Metabolism (9a)

Question 1

Metabolism?

Answer 1

= all the biochemical reactions occurring in an organism.

Question 2

What is metabolism divided into?

Answer 2

Metabolic pathways.

Question 3

Metabolic pathways?

Answer 3

= series of biochemical reactions that act together to produce a product.

Question 4

Kinds of metabolic pathways? (3)

Answer 4

• Linear.
• Cyclic.
• Branched.

Question 5

Lay out the linear metabolic pathway?

Answer 5

a
| (E1)
b
| (E2)
c
| (E3)
d
| (E4)
e

Question 6

Describe Cyclic metabolic pathway? (2)

Answer 6

• circle pathway.
• start with 1 molecule & end up with the same molecule (but more).

Question 7

Branched metabolic pathway features?

Answer 7

• circle pathway where you start with 1 molecule & end up with the same molecule.

OR

• circle pathway where you start with 1 molecule & end up with a different molecule/different pathway.

Question 8

Pros of metabolic pathways? (3)

Answer 8

• Can be segregated, either within organelles or specific parts of the cytoplasm.

• Little accumulation of intermediates.

• Rate at which product is used controls the rate of the pathway.

Question 9

Metabolism divisions? (2)

Answer 9

• Anabolism/Anabolic pathways.
• Catabolism/Catabolic pathways.

Question 10

Anabolism/Anabolic pathways?

Answer 10

= biosynthesis of complex organic molecules from simple molecules.

Question 11

Catabolism/Catabolic pathways?

Answer 11

= biodegradation of complex organic molecules to simple molecules.

Question 12

Special feature of Catabolism?

Answer 12

It releases chemical energy & intermediates which can be used in other pathways/Anabolic pathways.

Question 13

Eg of Anabolic pathway?

Answer 13

Photosynthesis.

Question 14

Eg of Catabolic pathway?

Answer 14

Respiration.

Question 15

How is energy needed for cellular activity provided?

Answer 15

Provided by the oxidation of fuels namely, carbohydrates, lipids & proteins.

Question 16

Egs of Fuels? (3)

Answer 16

• Carbohydrates.
• Lipids.
• Proteins.

Question 17

Site of breakdown processes? (2)

Answer 17

• Cytoplasm.
• Mitochondria.

Question 18

Result of breakdown processes?

Answer 18

Energy is released and captured in the form of ATP.

Question 19

ATP use types? (2)

Answer 19

• Direct uses.
• Indirect uses.

Question 20

Direct uses of ATP? (3)

Answer 20

• Movement.
• Thermoregulation.
• Transport of molecules across membranes.

Question 21

Enzyme that indicates direct use of ATP?

Answer 21

ATPase.

Question 22

Indirect use of ATP?

Answer 22

Glycolysis.

Question 23

Enzyme that indicates the indirect use of ATP?

Answer 23

Kinase.

Question 24

Equation of direct use of ATP?

Answer 24

ATP —> ADP + phosphate.

Question 25

Equation of indirect use of ATP?

Answer 25

ATP + biomolecule —> ADP + phosphorylated biomolecule

Question 26

Cellular Respiration AKA?

Answer 26

Cellular Oxidation.

Question 27

Lay out process of Cellular Oxidation? (5)

Answer 27

● Stage 1
• Glycolysis.

● Stage 2
• Link reactions.
• Kreb’s cycle.
• Electron transport.
• Oxidation phosphorylation.

Question 28

Site for Stage 1 of Cellular respiration?

Answer 28

Cytoplasm.

Question 29

Site for Stage 2 of Cellular respiration?

Answer 29

Mitochondria.

Question 30

Mitochondria features? (7)

Answer 30

• Spherical, fibrillar & granular.
• 100-1000/cell in most cell types.
• Dynamic structures.
• 2-membrane system.
• 2 compartments (due to membranes).
• Quantitative & qualitative differences between IM & OM.
• Autonomous.

Question 31

Fibrillar?

Answer 31

= has long fibrils.

Question 32

Eg of mitochondrial diversity?

Answer 32

● Amphibian egg
= 100 000 mitochondria.

● Micromonas
= 1 mitochondrion.

Question 33

Dynamic structures?

Answer 33

= continually changing shape.

Question 34

Mitochondrial membranes? (2)

Answer 34

• Outer membrane (OM).
• Inner membrane (IM).

Question 35

OM features? (2)

Answer 35

• continuous.
• separates organelles from the cytoplasm.

Question 36

IM features? (2)

Answer 36

• folded to form cristae.
• cristae extend into centre of organelle.

Question 37

Mitochondrial compartments? (2)

Answer 37

• Intermembrane compartment/space.
• Matrix.

Question 38

Intermembrane space?

Answer 38

= between inner & outer membrane.

Question 39

Matrix?

Answer 39

= enclosed in inner membrane.

Question 40

Quantitative differences between OM & IM? (2)

Answer 40

● OM
• 40% phospholipids.
• 60% protein.

● IM
• 25% phospholipids.
• 75% protein.

Question 41

Qualitative difference between OM & IM?

Answer 41

● OM
= 14 protein types.

● IM
= 20 protein types.

Question 42

Autonomous?

Answer 42

= mitochondria contain its own DNA & ribosomes.

Question 43

Results of mitochondria being autonomous? (2)

Answer 43

• Mitochondria can transcribe & translate a number of proteins.

• Remainder of proteins are from the cell nucleus & cell cytoplasm.

Question 44

Glycolysis features? (5)

Answer 44

• Stage 1 of Cellular respiration.

• Splits glucose (6C) into 3C fragments, energy is released & is captured in the form of ATP.

• Pathway divided into 2 sets of reactions.

• Enzymes of pathway are all located on juxtaposition on the surface of the micro microfilaments of the cytoskeleton.

• broken into 2 parts.

Question 45

How many enzymes in Glycolysis?

Answer 45

10.

Question 46

Juxtaposition?

Answer 46

= next to each other.

Question 47

Part 1 of Glycolysis features? (2)

Answer 47

• Energy utilizing ATP.
• Cells use 2ATPs.

Question 48

Part 2 of Glycolysis features? (2)

Answer 48

• Energy producing ATP.
• Cells gain 2ATPs.

Question 49

Part 1 of Glycolysis?

Answer 49

= elevation of energy levels of glucose.

Question 50

Glycolysis Rxn 1?

Answer 50

• ATP —> ADP.

Glucose
|
Glucose-6-phosphate.

Question 51

Rxn 1 enzyme?

Answer 51

Hexokinase.

Question 52

Hexokinase features? (2)

Answer 52

• Allosteric enzyme.
• Sensitive to levels of Glucose-6-phosphate.

Question 53

Glycolysis Rxn 2?

Answer 53

Rearrangement of:

Glucose-6-phosphate
|
Fructose-6-phosphate.

Question 54

Rxn 2 enzyme?

Answer 54

Phosphogluco-isomerase.

Question 55

Glycolysis Rxn 3?

Answer 55

• ATP —> ADP.

Fructose-6-phosphate
|
Fructose-1,6-phosphate.

Question 56

Rxn 3 enzyme?

Answer 56

Phosphofructokinase.

Question 57

Phosphofructokinase features? (2)

Answer 57

• Allosteric enzyme.
• Sensitive to ATP & NADH.

Question 58

Fructose-1,6-phosphate?

Answer 58

Has 2 allosteric sites, 1 for ATP, 1 for NADH.

Question 59

Part 2 of Glycolysis?

Answer 59

= oxidation of high energy level glucose to 3C pyruvate.

Question 60

Pyruvate AKA?

Answer 60

Pyruvic acid.

Question 61

Glycolysis Rxn 4?

Answer 61

Fructose-1,6-phosphate
| |
3, PGAL Dihydroxyacetate phosphate

Question 62

Rxn 4 enzyme?

Answer 62

Aldolase.

Question 63

Glycolysis Rxn 5?

Answer 63

Dihydroxyacetate phosphate
|
3, PGAL.

Question 64

Rxn 5 enzyme?

Answer 64

Triosephosphate isomerase.

Question 65

Why does Rxn 5 happen?

Answer 65

To make Dihydroxyacetate phosphate useful to Glycolysis.

Question 66

3, PGAL stands for?

Answer 66

3-phosphoglyceraldehyde.

Question 67

Glycolysis Rxn 6?

Answer 67

3, PGAL
|
1,3- diphosphoglycerate.

Question 68

Rxn 6 enzyme?

Answer 68

3 phosphoglyceraldehyde dehydrogenase.

Question 69

Rxn 6 features? (2)

Answer 69

• Inorganic phosphate (Pi).
• NAD —> NADH.

Question 70

Glycolysis Rxn 7?

Answer 70

1,3- diphosphoglycerate
|
3- phosphoglycerate.

Question 71

Rxn 7 enzyme?

Answer 71

Diphosphoglycerate kinase.

Question 72

Rxn 7 feature?

Answer 72

ADP —> ATP.

Question 73

Glycolysis Rxn 8?

Answer 73

3-phosphoglycerate
|
2-phosphogylcerate.

Question 74

Rxn 8 enzyme?

Answer 74

Phosphoglyceroisomerase.

Question 75

Glycolysis Rxn 9?

Answer 75

2-phosphogylcerate
|
PEP

Question 76

PEP stands for?

Answer 76

Phosphoenol pyruvate.

Question 77

Rxn 9 enzyme?

Answer 77

Enolase.

Question 78

Glycolysis Rxn 10?

Answer 78

PEP
|
Pyruvate.

Question 79

Rxn 10 enzyme?

Answer 79

Pyruvate kinase.

Question 80

Rxn 10 feature?

Answer 80

ADP —> ATP.

Question 81

List the energy capturing reactions in Glycolysis? (3)

Answer 81

• Rxn 6.
• Rxn 7.
• Rxn 10.

Question 82

What do we associate energy capturing reactions with? (2)

Answer 82

• Dephosphorylation.
• ADP —> ATP.

Question 83

End product of S1 of Cellular oxidation?

Answer 83

Pyruvate.

Question 84

S2 Cellular Oxidation features? (3)

Answer 84

● 3C Pyruvate is broken down into CO2 & H2O.

● 3 stages/parts.

● All stages/parts occur in mitochondria.

Question 85

The 3 parts of S2 of Cellular Oxidation?

Answer 85

• P1= Link reactions.
• P2= Krebs cycle.
• P3= E transport/Oxidative phosphorylation.

Question 86

What happens in link reactions/P1?

Answer 86

Pyruvate —> 2C + CO2 (released).

Question 87

What happens in the Krebs cycle/P2?

Answer 87

2C —> 2CO2.

Question 88

What happens in P3 of S2 of CellularOxidation? (2)

Answer 88

● The electrons released in P1 & P2 are passed down a chain of molecules to reach O2 to form water.

● Energy is released & is used to create ATP.

Question 89

Where does S2 of Cellular Oxidation occur?

Answer 89

Mitochondria.

Question 90

P1 of S2 of Cellular Oxidation layout? (4)

Answer 90

Pyruvate (from cytoplasm)
|
Pyruvate (to mitochondrial matrix) [3C]
|
Acetyl group (CH3CO) [2C]
|
Acetyl CoA

Question 91

Enzymes in P1 of S2 of Cellular Oxidation? (2)

Answer 91

• Pyruvic acid dehydrogenase.
• Coenzyme A.

Question 92

Pyruvic acid dehydrogenase features? (2)

Answer 92

• Allosteric.
• Sensitive to ATP (low ATP, increases).

Question 93

What else happens in P1 of S2 of Cellular respiration? (3)

Answer 93

• Pyruvate moves through membrane from cytoplasm to mitochondrial matrix.
• CO2 is released.
• NAD –> NADH.

Question 94

Krebs cycle AKA?

Answer 94

Citric acid cycle.

Question 95

P1 of S2 of Cellular Oxidation?

Answer 95

= oxidation of pyruvate to a 2C acetyl molecule.

Question 96

P2 of S2 of Cellular Oxidation?

Answer 96

= Krebs cycle/ Citric acid cycle.

Question 97

Special feature of Krebs cycle?

Answer 97

Cyclic pathway.

Question 98

P2 of S2 of Cellular Oxidation layout? (7)

Answer 98

Acetyl CoA (2C) + Oxaloacetate (4C)
|
Citric acid (6C)
|
Isocitrate (6C)
|
alpha Ketoglutarate (5C)
|
Succinic acid (4C)
|
Fumurate (4C) [rearranged from previous]
|
Malate (4C)

Cyethenrepeats again circularly.

Question 99

6C to 5C? (2)

Answer 99

• NAD –> NADH.
• H+ & CO2 released.

Question 100

5C to 4C? (3)

Answer 100

• NAD –> NADH.
• ADP –> ATP.
• H+ & CO2 released.

Question 101

Succinic acid TO Fumurate?

Answer 101

FAD –> FADH2.

Question 102

FAD stands for?

Answer 102

Flavin Adenine Dinucleotide.

Question 103

Malate TO Start of Krebs cycle?

Answer 103

NAD –> NADH.

Question 104

P3 of S2 of Cellular Oxidation?

Answer 104

= electron transport & Oxidative phosphorylation.

Question 105

P3 of S2 of CO layout? (3)

Answer 105

● Electrons associated with NADH & FADH2 are passed along a chain of molecules.

● Electrons are delivered to O2 & this O2 combines with H2 to form H2O.

● During transfer of electrons, energy is released & is used to create ATP.

Question 106

Where does electron transport (P3) occur?

Answer 106

Within inner membrane of mitochondria.

Question 107

Types of electron carrier molecules? (4)

Answer 107

• Flavoproteins.
• Cytochromes.
• Fe-S (Iron-Sulphur) proteins.
• Coenzyme Q.

Question 108

Flavoproteins?

Answer 108

= protein plus a prosthetic group.

Question 109

Prosthetic group?

Answer 109

= a structure that can be repeatedly oxidized & reduced.

Question 110

Prosthetic group derivation?

Answer 110

From riboflavin (vitamin B).

Question 111

Prosthetic group composition? (3)

Answer 111

• Nitrogenous base.
• 5C sugar.
• Phosphate group.

Question 112

Cytochromes?

Answer 112

= 5 cytochromes in electron chain.

Question 113

Cytochrome composition? (2)

Answer 113

• Prophyrin ring.
• with Central Fe atom.

Question 114

Prophyrin ring?

Answer 114

= ring of Nitrogen atoms.

Question 115

Cytochrome types? (5)

Answer 115

• Cytochrome a.
• Cytochrome a3.
• Cytochrome b.
• Cytochrome c.
• Cytochrome c1.

Question 116

Fe-S proteins composition? (2)

Answer 116

• A specialized protein (repeatedly oxidized & reduced).
• Atoms of Fe & S.

Question 117

How many kinds of Fe-S proteins exist?

Answer 117

7.

Question 118

Coenzyme Q composition? (2)

Answer 118

• A lipid.
• A quinine ring.

Question 119

Oxidative phosphorylation process? (2)

Answer 119

● A proton gradient is established across the inner membrane of mitochondria.

● The potential energy in the proton gradient is used to create ATP.

Question 120

Special fact about IM of mitochondria?

Answer 120

It’s impermeable to movement of molecules back.

Question 121

Things to note in Oxidative phosphorylation? (2)

Answer 121

● H+ ions from Krebs cycle & matrix is getting less acidic and intermembrane is acidic.

● Energy released during e transport moves the H+ ions through IM to intermembrane space & becomes more acidic as [H+] increases.

Question 122

ATP synthetase features? (2)

Answer 122

• Complex enzyme.
• Divided into Fo & F1.

Question 123

Fo?

Answer 123

= transport protein.

Question 123

Fo?

Answer 123

= transport protein.

Question 124

Fo located?

Answer 124

Embedded in inner membrane of mitochondria.

Question 125

Fo role?

Answer 125

Transverses the membrane & provides a channel for proton movement.

Question 126

F1?

Answer 126

= large structure made of 9 polypeptides

Question 127

F1 role?

Answer 127

Site of ATP.

Question 128

F1 location?

Answer 128

Mitochondrial matrix.

Question 129

What is the question scientists are still figuring out about ATP synthetase?

Answer 129

How many proteins does it take?

Question 130

Explain election transport chain.

Question 131

Oxidative phosphorylation location?/ Where does it occur?

Answer 131

Across the inner membrane of the mitochondrion.