Ford Review

Question 1

What are the four types of noncovalent interactions?

Answer 1

charge-charge
dipole interactions
van der waals
hydrogen

Question 2

Example of charge-charge interaction

Answer 2

salt bridges

Question 3

Example of dipole interaction

Answer 3

selectivity filter of K+ channgel

Question 4

Example of van Der Waals interactions

Answer 4

nucleotide stacking

Question 5

Example of hydrogen interactions

Answer 5

nuclei acid and base pairing/protein secondary structure

Question 6

If pH< pKa what does that mean?

Answer 6

protonated

Question 7

If pH> pKa what does that mean

Answer 7

deprotonated

Question 8

If pH=pKa what does that mean?

Answer 8

just as likely to be protonated as deprotonated

Question 9

what is the equation for pKa?

Answer 9

pKa= -logKa = [H+] [A-] / [HA]

Question 10

What does Ka mean?

Answer 10

dissociation constant, predicts how likely an acid will donate a proton

Question 11

What is the Henderson-Hasselbalch equation?

Answer 11

pH= pKa + log [A-] / [HA]

Question 12

What happens when something is reduced?

Answer 12

gains electrons (H)

Question 13

What happens when something is oxidized?

Answer 13

loses electrons

Question 14

What amino acid preforms redox?

Answer 14

cystein (disulfide linkages are reductions)

Question 15

What are the 3 important electron carriers in cellular metabolism and their reduced and oxidized forms?

Answer 15

NAD+/NADH
FAD/FADH2
FMN/FMNH2

Question 16

What is equilibrium?

Answer 16

forward rate = reverse rate, no net formation or destruction

Question 17

How does Le Chatlier fit into cellular metabolism?

Answer 17

it’s how to drive an unfavorable reaction forward

• make pathway/use up products
• couple it to a favorable reaction like ATP hydrolysis

Question 18

What is the gibs free energy equation?

Answer 18

deltaG= deltaH- TdeltaS

Question 19

how does thermodynamics relate to protein folding?

Answer 19

change of entropy–protein folds, loses entropy

aqueous environment has more disorder

Question 20

negative delta H

Answer 20

energy released

Question 21

postive delta H

Answer 21

energy added

Question 22

zero delta H

Answer 22

closed system

Question 23

negative delta S

Answer 23

decrease disorder

Question 24

positive delta S

Answer 24

increase disorder

Question 25

zero delta S

Answer 25

no net change in disorder

Question 26

negative delta G

Answer 26

free energy released
exergonic, favorable
spontaneous reaction

Question 27

positive delta G

Answer 27

free energy required
endergonic, unfavorable
driven reaction

Question 28

zero delta G

Answer 28

equilibrium

Question 29

Give example of cooperative binding

Answer 29

hemoglobin binds oxygen cooperatively

Question 30

Positive cooperativity definition

Answer 30

binding site affinity for ligand increases with every subsequent binding

Question 31

negative cooperativity definition

Answer 31

binding site affinity for ligand decreases with every subsequent binding

Question 32

no cooperativity definition

Answer 32

binding sites are independent, situation can be Michaelis menten enzyme

Question 33

Km definition

Answer 33

Michaelis constat, [S] where reaction rate is half maximal OR half of the active sites are full

Km= [E] [S] / [ES]

Question 34

Vmax definiton

Answer 34

maximum rate possible for a give concentration of enzyme

Vmax= Kcat [E]T

Question 35

Kcat definition

Answer 35

number of substrate molecules concerted per active site per time (first order rate constant)

kcat= K2

Question 36

Kcat/Km definition

Answer 36

measure of enzyme performance by predicting the fate of E*S, how good an enzyme is

Kcat/Km= Kcat/ k-1 +Kcat

Question 37

VIEW DIFFERENT TYPES OF INHIBITORS

Answer 37

pictures on slides

Question 38

similarities between substate level control and feedback control

Answer 38

alters ability of reaction to proceed

Question 39

differences between substate level control and feedback control

Answer 39

substrate: acts on single reaction
feedback: acts on different reaction pathway

Question 40

example of substrate level control

Answer 40

G6P and hexokinase

Acetyl-CoA inhibits PDH

Question 41

example of feedback control

Answer 41

nucleotide de novo synthesis

aa biosynthesis

Question 42

similarities between activation and inhibition

Answer 42

alters ability of reaction to proceed, can be substrate or feedback

Question 43

differences between activation and inhibition

Answer 43

activation: adds new or increases existing function
inhibition: decreases or stops existing function

Question 44

example of activation

Answer 44

dephosphorylation of pyruvate kinase

Question 45

example of inhibition

Answer 45

phosphorylation of pyruvate kinase

Question 46

description of reversible covalent modification

Answer 46

+/- small molecule

Question 47

description of irreversible covalent modification

Answer 47

proteolytic activation

Question 48

similarities between reversible covalent modification and irreversible covalent modification

Answer 48

reversible: may be activating
irreversible: activating mechanism only

Question 49

differences between reversible covalent modification and irreversible covalent modification

Answer 49

reversible: may be inhibiting, reversible
irreversible: never inhibiting, irreversible

Question 50

examples of reversible covalent modification

Answer 50

histone modification
adenylation/uridylation
and glutamine synthetase
phosphorylation

Question 51

examples of irreversible covalent modification

Answer 51

protease cascade/digestive enzyme
blood clotting factors
insulin

Question 52

allosteric effector description

Answer 52

binds at unique locations and alters the proteins functionality

Question 53

competitive effector description

Answer 53

competes with intended substate to bind the active site

Question 54

allosteric effector and competitive effector similarities

Answer 54

allosteric: may inhibit function
competitive: always inhibits function

Question 55

allosteric effector and competitive effector differences

Answer 55

allosteric: does not bind active site, may be activating
competitive: binds at active site, can never be activating

Question 56

allosteric effector examples

Answer 56

ATCase
ribonucleotide reductase
phosphofructokinase

Question 57

competitive effector examples

Answer 57

methotrexate vs dihydrofolate for dihydrofolate reductase

Question 58

What does covalent catalysis do?

Answer 58

share electrons

Question 59

What does acid base catalysis do?

Answer 59

share protons

Question 60

What does approximation do in catalysis?

Answer 60

orientation and proximity

Question 61

What does electrostatic catalysis do?

Answer 61

non covalent interactions

Question 62

oxidoreductases description and example

Answer 62

description: redox, move elections
example: dehydrogenase (oxidizers)
reductases (reducers)

Question 63

transferases description and example

Answer 63

move a functional group
kinases add phosphate
phosphotases remove phosphate

Question 64

hydrolases description and example

Answer 64

break a bond by adding water

citrate synthase, lactose

Question 65

lyases description and example

Answer 65

break a bond without water

aldolase in glycolysis

Question 66

isomerases description and example

Answer 66

rearrange order of atoms

TPI

Question 67

ligases description and example

Answer 67

make a covalent bond

aldolase in gluconeogenesis

Question 68

Describe active transport

Answer 68

requires energy

moves something against/creates a concentration gradient

Question 69

Describe the P-type ATPase

Answer 69

phosphorylates itself
transports ions
4 domains: transmembrane, actuator, nucleotide, binding, phosphorylation
example: Na/K pump

Question 70

Describe the ABC transporter

Answer 70

no phosphorylation of self
transport small molecules
dimeric, contains 2 copies of transmembrane domain and aTP binding cassette (ABC)

example: multidrug resistance protein

Question 71

describe the secondary transport

Answer 71

uses gradient established by primary active transport
moves ion or molecule against its gradient without using energy

example: Na-glucose cotransport

Question 72

describe passive transport

Answer 72

no energy needed

Question 73

describe the ion channel

Answer 73

selectivity filter

gate: voltage gated, ligand gated

Question 74

describe the aquaporin

Answer 74

selectivity filter

no gate

Question 75

describe the gap junction

Answer 75

no selectivity filter

no gate

Question 76

review glycolysis, TCA and ox-phos

Answer 76

look at notes

Question 77

location of glycolysis

Answer 77

cytoplasm

Question 78

rate limiting enzyme of glycolysis

Answer 78

phosphofructokinase

Question 79

how does hexokinase regulate in glycolysis

Answer 79

G6P inhibits

Question 80

how is phosphofructokinase regulated in glycolysis

Answer 80

citrate inhibits

low ATP is activating

Question 81

how is pyruvate kinase regulated in glycolysis

Answer 81

high ATP is inhibitory

F16BP activates

Question 82

location of TCA cycle

Answer 82

mitochondrial matrix

Question 83

rate limiting enzyme of TCA cycle

Answer 83

isocitrate dehydrogenase

Question 84

how is the pyruvate dehydrogenase complex regulated in the TCA cycle

Answer 84

ATP, acetyl CoA, NADH are inhibitory (kinase/+PO4)

ADP and pyruvate are activating (phosphatase/-PO4)

Question 85

how is isocitrate dehydrogenase regulated in the TCA cycle

Answer 85

ATP and NADH inhibit

ADP activates

Question 86

how is alpha-ketoglutarate dehydrogenase complex regulated in TCA cycle

Answer 86

ATP, succinyl CoA and NADH inhibit

Question 87

location of ox phos

Answer 87

mitochondrial inner membrane and inter membrane space

Question 88

glycogenolysis location

Answer 88

cytoplasm

Question 89

glycogenolysis rate limiting enzyme

Answer 89

glycogen phosphorylase

Question 90

glycogenolysis regulated enzyme

Answer 90

glyogen phosphorylase

• dephosphorylation inhibits
• phosphorylation activates

Question 91

amino acid catabolism location

Answer 91

cytoplasm and mitochondrial matrix

urea cycle only in liver

Question 92

beta oxidation location

Answer 92

cytoplasm (activation)
mitochondrial matrix (beta oxidation)

Question 93

rate limiting enzyme of beta oxidation

Answer 93

perilipins

Question 94

how is perilipins regulated in beta oxidation

Answer 94

phosphorylation promotes TAG release by inhibiting perilipin

Question 95

location of ketone bodies

Answer 95

only produced in liver, but broken down in non liver cells though

Question 96

location of gluconeogenesis

Answer 96

cytoplasm (ER in liver and kidney only)

Question 97

rate limiting enzyme of gluconeogenesis

Answer 97

fructose- 1,6- bisphophate

Question 98

How is pyruvate carboxylase regulated in gluconeogenesis

Answer 98

ADP inhibits

acetyl CoA is activating

Question 99

how is PEP carboxykinase regulated in gluconeogenesis

Answer 99

ADP inhibits

Question 100

how is fructose 1,6 bisphoate regulated in gluconeogenesis

Answer 100

low ATP is inhibitory

citrate activates

Question 101

location of PPP

Answer 101

cytoplasm

Question 102

rate limiting enzyme of PPP

Answer 102

glucose 6 phosphate dehydrogenase

Question 103

how is G6P dehydrogenase regulated in the PPP

Answer 103

monomers inactive, dimers activate
dephosphorylated inactive, phosphorylation activates
insulin activates

Question 104

location of nucleotide de novo synthesis

Answer 104

cytoplasm (except dihydroorotate dehydrogenase in mitochondria)

Question 105

what are the regulated in enzymes in nucleotide de novo synthesis

Answer 105

general theme: feedback regulation

ribonucleotide reductase: activity site and specificity site

Question 106

amino acid biosynthesis location

Answer 106

cytoplasm and mitochondrial matrix

Question 107

amino acid biosynthesis regulated enzymes

Answer 107

general theme: feedback regulation

glutamine synthetase:

• adenylylation inhibits/deadenylylation actives
• PII is inactivating/ PII-UMP is activating
• feed back inhibition is glutamine
• feed forward activation is alpha ketoglutarate, ATP

Question 108

fatty acid synthesis location

Answer 108

cytoplasm and mitochondrial matrix

Question 109

rate limiting enzyme of fatty acid synthesis

Answer 109

acetyl coA carboxylase

Question 110

how is ATP citrate lyase regulated in fatty acid synthesis

Answer 110

activated by phosphorylation and glucose/insulin

inhibited by PUFAs and leptin

Question 111

how is acetyl coA carboxylase regulated in fatty acid synthesis

Answer 111

active by citrate, -PO4/ insulin, high carb diet

inhibited by palmitate, +PO4/epinephrine/glucagon/AMP

Question 112

how is fatty acid synthase regulated in fatty acid synthesis

Answer 112

activated by sugar-PO4, insulin, high carb diet

inhibited by high fat diet, starvation and PUFAs

Question 113

glycogenesis location

Answer 113

cytoplasm

Question 114

glycogenesis rate limiting enzyme

Answer 114

glycogen synthase

Question 115

how is glycogen synthase regulated in glycogenesis

Answer 115

phosphorylation inhibits

dephosphorylation activates

Question 116

where does TAG synthesis occur

Answer 116

hepatocytes and adipocytes