects of competitive inhibitors.

A patient is rushed into the ER due to methanol poisoning, in which methanol is enzymatically converted to toxic metabolites. The doctor treats the patient by administering intravenous ethanol to compete for the active sites of the enzymes involved to prevent the production of toxic metabolites. What type of inhibitor is this? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(A) Competitive We should know this is a competitive inhibitor because the inhibitor works by binding to the *active site* of the enzyme.

During glycolysis, phosphofructokinase catalyzes the conversion of fructose-6-phosphate to fructose-1,6-bisphosphate using ATP as one of its other substrates. However, high levels of ATP inhibit phosphofructokinase. In this scenario, ATP is acting as a: (A) Homotropic inhibitor (B) Homotropic activatoror (C) Heterotropic inhibitor (D) Heterotropic activator

(A) Homotropic inhibitor ATP is acting as a homotropic inhibitor because it acts as a substrate for the enzyme and as an inhibitor. Also, because the goal of glycolysis is to produce ATP, this can also be considered a negative feedback loop (output ATP reduces the input of phosphorylating fructose to start glycolysis).

The catalytic efficiency (specificity constant) for a certain reaction increases. What happens to the reaction rate? (A) It would increase (B) It would remain the same (C) It would decrease (D) It would stop

(A) It would increase Catalytic efficiency is basically an enzyme's ability to catalyze reactions. If it increases so too will the rate of the reaction.

What is enzyme cooperativity? (A) Substrate binding that changes substrate affinity (B) Substrate affinity that changes substrate binding (C) Enzyme binding that changes product affinity (D) Product binding that changes Enzyme affinity

(A) Substrate binding that changes substrate affinity Enzyme cooperativity is substrate binding that changes substrate affinity.

What is the steady-state assumption when talking about enzyme kinetics? (A) [ES] is constant (B) [S] is constant (C) [P] is constant (D) [I] is constant

(A) [ES] is constant The steady state assumption means that the concentration of the enzyme-substrate complex (ES) is constant, which means that the rate of formation of ES is equal to the rate of dissociation of ES. k1 [E][S] = K2 [ES] + K-1 [ES] This means that products can form just as much as the complex can dissociate.

Hemoglobin is written as Hb(O2)4. What type of cooperativity does hemoglobin have, and how does this affect oxygen binding? (A) positive-cooperative binding (B) negative-cooperative binding (C) neutral-cooperative binding (D) non-cooperative binding

(A) positive-cooperative binding Hemoglobin exhibits positive cooperative binding. This means that after the first oxygen molecule binds, a second molecule of oxygen is more likely to bind because the affinity for that substrate increased. This affinity will continue increasing as more oxygen binds until the hemoglobin is saturated. Because of this, hemoglobin has a higher affinity for oxygen at higher partial pressures of oxygen.

*CRB* Which of the following is NOT going to affect all enzymes if it is drastically altered from physiological norms? (A) Salinity (B) Allosteric Inhibitor Concentrations (C) Temperature (D) pH

(B) Allosteric Inhibitor Concentrations Allosteric Inhibitors do not affect all enzymes, only ones with allosteric sites compatible with that specific inhibitor. Salinity, Temperature and pH could affect all enzymes if they are drastically altered.

How can we increase the rate of a reaction assuming the rate constant (k) is constant? I. Increase Substrate Concentration II. Increase Enzyme Concentration III. Increase Mixed Inhibitor Concentration (A) I Only (B) I and II Only (C) II and III Only (D) I, II, and III

(B) I and II Only We can increase the rate of reaction by increasing the substrate or enzyme concentration. Adding any type of inhibitor will not increase the rate of a reaction.

*CRB* Which of the following descriptions of Isoelectric Focusing are true? I. The gel that the samples are separated in has a pH gradient, ranging from acidic to basic. II. The protein will settle at the pH where the protein's R-groups are fully deprotonated. III. As proteins move towards the Cathode, the pH increases. (A) I only (B) I and III only (C) II and III only (D) I, II and III

(B) I and III only Each of the following statements are true about Isoelectric Focusing: I. The gel that the samples are separated in has a pH gradient, ranging from acidic to basic. II. The protein will settle at the pH equal to the protein's pI. III. As proteins move towards the Cathode, the pH increases.

The enzyme pepsin is unable to break down proteins into smaller peptides thus causing a digestion problem in the stomach. What can we do to increase pepsin's catalytic efficiency? I. Increase Km II. Increase Kcat III. Increase Vo (A) I Only (B) II Only (C) I and II Only (D) I, II, and III

(B) II Only To increase catalytic efficiency, we need to increase the enzyme turnover number (Kcat) or DECREASE the Michaelis constant (Km).

In Michaelis-Menten Kinetics experiments, which of the following is assumed to be true? I. Substrate concentration is constant. II. Increasing the Enzyme concentration will not change Vmax. III. The enzymes are saturated at Vmax. (A) I Only (B) III Only (C) I and II Only (D) I, II, and III

(B) III Only In Michaelis-Menten Kinetics experiments: - ENZYME concentration is held constant as we increase the substrate concentration. - If you were to increase the enzyme concentration, the Vmax would increase. - The enzymes are saturated at Vmax.

What is the one way to increase the Vmax of a reaction? (A) Increase Substrate Concentration (B) Increase Enzyme Concentration (C) Increase Inhibitor Concentration (D) Increase Product Concentration

(B) Increase Enzyme Concentration The only way to increase Vmax is by increasing the enzyme concentration.

If a reaction has reached Vmax, what would happen to the rate of reaction if we increase the substrate concentration? (A) It would increase (B) It would remain the same (C) It would decrease (D) It would stop

(B) It would remain the same Increasing the substrate concentration would have no effect on the rate of the reaction because all active sites are already occupied at Vmax.

*CRB* Which of the following is NOT typically and easily identified using Lineweaver-Burke Plots? (A) Km (B) Kcat (C) Vmax (D) The type of inhibition and enzyme faces.

(B) Kcat Lineweaver-Burke Plots are often used to identify Km, Vmax and the type of inhibition an enzyme is facing.

*CRB* The Bradford Protein Assay is one of the most common and simplest Protein Assays. Which of the following is NOT a true statement about Bradford Protein Assays? (A) It mixes dissolved proteins with a green-brown dye that will turn blue. (B) The dye accepts electrons from the amino acid groups, triggering that color change. (C) Ionic interactions stabilize the blue form of this dye, and then Spectrophotometry can be used. (D) Samples must be compared to an appropriate Standard Curve to determine the concentration of the protein.

(B) The dye accepts electrons from the amino acid groups, triggering that color change. The Dye actually Donates protons to the Amino Acids. Also note that Bradford Protein Assays are sensitive to having multiple proteins mixed in one sample and to having too dilute a sample or detergent in the sample.

Which type of inhibitor will decrease both Km and Vmax? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(B) Uncompetitive Uncompetitive inhibitors will apparently decrease Km (increase substrate affinity). This is because binding to ES will shift the reaction (E + S --> ES) to the right (the forward direction). These inhibitors will also decrease Vmax because they bind to the enzyme-substrate complex, preventing these bound enzymes from completing any further reactions. This essentially decreases the concentration of active E, decreasing Vmax. (Note: remeber that vMax increases with increased enzyme concentration)

A single reaction in a pathway would be a great control point for regulation if it has a very: (A) positive ΔG. (B) negative ΔG. (C) positive ΔS. (D) negative ΔS.

(B) negative ΔG. A reaction with a negative ΔG would be a great "committing" step for a pathway because that reaction is unlikely to be reversed. That reaction's products would then be committed to moving forward in the pathway. Phosphofructokinase's reaction has a very negative ΔG; thus, it is a great control point for glycolysis.

*CRB* One of the ways that Proteins are analyzed are through Amino Acid Composition. Which of the following is a sequential digestion technique that can sequence 50-70 amino acids from the N-terminus? (A) NMR (B) Bradford Assay (C) Edman Degradation (D) Lowry Reagent Assay

(C) Edman Degradation Edman Degradation is a sequential digestion technique that can sequence 50-70 amino acids from the N-terminus, giving us knowledge about a protein's Primary Structure.

In Michaelis-Menten Kinetics experiments, which of the following is assumed to be true? I. Our Solutions are behaving ideally. II. Our constants ([E] and k) are not changing during the experiment. III. Substrate can be converted into product with or without the enzyme when discussing enzyme kinetics (A) I Only (B) III Only (C) I and II Only (D) I, II, and III

(C) I and II Only In Michaelis-Menten Kinetics experiments, we assume that: - Our Solutions are behaving ideally, and we can classify the enzymes reaction in two distinct steps. First being the binding of enzymes an substrates (k[E][S]) and second is the transition from substrate to product with the enzymes help. - Our constants ([E] and k) are not changing during the experiment. [E] can be influenced by protein synthesis/degradation and k can be influenced by environmental factors but we are assuming that in this case, neither of these variables are being affected - Substrate CANNOT be converted into product without the enzyme for reactions needing enzymes

When talking about cooperativity, what can we infer about the enzyme? I. The enzyme has multiple binding sites II. The enzyme can bind to more than one substrate III. The enzyme is immune to inhibitors (A) I Only (B) II Only (C) I and II Only (D) II and III Only

(C) I and II Only When talking about cooperativity we can infer that the enzyme has multiple binding sites and can bind to more than one substrate.

Which type of inhibitor will decrease Vmax but does not apparently alter the value of Km? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(C) Noncompetitive A noncompetitive Inhibitor will decrease Vmax and not alter the value Km. A noncompetitive inhibitor decreases Vmax because it binds to enzyme and the enzyme-substrate complex, thus creating less available enzymes to react. The inhibitor binds ES, shifting the reaction (E + S --> ES) to the right. The inhibitor also binds to E, shifting the reaction to the left. These shifts cancel each other out, resulting in no change to affinity (Km). *Note that this is NOT what Khan Academy says. Their description is incorrect!*

What type of inhibitor does not change the apparent Km value? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(C) Noncompetitive A noncompetitive inhibitor does not change the apparent Km value because the inhibitor binds equally well to the enzyme and enzyme-substrate complex.

What is the Michaelis constant (Km)? (A) The Vo at half of Vmax (B) The Vmax at half of Vo (C) The [S] at half of Vmax (D) The Vmax at half of [S]

(C) The [S] at half of Vmax The Michaelis constant (Km) is the substrate concentration where the initial velocity (Vo) is equal to 1/2 of Vmax. It has an inverse relationship with affinity of enzyme for substrate. The larger the km, the lower the affinity

*CRB* There are a variety of ways to separate proteins based on their different characteristics. Which of the following would you NOT expect to be used to separate proteins? (A) Electrophoresis (B) Isoelectric Focusing (C) X-ray Crystallography (D) Chromatography

(C) X-ray Crystallography X-ray Crystallography could be used once a protein has been purified to learn about its structure. Electrophoresis, Isoelectric Focusing and Chromatography are all techniques used to separate proteins. (Note that there is a whole lesson on Chromatography in Chemistry II, so we will not discuss it further here).

*CRB* Fill in the blanks: Cooperativity is often compared using Hill's Coefficient. If Hill's coefficient is ________, then positive cooperative binding is occurring, and if Hill's coefficient is _________, then negative cooperative binding is occurring. (A) > 0 , < 0 (B) < 0 , > 0 (C) < 1 , > 1 (D) > 1 , < 1

(D) > 1 , < 1 Cooperativity is often compared using Hill's Coefficient. If Hill's coefficient is > 1, then positive cooperative binding is occurring, and if Hill's coefficient is < 1, then negative cooperative binding is occurring. If Hill coefficient is equal to 1 then there is no cooperativity

During glycolysis, phosphofructokinase catalyzes the conversion of fructose to fructose-6-bisphosphate using ATP as one of its other substrates. High levels of AMP enhance the activity of phosphofructokinase. In this scenario, AMP is acting as a: (A) Homotropic inhibitor (B) Homotropic activator (C) Heterotropic inhibitor (D) Heterotropic activator

(D) Heterotropic activator AMP is acting as a heterotropic activator, because it does not act as a substrate for the enzyme that it activates.

*CRB* Which of the following statements about Positive Cooperativity are true? I. Substrate binding to one binding site will encourage other binding sites to transition from the T state to the R state. II. When substrates dissociate, the newly-empty binding site will almost instantaneously bind to another substrate to maintain that R-state. III. When substrates dissociate, all subunits are more likely to transition from R state to the T state, promoting further dissociation. (A) I only (B) II only (C) I and II only (D) I and III only

(D) I and III only Each of the following about Positive Cooperativity are true: I. Substrate binding to one binding site will encourage other binding sites to transition from the T state to the R state. III. When substrates dissociate, all subunits are more likely to transition from R state to the T state, promoting further dissociation.

*CRB* Drastically increasing which of the following could lead to denaturing an enzyme, decreasing its rate of reaction? I. Temperature II. pH III. Salinity (A) I only (B) I and II only (C) II and III only (D) I, II and III

(D) I, II and III Drastically increasing any of temperature, pH or Salinity could lead to enzyme denaturation.

An inhibitor binds to a free enzyme preventing it from being able to react with the substrate. That same inhibitor is also able to bind to the enzyme-substrate complex, preventing the enzyme from turning the substrate into product. What type of inhibitor could this be? I. Uncompetitive II. Noncompetitive III. Mixed (A) I Only (B) II Only (C) I and II Only (D) II and III Only

(D) II and III Only This can be either a non-competitive inhibitor or mixed inhibitor because it can bind to either the enzyme or the enzyme-substrate complex. Uncompetitive inhibitors only bind to the ES complex.

*CRB* How could dramatically increasing the Salinity of an solution with enzymes denature the enzyme? (A) It could disrupt the Primary Structure by breaking only covalent bonds. (B) It could disrupt Secondary Structure by disrupting only Hydrogen Bonds. (C) It could disrupt Tertiary and Quaternary Structure by disrupting only Ionic Bonds. (D) It could disrupt Secondary, Tertiary and Quaternary Structure by disrupting both Hydrogen and Ionic Bonds.

(D) Increased Salinity could disrupt Secondary, Tertiary and Quaternary Structure by disrupting both Hydrogen and Ionic Bonds.

Which type of inhibitor decreases Vmax and can either increase or decrease Km? (A) Competitive (B) Uncompetitive (C) Noncompetitive (D) Mixed

(D) Mixed A mixed inhibitor always decreases Vmax; but can either apparently increase or decrease Km (decrease or increase affinity for substrate) since a mixed inhibitor has different affinities for the enzyme and enzyme-substrate complex. If a mixed inhibitor prefers binding to the enzyme, the Km will increase. If mixed inhibitor prefers binding to the enzyme-substrate complex, the Km will decrease.

*CRB* Fill in the blanks: Binding Sites can exist in either the low-affinity ____________ state or the high-affinity _____________ state. (A) R, S (B) S, T (C) T, S (D) T, R

(D) T, R Binding Sites can exist in either the low-affinity T (tense) state or the high-affinity R (relaxed) state.

What does it mean if the rate of reaction has reached maximum velocity (Vmax)? (A) There are more products than reactants. (B) The substrates are no longer able to get any closer to the enzymes. (C) The substrates are no longer able to get in any better of an orientation. (D) The enzymes no longer have available active sites.

(D) The enzymes no longer have available active sites. When the rate of reaction reaches Vmax, it means that the enzymes are saturated and will not be able to react any more quickly since all active sites are filled up with substrates.

Myoglobin is written as Mb(O2). What type of cooperativity does myoglobin have and why? (A) positive-cooperative binding (B) negative-cooperative binding (C) neutral-cooperative binding (D) non-cooperative binding

(D) non-cooperative binding Myoglobin exhibits non-cooperative binding because it can only bind one molecule of oxygen. In other words, there is no affinity for oxygen after the first molecule binds because there is no way to bind more!

Substrate binding that does not affect the affinity for subsequent substrates is known as: (A) positive-cooperative binding. (B) negative-cooperative binding. (C) neutral-cooperative binding. (D) non-cooperative binding.

(D) non-cooperative binding. It is called non-cooperative binding since the substrate binding does not affect the affinity for subsequent substrates.

*Does Kcat change with uncompetitive inhibition?

*No it does not change because when the inhibitor is not bound to the enzyme the rate at which it forms products is the same

Example: For the reaction 2A + 3B → 4C + 5D, the rate of the reaction in terms of ΔA would be written as:

-1/2 ΔA/Δt. But note that finding rates of products formed and reactants consumed is not very useful and we ant to determine rate of entire equation as a whole and that is where we use rate law

What is a homotropic inhibitor/activator versus a heterotropic inhibitor/activator?

A homotropic inhibitor/activator is a molecule that acts as both a substrate and an inhibitor/activator. A heterotropic inhibitor/activator is strictly a regulating molecule and not an active site substrate.

What is a psuedofirst order reaction?

A second order reaction that behaves like a first order reaction. Ex. in A+ B-->C if there was lots of B then changes in concentration wouldn't really affect rate of reaction acting as a zeroth order... but if there was little concentration of A, the reaction rate would increase if A increases acting as a first order

Compare the two types of enzyme regulators -- allosteric activators vs. inhibitors. How does each affect Km and Vmax?

Allosteric activators increase enzyme activity. They increase Vmax and decrease Km. Allosteric inhibitors decrease enzyme activity. They decrease Vmax and increase Km.

Compare allosteric site vs. active site?

Allosteric sites are sites on the enzyme other than the active site to which a regulator can bind. (inhibitors or activators) The active site is where the substrate binds.

On a Michaelis-Menten plot please draw what the curves would look like for enzymes with non-cooperative binding, positive-cooperative binding, and negative-cooperative binding.

An enzyme with non-cooperative binding will have a hyperbolic shaped curve. An enzyme with positive-cooperative binding will have a sigmoidal "S" shaped curve. An enzyme with negative-cooperative binding will have an altered hyperbolic shape with a steeper initial curve than non-cooperative binding. And the " vmax " will possibly be lower

What is the difference/similarity between a positive feedback loop versus a negative feedback loop?

Both a positive feedback loop and a negative feedback loop consist of a downstream product that regulates upstream reactions. The difference is that the output/product of positive feedback loop acts as an activator and amplifies the system, whereas the output/product of a negative feedback loop inhibits the system.

What is the formula for catalytic efficiency?

Catalytic Efficiency = Kcat/Km.

Catalytic efficiency is depedent on both Kcat and Km, so describe how both affect catalytic efficiency

Catalytic efficiency= Kcat/Km This increasing Kcat and decreasing Km increases the enzymes catalytic efficiency