Lecture 26

Question 1

What is the change in free energy?

Answer 1

The free energy that is associated with the free energy of products minus free energy of reactants

Question 2

What is 𝛥Gº?

Answer 2

The standard free energy change in the chemical standard state

Question 3

What is 𝛥Gº’ ?

Answer 3

The change in free energy of the biochemical standard state

Question 4

What does 𝛥Gº take into account?

Answer 4

Things like protons and water

Question 5

What does the actual free energy change deal with?

Answer 5

The actual concentrations of the reactants and products for a given reaction but not standard concentrations that is usually 1 molar for reactants and products

Question 6

Why is actual free energy change more important than standard free energy?

Answer 6

Because in real situations were never at the standard state

Question 7

When is standard free energy change useful?

Answer 7

Reactions in terms of stability of products vs substrates

Question 8

What are the conditions of the the biochemical standard state?

Answer 8

• pH = 7
• [S] & [P] = 1M
• Temperature = 25ºC/298K
• Pressure = 1 atm
• [H2O] = 55M

Question 9

What is the proton concentration in the biochemical state?

Answer 9

10^-7 molar

Question 10

Why is the [H2O] = 55M in the biochemical standard state?

Answer 10

Because that is the amount found in a unit volume

Question 11

What do we exclude from biochemical reaction calculations and why?

Answer 11

• [H+]
• [H2O]
• Because we assume they’re not changing much

Question 12

What must the actual free energy change be for a reaction to proceed?

Answer 12

It must be negative

Question 13

What must the characteristics of the standard free energy change be for a reaction to proceed?

Answer 13

It doesn’t necessarily have to be negative for a reaction to proceed

Question 14

What must be negative for a reaction to proceed?

Answer 14

𝛥G’ is negative - Actual free energy change is negative

Question 15

What does Exergonic mean?

Answer 15

𝛥G’ (actual free energy change) is negative and the reaction is spontaneous

Question 16

What can be used to represent the symbols of actual free energy change?

Answer 16

𝛥G’

Question 17

What determines if a reaction is going to proceed in the forward or reverse direction?

Answer 17

Actual free energy change

Question 18

What does it mean if free energy is greater than zero (𝛥G > 0)?

Answer 18

A reaction will not occur in the forward direction, it will proceed backwards so that substrates are favored

Question 19

What does it mean if free energy is less than zero (𝛥G < 0)?

Answer 19

Reaction will occur spontaneously

Question 20

When will a reaction be considered irreversible?

Answer 20

𝛥G &laquo_space;0

Question 21

When is reaction considered reversible?

Answer 21

When 𝛥G ~ 0

Question 22

What is an irreversible reaction?

Answer 22

One where the free energy change is always negative under cellular conditions

Question 23

Which types of reactions are more encountered in metabolic pathways?

Answer 23

Reversible reactions

Question 24

What does it mean if actual free energy (𝛥G) is close to zeroe?

Answer 24

The system is close to equilibrium, and the reaction can be reversible

Question 25

What is 𝛥G?

Answer 25

The chemical actual free energy change

Question 26

What is 𝛥G’?

Answer 26

The biochemical actual free energy change

Question 27

What is 𝛥Gº’?

Answer 27

The actual free energy of the biochemical standard state

Question 28

What is 𝛥G’?

Answer 28

The biochemical actual free energy change

Question 29

What may change the the direction of the reaction in reversible reaction?

Answer 29

Changes in concentration of either the reactants or products

Question 30

What happens as the concentration of C in a reversible reaction is increased?

Answer 30

The second term becomes more positive and the free energy change will also become more positive and the reaction will proceed in the reverse direction

Question 31

What happens as the concentration of B in a reversible reaction is increased? (B ➡️ C)

Answer 31

The second value in the equation becomes smaller and the terms becomes less positive or more negative and the actual free energy then becomes negative and the reaction proceeds in the forward direction

Question 32

What happens to the actual free energy if Q is increased (less reactants more products)?

Answer 32

The actual free energy becomes less negative

Question 33

What should 𝛥G (actual free energy) be equal to at equilibrium?

Answer 33

It should be equal to 0

Question 34

What should Q be equal to at equilibrium?

Answer 34

K

Question 35

What does it mean in terms of reactants and products if the actual free energy change is more negative?

Answer 35

This means the reaction is more spontaneous so there are more reactants to drive the products. Because looking at Q, the ratio of products to reactants, there are more reactants on the bottom meaning that Q is smaller and the whole term is smaller

Question 36

What are metabolic pathways?

Answer 36

A series of enzyme-catalyzed chemical reactions

Question 37

When will a metabolic pathway proceed?

Answer 37

When the free energy change overall is negative ie. exergonic

Question 38

In a metabolic pathway (A→B↔C↔D→E) what are the concentrations of intermediates?

Answer 38

A and E change but B, C, and D are relatively stable

Question 39

Which steps in metabolism are usually regulated?

Answer 39

Irreversible steps are usually regulated

Question 40

What is the rate-limiting step in a pathway?

Answer 40

The irreversible, regulated reaction that determines the overall rate of the pathway

Question 41

What is product inhibition?

Answer 41

When an enzyme is inhibited by the product of its reaction

Question 42

What is feedback inhibition?

Answer 42

When an enzyme is inhibited by a metabolite further down the pathway

Question 43

What is feedback inhibition an example of?

Answer 43

Negative heteroallostery

Question 44

What is feed-forward activation?

Answer 44

When an enzyme may be activated by a metabolite upstream

Question 45

What is feed forward activation an example of?

Answer 45

Positive heteroallostery

Question 46

What kind of allostery is product inhibition?

Answer 46

It is heteroallostery

Question 47

What is the reciprocal pathway to glycolysis?

Answer 47

Gluconeogenesis

Question 48

What is added in reciprocal regulation?

Answer 48

Different enzymes that may consume ATP to catalyze the reverse reaction

Question 49

What is the free energy change of reversible reactions?

Answer 49

About 0

Question 50

What is the direction of reversible reactions dependant on?

Answer 50

The concentration of the substrates and products

Question 51

What aren’t usually the point of control in a metabolic pathway?

Answer 51

Reversible reactions

Question 52

Do reversible reactions use enzymes?

Answer 52

Yes

Question 53

What contributes to metabolic pathways acting at a steady state?

Answer 53

• biological reactions being reversible
• key reactions at the beginning and end of a pathway are often regulated synchronously
• reversible reactions proceed to equilibrium

Question 54

When are catabolic pathways active?

Answer 54

When cellular energy levels are low

Question 55

What are high energy intermediates?

Answer 55

Compounds which contain usable chemical energy

Question 56

What is the criteria for high energy intermediates?

Answer 56

• Energy can be recovered or used

* Simple reaction associated with large 𝛥G (20kJ/mol released)

Question 57

What are the three major types of high energy intermediates?

Answer 57

• Electron carriers
• Nucleotide triphosphates
• Thioesters

Question 58

What are examples of electron carriers?

Answer 58

• NADH
• NADPH
• FADH2
• FMNH2

Question 59

What are the electron acceptors?

Answer 59

NAD+, NADP+, FAD and FMN

Question 60

What are examples of nucleotide triphosphates?

Answer 60

ATP, UTP, GTP

Question 61

Why are NTPs considered high energy molecules?

Answer 61

Because of the phosphoanhydride bond

Question 62

What are the products of hydrolysis of a thioester?

Answer 62

A carboxylate and a thiol

Question 63

Is Catabolism oxidative or reductive?

Answer 63

Oxidative

Question 64

Is anbolism oxidative or reductive?

Answer 64

Reductive

Question 65

What happens to metabolites in catabolism?

Answer 65

They lose electrons (are oxidized)

Question 66

What happens to cofactors in catabolism?

Answer 66

They are reduced (this is why they are oxidizing agents)

Question 67

What happens to metabolites in anabolism?

Answer 67

They are reduced (gain electrons)

Question 68

What happens to cofactors in anabolism?

Answer 68

They are oxidized (this is why they are called reducing agents)