Enzymes

Question 1

Pretein catalysts that increase the velocity of chemical reactions and are NOT consumed in the reaction they catalyze

Answer 1

Ezymes

Question 2

_______ are physically distinct forms of given enzyme, each of which catalyze the same reaction

Answer 2

Isoenzymes

Question 3

Class of ezyme and example. Catalyze oxidation and reductions

Answer 3

Oxidoreductases

Eg lactate dhydrogenase

Question 4

Class of enzyme and example, catalyze transfer of moieties such as glucosyl, methyl, phosphoryl groups

Answer 4

Transferases

Eg methyl transferase

Question 5

Class of eznyme and example. Catalyze cleavage of C-C and C-O C-N and other bonds in the presence of water

Answer 5

Hydrolase

Eg urease

Question 6

Class of enzyme and example

Catalyze cleavage of C-O, CC, CN and other bonds by atom elimination, leaving double bonds

Answer 6

Lyases

Eg decarboxylase

Question 7

Class of ezyme and example

Catalyze geometric of stuctural changes within a molecule

Answer 7

Isomerases

Eg …mutas

Question 8

Class of enzyme and example

Catalyze joining together of 2 molecules coupled to the hydrolysis of ATP

Answer 8

Ligases

Eg carboxylases

Question 9

Enzymes contain active site for substrate held together by ______ bonds

Answer 9

Hydrogen

Question 10

T/F

Enzymes are highly specific and highly efficient

Answer 10

T

Question 11

Enzymes require _____, which bind in transient dissociable manner to either enzyme or substrate

Answer 11

Cofactor

Question 12

______ are substances that serve as recyclable shuttles or griupntransfer agents that transport many substrates from their point of generation to their point of utilization

Answer 12

Co-enzyme

Question 13

______ are distinguished by their tight stable incorporation into a protein stucture by covalent or noncovalent forces

Answer 13

Prosthetic groups

Question 14

_____ are non protein component of enzymes

Answer 14

Co factors

Question 15

Co-factor vs effector

Required for function

Answer 15

Co factor

Question 16

Co factor vs effector
Are not proteins like enzymes
Examples are Fe in Hgb, Cu in cytochrome oxidase

Answer 16

Co factor

Question 17

Co factor vs Effector

Negative______ will decrease rate of reaction

Answer 17

Effector

Question 18

Cofator vs effector

Positive ______ will increase rate of reaction

Answer 18

Effector

Question 19

Cofactor vs effector

Coezymes are organcic ______ like vitamins

Answer 19

Co factor

Question 20

Enzymes (increase/decrease) free energy of activation

Answer 20

Decrease

Question 21

Enymes (inc/dec/dont affect) the energy of the rectants and products, and the equilibrium ofnthe reaction

Answer 21

Dont affect

Question 22

Components of conjugated protein:

1. Protein part
2. Non-protein part

Answer 22

1. Apoenzyme

2. Co factor

Question 23

Michaelis Menten Equation describes how reaction velocity varies with _______ concentratiom

Answer 23

Substrate

Question 24

3 assumptions of Michaelis Menten Equation

Answer 24

[S] is much greater than [ E]
[ES] is contant
[P] is low

Question 25

Enzymes that follow Michaelis Menten kinetics have a (hyperbolic/sugmoidal/bell) curve

Answer 25

Hyperbolic

Question 26

Vmax is

Answer 26

Maximal velocity

Question 27

Maximal number of substrate molecules converted into product per unit time

Answer 27

Vmax

Maximal Velocity

Question 28

The substrate concentration at which Vi (initial velocity) is half the maximal velocity (Vmax/2) attainable at a particular concentration of enzyme

Answer 28

Km (Michaelis Constant)

Question 29

3 factors that affect rate of reaction

Answer 29

Substrate concentration, Temperature, pH

Question 30

Reciprocal of Michaelis -Menten equation

Answer 30

Lineweaver-Burk Plot

Question 31

Used to calculate Km and Vmax as well as to determine the mechanism of action of enzyme inhibitors

Answer 31

Lineweaver-Burk Plot

Question 32

Anysubstnace that can diminish the velocity if an enzyme catalyzed reaction

Answer 32

Enzyme inhibitor

Question 33

Competititive/Noncompetitive inhibition

Inhibitor is shaped like substrate and competes for binding site

Answer 33

Competitive

Question 34

Competitive/Noncompetitive

Reversed by increasing substrate concentration

Answer 34

Competitive

Question 35

Competitive/noncompetitive

Km is not changed

Answer 35

Non competitive

Question 36

Competitive/noncompetitive

Reversed by increasing enzyme concentration

Answer 36

Noncompetitive

Question 37

Competitive/noncompetitive

Vmax is not changed

Answer 37

Competitive

Question 38

Competitive/Non-competitive

Km is increased

Answer 38

Competitive

Question 39

Competitive/Noncompetitive

Vmax is lowered

Answer 39

Noncompetitive

Question 40

Competitive/Noncompetitive

Inhibitor binds to enzymes somewhere pther than the active site and halts catalysis

Answer 40

Noncompetitive

Question 41

Competitive/noncompetitive

Changes shape of enzyme so it cannot bind to substrate

Answer 41

Noncompetitive

Question 42

T/F on enzyme regulation
The rates of most enzymes are responsive to changes in substrate comcentration, because the extracellular levels of many substrates is in the range of Km

Answer 42

F. Intracellular

Question 43

T/F on enzyme regulation

Heterotropic effectors: the substrate itself serves as an effector

Answer 43

F. Homotropic

Question 44

T/F on enzyme synthesis

Enzymes are often those that are needed only at one stage of development or under selected physiologic conditons

Answer 44

T

Question 45

Identify enzyme

Myocardial infaractiom

Answer 45

AST/ SGOT

Question 46

Identify enzyme

Viral hepatitis

Answer 46

ALT/SGPT

Question 47

Identify enzyme

Acute pancreatitis

Answer 47

Amylase

Lipase

Question 48

Identify enzyme

Hepatocellular degeneration as in Wilsons dse

Answer 48

Ceruloplasmin

Question 49

Identify enzyme

Muscle disorders and MI

Answer 49

Creatine kinase

Question 50

Identify enzyme

Gauchers dse

Answer 50

B-glucocerebrosidase

Question 51

Identify enzyme

Bone diseases and obstructive liver dse

Answer 51

Alkaline phosphatase

Question 52

Term that denotes transfer and utilization if energy in biologic systems

Answer 52

Bioenergetics

Question 53

Measures the change in heat content of the reactants and products

Answer 53

Change in enthalpy (delta H)

Question 54

Unit of measurement for enthalpy

Answer 54

Joules

Question 55

Measures change of disorder of reactants and products

Answer 55

Change in entropy (delta S)

Question 56

Unit of measurement for entropy

Answer 56

Joules per Kelvin

Question 57

Energy available to do work

Answer 57

Change in free energy (delta G)

Question 58

Predicts the direction in which a reaction will spontaneously proceed

Answer 58

Change in free energy (delta G)

Question 59

Change in free energy apporaches this value as the reaction proceeds to equilibrium

Answer 59

Zero

Question 60

Formula for change in free energy

Answer 60

DeltG= delta H - T delta S

Question 61

Is the reaction spontaneous?

Delta G < O

Answer 61

Yes

Question 62

Is the reaction spomtaneous?

Delta G = 0

Answer 62

Forward and backward rxns are equal

Question 63

Is the rxn spontaneous?

Delta G > 0

Answer 63

No, Endergonic, net gain of energy

Question 64

Is the rxn spontaneous?

Exergonic rxn

Answer 64

Yes (G<0) net loss of energy

Question 65

T/F

Endergonic processes proceed by coupling to exergonic processes

Answer 65

Coupling reactions

Question 66

This molecule acts as energy currency of the cell, transferring free energy derived feom substances of higher energy to those of lower energy potential

Answer 66

ATP

Question 67

Substrate level/Oxidative phosphorylation

Done through coupling reactions where a phosphate group is transferred to ADP from another substance with higher delta G

Answer 67

Substrate level phosphorylation

Question 68

Pathway wherein there is net formation of twoo high energy phosphates resulting from the formation of lactate from one molecule of glucose

Answer 68

Glycolysis

Question 69

Two pathways that compose substrate level phosphorularylation

Answer 69

Glycolysis

Citric acid cycle

Question 70

Pathway wherein high energy phosphate is generated directly at the succinyl thiokinase step

Answer 70

Citric acid cycle

Question 71

Pathway, greatest quantitative siurce of high energy phosphate in aerobic organism

Answer 71

Oxidative phosphorylation

Question 72

Site of oxidative phosphosrylation

Answer 72

Mitochondria

Question 73

Final substance to be reduced in oxidative phosphotylation

Answer 73

O2

Question 74

Part of mitochondria

Freely permeable to most molecules

Answer 74

Outer membranes

Question 75

Part of mitochondria

Impermeable to most substances

Answer 75

Inner membrane

Question 76

Part of mitochondria

Increases surface area

Answer 76

Cristae

Question 77

Part of mitochondria

Contains enzymes, mtDNA, mtRNA, mitochondrial ribosomes

Answer 77

Matrix

Question 78

Final common pathway by which electrons from differents fuels of the body flow to oxygen

Answer 78

ETC

Question 79

Location of ETC

Answer 79

Inner mitochondrial membrane

Question 80

Two electron carriers used in ETC

Answer 80

NAD+, FAD

Question 81

NAD+, FAD undergo ________ to form NADH and FADH2

Answer 81

Reduction

Question 82

Vitamins from which these are derived:
1 )NADH
2)FADH2

Answer 82

1. B3 (niacin)

2. B2 (riboflavin)

Question 83

The only 2 components of ETC not attached to inner mitochondrial membrane

Answer 83

Coenzyme Q, cytrochrome C

Question 84

The only non protein compoenent of ETC

Answer 84

Ubiquinone (CoQ)

Question 85

In ETC, protons are pumped to the intermembranous space in what complexes

Answer 85

I, III, IV

Question 86

In ETC, final electron acceptor is

Answer 86

O2

Question 87

This hypothesis explains how the free energy generated by the transport of electrons by ETC is used to produced ATP

Answer 87

Mitchell/Chemiosmotic hypothesis

Question 88

T/F in ETC, the intramembranous space becomes more positive and has more H+

Answer 88

T

Question 89

In ETC, protons reenter the mitochondrial matrix through what complex

Answer 89

ATP synthase complex (Complex V)

-this is the oxidative phosphorylation part

Question 90

T/F when there is lack of O2, there is decreased actovitynof ETC. ATP production shifts from oxidative phosphorylation to substrate level phosphorylation

Answer 90

T

Question 91

Substrate level phosphorylation does not require oxygen but anaerobic glycolysis is not enough for highly aerobic tissues like _____ and _____

Answer 91

Neuron

Cardiac muscle

Question 92

Effects of ETC inhibitor (increase/decrease)

O2 consumption

Answer 92

Decrease

Question 93

Effects of ETC inhibitor (increase/decrease)

Intracelluar NADH/NAD+ and FADH2/FAD ratio

Answer 93

Increase,

NADH and FADH2 accumulate bcos they cannot transfer electrons to the ETC

Question 94

Effects of ETC inhibitor (increase/decrease)

ATP

Answer 94

Decrease

Question 95

Identify 4 inhibitors
Complex I (NADH dehydrogenase)

Answer 95

Barbiturates
Piericidin A
Amytal
Rotenon

Question 96

Identify 3 inhibitors
Complex II (Succinate-CoQ reductase)

Answer 96

Malonate
Carboxin
TTFA

Question 97

Indentify 2 inhibitors
Complex III (CoQ-Cytochrome c reductase)

Answer 97

Antimycin A

Dimercaprol

Question 98

Identify 4 inhibitors
Complex IV (cytochrome oxidase)

Answer 98

Cyanide
Carbon monoxide
Sodium azide
Hydrogen sulfide

Question 99

Compounds that increase permeability of inner mitochondiral membrane to protons

Answer 99

Uncouplers

Question 100

In the presence of uncouplers, electron transport proceeds at (rapid/slow) rate without establishing a proton gradient

Answer 100

Rapid

Question 101

Effect of uncouplers ETC

Oxygen consumption

Answer 101

Increase

Question 102

Effect of ETC uncoupler

NADH/NAD+ and FADH2/FAD ratio

Answer 102

Decrease

“Uncouplers are FADulous”

Question 103

Effect of ETC uncoupler

ATP synthesis

Answer 103

Decrease

Question 104

2 examples of synthetic ETC uncoupler

Answer 104

2,4 dintrophenol

Aspirin

Question 105

Uncoupling ETC protein

Answer 105

Thermogenin (brown fats)

Nenonates depend on this for heat production, prevention of hypothermia

Question 106

Symptom if aspirin overdose caused by its ETC uncoupling property

Answer 106

Hyperpyrexia

Question 107

Example of ATP synthase (complex V) inhibitor)

Answer 107

Oligomycin

Question 108

T/F
In the presence of ATP synthase inhibitor, proton gradient continuous to rise but there is ni excape valve for the protons. ETC eventually stops sicne cytochromes can no longer pump protons into the intermembranous space

Answer 108

T

Question 109

Substance that inhibits oxidative phosphorylationby inhibiting the transporter of ADP into and ATP out of the mitochondrion

Answer 109

Atractyloside

Question 110

Unstable products produced as byproduct of ETC when molecular O2 is partially reduced

Answer 110

Reactive Oxygen Species:
Superoxide (O2-)
Hydrogen peroxide H2O2
Hydroxyl radical (OH-)

Question 111

Increased during reperfusion injury, reacts with lipids to cause peroxidation to cause disruption of cell membranes, denatures & precipitates proteins and other substrates

Answer 111

Reactive Oxygen Species

Question 112

Indentify enzyme

Hydrogen peroxide —> water and O2

Answer 112

Catalase

Question 113

Identify enzyme

H2O2 + AH2 —> 2H2O + A

Answer 113

Peroxidase

Question 114

Identify enzyme

O2- + O2- +2H —> H2O2 + O2

Answer 114

Superoxide dismutase

Question 115

T/F mitchondrial diseases follow Mendelian genetics

Answer 115

F. Non-Mendelian

Question 116

Mitochondrial disease. Encephalomyopathy
Short stature
Stoke-like episodes
Migrainous headaches
Vomiting
Seizures
Lactic acidosis

Answer 116

MELAS - Mitochondrial Encephalomyelopathy, Lactic Acidosis, and Stroke-like episodes

Question 117

Point mutations in mitochondrial DNA result to loss of retinal ganglion cell, leading to optic neuropathy and bilateral central vision loss

Answer 117

LHON ( Leber Hereditary Optic Neuropathy)

Question 118

______ is the sum of all chamical reactions in a cell, tissue or whole body

Answer 118

Metabolism

Question 119

Synthesis of compounds from smaller raw materials

Answer 119

Anabolism

Question 120

T/F Anabolic pathways are exergonic and divergent processes

Answer 120

F, Endergonic

Question 121

T/F Catabolic rxns are usually reductive

Answer 121

F, oxidative

Question 122

Example of amphibolic reaction

Answer 122

Citric acid cycle (links anabolic and catabolic pathways)