SAS #7: Biochemical Energy Production (Module)

Question 1

is the sum total of all the biochemical reactions that take place in a living organism.

Answer 1

Metabolism

Question 2

is a series of consecutive biochemical reactions used to convert a starting material into an end product, which is either linear or cyclic.

Answer 2

metabolic pathway

Question 3

sum total of all biochemical reaction of citric acid cycle, the electron transport chain, and oxidative phosphorylation

Answer 3

common metabolic pathway

Question 4

2 Types of Metabolism:

is all metabolic reactions in which small biochemical molecules are joined together to form larger ones

Answer 4

ANABOLISM

Question 5

2 Types of Metabolism:

Consumes energy.

Answer 5

ANABOLISM

Question 6

2 Types of Metabolism:

is all metabolic reactions in which large biochemical molecules are broken down to smaller ones

Answer 6

CATABOLISM

Question 7

2 Types of Metabolism:

Releases energy

Answer 7

CATABOLISM

Question 8

2 Types of Metabolism:

Ex. Oxidation of glucose

Answer 8

ANABOLISM

Question 9

2 Types of Metabolism:

Ex. Synthesis of proteins

Answer 9

CATABOLISM

Question 10

is a cell in which the DNA is found in a membrane-enclosed nucleus.

Answer 10

Eukaryotic cell

Question 11

Where DNA replication and RNA synthesis happens

Answer 11

Nucleus

Question 12

Cellular boundary

Answer 12

Plasma membrane

Question 13

the water-based material that lies between the nucleus and the outer membrane of the cell

Answer 13

Cytoplasm

Question 14

generates of most of the
energy for a cell

Answer 14

Mitochondria

Question 15

contains hydrolytic enzymes needed for cellular rebuilding, repair, and degradation

Answer 15

Lysosome

Question 16

site for protein synthesis

Answer 16

Ribosome

Question 17

Powerhouse of the cell

Answer 17

MITOCHONDRIA:

Question 18

▪ 50% lipid and 50% protein
▪ freely permeable to small molecules.

Answer 18

Outer membrane

Question 19

about 20% lipid and 80% protein

Answer 19

Inner membrane

Question 20

Highly impermeable to most substances

Answer 20

Inner membrane

Question 21

What is the interior region of the inner membrane?

Answer 21

Matrix

Question 22

What is the region between inner and outer membrane?

Answer 22

intermembrane space

Question 23

Folds into cristae to increase surface area

Answer 23

intermembrane space

Question 24

small spherical knob attached to cristae

Answer 24

ATP synthase complexes

Question 25

Site for ATP synthesis

Answer 25

ATP synthase complexes:

Question 26

the net energy produced used for cellular reactions

Answer 26

ATP (Adenosine Triphosphate)

Question 27

Active portion is –SH (sulfhydryl group) or as CoA-SH Derivative of Vit. B5

Answer 27

CoA (Coenzyme A)

Question 28

Coenzyme required for redox reactions, Derivative of Vit. B2

Answer 28

FAD (Flavin Adenine Dinucleotide)

Question 29

What is the oxidized form of FAD?

Answer 29

FAD+

Question 30

What is the reduced form of FAD?

Answer 30

FADH2

Question 31

Coenzyme required for redox reactions

Answer 31

NAD (Nicotinamide adenine dinucleotide)

Question 32

What is the oxidized form of NAD?

Answer 32

NAD+

Question 33

What is the reduced form of NAD?

Answer 33

NADH

Question 34

Derivative of Vit. B3

Answer 34

NAD (Nicotinamide adenine dinucleotide)

Question 35

REDOX REACTION:

hydrogen atom loss

Answer 35

Oxidation

Question 36

REDOX REACTION:

hydrogen atom gain.

Answer 36

Reductio

Question 37

is the biochemical process by which food molecules, through hydrolysis, are broken down into simpler chemical units that can be used by cells for their metabolic need

Answer 37

Digestion

Question 38

What are the end product of digestion?

Answer 38

Carbohydrates, proteins, fats and oils

Question 39

Acetyl group formation:

reaction in cytosol

Answer 39

glucose metabolism

Question 40

acetyl group formation:

reaction in the mitochondria

Answer 40

fatty acid metabolism

Question 41

the end product of acetyl group formation

Answer 41

Acetyl CoA

Question 42

what are the primary products of acetyl group formation?

Answer 42

2-carbon acetyl units and the reduced coenzyme NADH

Question 43

A cycle that occurs in the mitochondria

Answer 43

Citric acid cycle

Question 44

Acetyl groups are oxidized to produce CO2 (which we exhale during breathing) and energy.

Answer 44

citric acid cycle

Question 45

Some of the energy released by these reactions is lost as heat, and some is carried by the reduced coenzymes NADH and FADH2 to the fourth stage.

Answer 45

the citric acid cycle

Question 46

Where does the electron transport chain and oxidative phosphorylation occurs?

Answer 46

Mitochondria

Question 47

Who discovered the Krebs cycle?

Answer 47

Hans Adolf Krebs

Question 48

take place in the mitochondrial matrix for eukaryotes and cytosol for the prokaryotes.

Answer 48

Krebs cycle

Question 49

Oxidation (produces NADH or FADH2), and decarboxylation, (carbon chain is shortened by the removal of a carbon atom as a CO2 molecule), are steps involved.

Answer 49

Krebs cycle

Question 50

Reactions of the Citric Acid Cycle:

carries the two-carbon degradation product of carbohydrates, fats, and proteins, enters the cycle by combining with the four- carbon keto dicarboxylate species oxaloacetate.

Answer 50

Step 1: Formation of Citrate

Question 51

Reactions of the Citric Acid Cycle:

This results in the transfer of the acetyl group from coenzyme A to oxaloacetate, producing the C6 citrate species and free coenzyme A.

Answer 51

Step 1: Formation of Citrate

Question 52

Reactions of the Citric Acid Cycle:

There are two parts to the reaction: (1) the condensation of acetyl CoA and oxaloacetate to form citryl CoA, a process catalyzed by the enzyme citrate synthase and (2) hydrolysis of the thioester bond in citryl CoA to produce CoA-SH and citrate, also catalyzed by the enzyme citrate synthase.

Answer 52

Step 1: Formation of Citrate

Question 53

Reactions of the Citric Acid Cycle:

Citrate is converted to its less symmetrical isomer isocitrate in an isomerization process that involves a dehydration followed by a hydration, both catalyzed by the enzyme aconitase.

Answer 53

Step 2: Formation of Isocitrate.

Question 54

Reactions of the Citric Acid Cycle:

The net result of these reactions is that the -OH group from citrate is moved to a different carbon atom. Citrate is a tertiary alcohol and isocitrate a secondary alcohol. Tertiary alcohols are not readily oxidized; secondary alcohols are easier to oxidize. The next step in the cycle involves oxidation.

Answer 54

Step 2: Formation of Isocitrate.

Question 55

Reactions of the Citric Acid Cycle:

This step involves oxidation–reduction (the first of four redox reactions in the citric acid cycle) and decarboxylation.

Answer 55

Step 3: Oxidation of Isocitrate and Formation of CO2.

Question 56

Reactions of the Citric Acid Cycle:

The reactants are a NAD+ molecule and isocitrate.

Answer 56

Step 3: Oxidation of Isocitrate and Formation of CO2.

Question 57

Reactions of the Citric Acid Cycle:

This second redox reaction of the cycle involves one molecule each of NAD+, CoA-SH, and a-ketoglutarate.

Answer 57

Step 4: Oxidation of a-Ketoglutarate and Formation of CO2.

Question 58

Reactions of the Citric Acid Cycle:

Two reactant molecules are involved in this step—a Pi (HPO4-2) and a GDP (similar to ADP). The entire reaction is catalyzed by the enzyme succinyl-CoA synthetase.

Answer 58

Step 5: Thioester Bond Cleavage in Succinyl CoA and Phosphorylation of GDP.

Question 59

Reactions of the Citric Acid Cycle:

This is the third redox reaction of the cycle. The enzyme involved is succinate dehydrogenase, and the oxidizing agent is FAD rather than NAD+.

Answer 59

Step 6: Oxidation of Succinate.

Question 60

Reactions of the Citric Acid Cycle:

The enzyme fumarase catalyzes the addition of water to the double bond of fumarate. The enzyme is stereospecific, so only the L isomer of the product malate is produced.

Answer 60

Step 7: Hydration of Fumarate.

Question 61

Reactions of the Citric Acid Cycle:

In the fourth oxidation–reduction reaction of the cycle, a molecule of NAD+ reacts with malate, picking up two hydrogen atoms with their associated energy to form NADH+ H+. The needed enzyme is malate dehydrogenase. The product of this reaction is regenerated oxaloacetate, which can combine with another molecule of acetyl CoA (Step 1), and the cycle can begin again.

Answer 61

Step 8: Oxidation of L-Malate to Regenerate Oxaloacetate.

Question 62

is a series of biochemical reactions in which electrons and hydrogen ions from NADH and FADH2 are passed to intermediate carriers and then ultimately react with molecular oxygen to produce water. NADH and FADH2 are oxidized in this process.

Answer 62

Electron Transport Chain

Question 63

The enzymes and electron carriers needed for the ETC are located along the __________________.

Answer 63

inner mitochondrial membrane

Question 64

is the biochemical process by which ATP is synthesized from ADP as a result of the transfer of electrons and hydrogen ions from NADH or FADH2 to O2 through the electron carriers involved in the electron transport chain.

Answer 64

Oxidative Phosphorylation

Question 65

transferring protons from the matrix side of the inner mitochondrial membrane to the intermembrane space.

Answer 65

proton pumps

Question 66

is an explanation for the coupling of ATP synthesis with electron transport chain reactions that requires a proton gradient across the inner mitochondrial membrane.

Answer 66

Chemiosmotic coupling