1. Lectures prepared by Christine L. Case
Chapter 5
Microbial Metabolism
Lectures prepared by Christine L. Case
© 2013 Pearson Education, Inc. 1

3. Catabolic and Anabolic Reactions
Metabolism: the sum of the chemical reactions in an organism

4. Catabolic and Anabolic Reactions
Catabolism: provides energy and building blocks for anabolism
Anabolism: uses energy and building blocks to build large molecules

5. Figure 5.1 The role of ATP in coupling anabolic and catabolic reactions.

6. Catabolic and Anabolic Reactions
A metabolic pathway is a sequence of enzymatically catalyzed chemical reactions in a cell
Metabolic pathways are determined by enzymes
Enzymes are encoded by genes
ANIMATION Metabolism: Overview

7. Collision Theory
The collision theory states that chemical reactions can occur when atoms, ions, and molecules collide
Activation energy is needed to disrupt electronic configurations
Reaction rate is the frequency of collisions with enough energy to bring about a reaction
Reaction rate can be increased by enzymes or by increasing temperature or pressure

8. Reaction Activation without enzyme energy without enzyme Reaction
Figure 5.2 Energy requirements of a chemical reaction.
Reaction
without enzyme
Activation
energy
without enzyme
Reaction
with enzyme
Activation
energy
with
enzyme
Reactant
Initial energy level
Final energy level
Products

9. Enzyme Components Biological catalysts Apoenzyme: protein
Specific for a chemical reaction; not used up in that reaction
Apoenzyme: protein
Cofactor: nonprotein component
Coenzyme: organic cofactor
Holoenzyme: apoenzyme plus cofactor

10. Coenzyme Substrate Apoenzyme (protein portion), inactive Cofactor
Figure 5.3 Components of a holoenzyme.
Coenzyme
Substrate
Apoenzyme
(protein portion),
inactive
Cofactor
(nonprotein portion),
activator
Holoenzyme
(whole enzyme),
active

11. Important Coenzymes
NAD+
NADP+
FAD
Coenzyme A

12. Enzyme Specificity and Efficiency
The turnover number is generally 1 to 10,000 molecules per second
ANIMATION Enzymes: Overview
ANIMATION Enzymes: Steps in a Reaction

13. Active site Products Substrate Enzyme–substrate Enzyme complex
Figure 5.4a The mechanism of enzymatic action.
Active site
Substrate
Products
Enzyme
Enzyme–substrate
complex

14. Enzyme Substrate Substrate
Figure 5.4b The mechanism of enzymatic action.
Enzyme
Substrate
Substrate

15. Enzyme Classification
Oxidoreductase: oxidation-reduction reactions
Transferase: transfer functional groups
Hydrolase: hydrolysis
Lyase: removal of atoms without hydrolysis
Isomerase: rearrangement of atoms
Ligase: joining of molecules; uses ATP

16. Factors Influencing Enzyme Activity
Temperature pH
Substrate concentration
Inhibitors

17. Factors Influencing Enzyme Activity
Temperature and pH denature proteins

18. Active (functional) protein Denatured protein
Figure 5.6 Denaturation of a protein.
Active (functional) protein
Denatured protein

19. Figure 5.5a Factors that influence enzymatic activity, plotted for a hypothetical enzyme.
(a) Temperature. The enzymatic activity (rate of reaction catalyzed by the enzyme) increases with increasing temperature until the enzyme, a protein, is denatured by heat and inactivated. At this point, the reaction rate falls steeply.

20. Figure 5.5b Factors that influence enzymatic activity, plotted for a hypothetical enzyme.
(b) pH. The enzyme illustrated is most active at about pH 5.0.

21. Figure 5.5c Factors that influence enzymatic activity, plotted for a hypothetical enzyme.
(c) Substrate concentration. With increasing concentration of substrate molecules, the rate of reaction increases until the active sites on all the enzyme molecules are filled, at which point the maximum rate of reaction is reached.

22. Normal Binding of Substrate Action of Enzyme Inhibitors
Figure 5.7ab Enzyme inhibitors.
Normal Binding of Substrate
Action of Enzyme Inhibitors
Substrate
Competitive
inhibitor
Active site
Enzyme

23. Enzyme Inhibitors: Competitive Inhibition

24. Normal Binding of Substrate Action of Enzyme Inhibitors
Figure 5.7ac Enzyme inhibitors.
Normal Binding of Substrate
Action of Enzyme Inhibitors
Altered
active site
Substrate
Active site
Enzyme
Noncompetitive
inhibitor
Allosteric
site

25. Figure 5.8 Feedback inhibition.
Substrate
Pathway
Operates
Pathway
Shuts Down
Enzyme 1
Allosteric site
Intermediate A
Bound
end-product
Enzyme 2
Feedback Inhibition
Intermediate B
Enzyme 3
End-product

26. Ribozymes
RNA that cuts and splices RNA

27. Oxidation-Reduction Reactions
Oxidation: removal of electrons
Reduction: gain of electrons
Redox reaction: an oxidation reaction paired with a reduction reaction

28. Reduction A B A oxidized B reduced Oxidation
Figure 5.9 Oxidation-reduction.
Reduction A B
A oxidized
B reduced
Oxidation

29. Oxidation-Reduction Reactions
In biological systems, the electrons are often associated with hydrogen atoms
Biological oxidations are often dehydrogenations
ANIMATION Oxidation-Reduction Reactions

30. (reduced electron carrier)
Figure 5.10 Representative biological oxidation.
Reduction H+
(proton) H
Organic molecule
that includes two
hydrogen atoms (H)
NAD+ coenzyme
(electron carrier)
Oxidized organic
molecule
NADH + H+ (proton)
(reduced electron carrier)
Oxidation

31. The Generation of ATP
ATP is generated by the phosphorylation of ADP

32. The Generation of ATP

33. Substrate-Level Phosphorylation
Energy from the transfer of a high-energy PO4– to ADP generates ATP

34. Substrate-Level Phosphorylation

35. Oxidative Phosphorylation
Energy released from transfer of electrons (oxidation) of one compound to another (reduction) is used to generate ATP in the electron transport chain

36. Figure 5.14 An electron transport chain (system).
Flow of electrons
Energy

37. Photophosphorylation
Light causes chlorophyll to give up electrons
Energy released from transfer of electrons (oxidation) of chlorophyll through a system of carrier molecules is used to generate ATP

38. (a) Cyclic photophosphorylation
Figure 5.25 Photophosphorylation.
Electron
transport
chain
Light
Excited
electrons
Energy for
production
of ATP
Electron carrier
In Photosystem I
(a) Cyclic photophosphorylation
Electron
transport
chain
Light
Energy for
production
of ATP
Excited
electrons
In Photosystem I
Excited
electrons
Light
In Photosystem II
(b) Noncyclic photophosphorylation

39. Metabolic Pathways of Energy Production

40. Carbohydrate Catabolism
The breakdown of carbohydrates to release energy
Glycolysis
Krebs cycle
Electron transport chain

41. Glycolysis
The oxidation of glucose to pyruvic acid produces ATP and NADH

42. respiration fermentation
Figure 5.11 An Overview of Respiration and Fermentation.
respiration
fermentation
Glycolysis produces ATP and reduces NAD+ to NADH while oxidizing glucose to pyruvic acid. In respiration, the pyruvic acid is converted to the first reactant in the Krebs cycle, acetyl CoA. 1
Glycolysis
Glucose
NADH
ATP
The Krebs cycle produces some ATP by substrate-level phosphorylation, reduces the electron carriers NAD+ and FAD, and gives off CO2. Carriers from both glycolysis and the Krebs cycle donate electrons to the electron transport chain.
Pyruvic acid
In fermentation, the pyruvic acid and the electrons carried by NADH from glycolysis are incorporated into fermentation end-products. 2
Acetyl CoA
Pyruvic acid
(or derivative)
NADH
NADH
Kreb’s
brewer’s yeast
FADH2
cycle
Formation of
fermentation
end-products
In the electron transport
chain, the energy of the
electrons is used to
produce a great deal of
ATP by oxidative
phosphorylation.
NADH &
FADH2
CO2
ATP 3
Electrons
ATP
Electron
transport
chain and
chemiosmosis O2
H2O

43. Preparatory Stage of Glycolysis
2 ATP are used
Glucose is split to form 2 glycerol-3-phosphate

44. Figure 5.12 An outline of the reactions of glycolysis (Embden-Meyerhof pathway).
Glucose enters the cell and is phosphorylated. A
molecule of ATP is invested. The product is glucose 6-phosphate. 1
Glucose 6-phosphate
2 Glucose 6-phosphate is rearranged to form fructose 6-phosphate. 2
Fructose 6-phosphate
The from another ATP is used to produce fructose 1,6-diphosphate, still a six-carbon compound. (Note the total investment of two ATP molecules up to this point.) 3 P
Fructose 1,6-diphosphate
An enzyme cleaves (splits) the sugar into two three-carbon molecules: dihydroxyacetone phosphate (DHAP) and glyceraldehyde 3-phosphate (GP). 4
Glyceraldehyde 3-phosphate (GP) 5
DHAP is readily converted to GP (the reverse action may also occur).
The next enzyme converts each GP to another three-carbon compound, 1,3-diphosphoglyceric acid. Because each DHAP molecule can be converted to GP and each GP to 1,3-diphosphoglyceric acid, the result is two molecules of 1,3-diphosphoglyceric acid for each initial molecule of glucose. GP is oxidized by the transfer of two hydrogen atoms to NAD+ to form NADH. The enzyme couples this reaction with the creation of a high-energy bond between the sugar and a The three-carbon sugar now has two groups. 6
1,3-diphosphoglyceric acid P P
3-phosphoglyceric acid
The high-energy is moved to ADP, forming ATP, the first ATP production of glycolysis. (Since the sugar splitting in step 4, all products are doubled. Therefore, this step actually repays the earlier investment of two ATP molecules.) 7 P
2-phosphoglyceric acid
An enzyme relocates the remaining of 3-phosphoglyceric acid to form 2-phosphoglyceric acid in preparation for the next step. 8 P
Phosphoenolpyruvic acid (PEP)
By the loss of a water molecule, 2-phosphoglyceric acid is converted to phosphoenolpyruvic acid (PEP). In the process, the phosphate bond is upgraded to a high-energy bond. 9
This high-energy is transferred from PEP to ADP, forming ATP. For each initial glucose molecule, the result of this step is two molecules of ATP and two molecules of a three-carbon compound called pyruvic acid. 10 P

45. Energy-Conserving Stage of Glycolysis
2 glycerol-3-phosphate are oxidized to 2 pyruvic acid
4 ATP are produced
2 NADH are produced

46. Alternatives to Glycolysis
Pentose phosphate pathway
Uses pentoses and NADPH
Operates with glycolysis
Entner-Doudoroff pathway
Produces NADPH and ATP
Does not involve glycolysis
Pseudomonas, Rhizobium, Agrobacterium

47. Cellular Respiration
Oxidation of molecules liberates electrons for an electron transport chain
ATP is generated by oxidative phosphorylation

48. Intermediate Step
Pyruvic acid (from glycolysis) is oxidized and decarboxylated

49. Figure 5.13 The Krebs cycle.
A turn of the cycle begins as enzymes strip off the CoA portion from acetyl CoA and combine the remaining two-carbon acetyl group with oxaloacetic acid. Adding the acetyl group produces the six-carbon molecule citric acid. 1
– Oxidations generate
NADH. Step 2 is a rearrangement. Steps 3 and 4 combine oxidations and decarboxylations to dispose of two carbon atoms that came from oxaloacetic acid. The carbons are released as CO2, and the oxidations generate NADH from NAD+. During the second oxidation (step 4), CoA is added into the cycle, forming the compound succinyl CoA.
– Enzymes rearrange chemical bonds, producing three different molecules before regenerating oxaloacetic acid. In step 6, an oxidation produces FADH2. In step 8, a final oxidation generates NADH and converts malic acid to oxaloacetic acid, which is ready to enter another round of the Krebs cycle. 2 4 6 8
ATP is produced by substrate-level phosphorylation. CoA is removed from succinyl CoA, leaving succinic acid. 5

50. The Electron Transport Chain
A series of carrier molecules that are, in turn, oxidized and reduced as electrons are passed down the chain
Energy released can be used to produce ATP by chemiosmosis
ANIMATION Electron Transport Chain: Overview

51. Figure 5.14 An electron transport chain (system).
Flow of electrons
Energy

52. respiration fermentation
Figure 5.11 An Overview of Respiration and Fermentation.
respiration
fermentation
Glycolysis produces ATP and reduces NAD+ to NADH while oxidizing glucose to pyruvic acid. In respiration, the pyruvic acid is converted to the first reactant in the Krebs cycle, acetyl CoA. 1
Glycolysis
Glucose
NADH
ATP
The Krebs cycle produces some ATP by substrate-level phosphorylation, reduces the electron carriers NAD+ and FAD, and gives off CO2. Carriers from both glycolysis and the Krebs cycle donate electrons to the electron transport chain.
Pyruvic acid
In fermentation, the pyruvic acid and the electrons carried by NADH from glycolysis are incorporated into fermentation end-products. 2
Acetyl CoA
Pyruvic acid
(or derivative)
NADH
NADH
Kreb’s
brewer’s yeast
FADH2
cycle
Formation of
fermentation
end-products
In the electron transport
chain, the energy of the
electrons is used to
produce a great deal of
ATP by oxidative
phosphorylation.
NADH &
FADH2
CO2
ATP 3
Electrons
ATP
Electron
transport
chain and
chemiosmosis O2
H2O

53. Figure 5.16 Electron transport and the chemiosmotic generation of ATP.
Cell
wall
Periplasmic space
Plasma membrane
Outer membrane
Inner membrane
Intermembrane space
Mitochondrial matrix
Cytoplasm
Bacterium
Mitochondrion
Periplasmic space of prokaryote or intermembrane space of eukaryote
Prokaryotic
plasma
membrane
or eukaryotic
inner mitochondrial membrane
Cytoplasm of
prokaryote or
mitochondrial
matrix of
eukaryote

54. Figure 5.15 Chemiosmosis. High H+ concentration Low H+ concentration
Membrane
Low H+ concentration

55. A Summary of Respiration
Aerobic respiration: the final electron acceptor in the electron transport chain is molecular oxygen (O2)
Anaerobic respiration: the final electron acceptor in the electron transport chain is NOT O2
Yields less energy than aerobic respiration because only part of the Krebs cycle operates under anaerobic conditions

56. Anaerobic Respiration
Electron Acceptor
Products
NO3–
NO2–, N2 + H2O
SO4–
H2S + H2O
CO32 –
CH4 + H2O

57. Carbohydrate Catabolism
Pathway
Eukaryote
Prokaryote
Glycolysis
Cytoplasm
Intermediate step
Krebs cycle
Mitochondrial matrix
ETC
Mitochondrial inner membrane
Plasma membrane

58. Carbohydrate Catabolism
Energy produced from complete oxidation of one glucose using aerobic respiration
Pathway
ATP Produced
NADH Produced
FADH2 Produced
Glycolysis 2
Intermediate step
Krebs cycle 6
Total 4 10

59. Carbohydrate Catabolism
ATP produced from complete oxidation of one glucose using aerobic respiration
Pathway
By Substrate-Level Phosphorylation
By Oxidative Phosphorylation
From NADH
From FADH
Glycolysis 2 6
Intermediate step
Krebs cycle 18 4
Total 30

60. Carbohydrate Catabolism
36 ATPs are produced in eukaryotes
Pathway
By Substrate-Level Phosphorylation
By Oxidative Phosphorylation
From NADH
From FADH
Glycolysis 2 6
Intermediate step
Krebs cycle 18 4
Total 30

61. Fermentation Any spoilage of food by microorganisms (general use)
Any process that produces alcoholic beverages or acidic dairy products (general use)
Any large-scale microbial process occurring with or without air (common definition used in industry)

62. Fermentation Scientific definition:
Releases energy from oxidation of organic molecules
Does not require oxygen
Does not use the Krebs cycle or ETC
Uses an organic molecule as the final electron acceptor

63. Figure 5.18a Fermentation.

64. Figure 5.18b Fermentation.

65. Fermentation Alcohol fermentation: produces ethanol + CO2
Lactic acid fermentation: produces lactic acid
Homolactic fermentation: produces lactic acid only
Heterolactic fermentation: produces lactic acid and other compounds

66. (a) Lactic acid fermentation
Figure 5.19 Types of fermentation.
(a) Lactic acid fermentation
(b) Alcohol fermentation

67. Figure 5.23 A fermentation test.

68. Table 5.4 Some Industrial Uses for Different Types of Fermentations*

69. Figure 5.20 Lipid catabolism.
Lipase
Beta-oxidation
Krebs
cycle

70. Figure 5.21 Catabolism of various organic food molecules.
Krebs
cycle
Electron
transport
chain and
chemiosmosis

71. Protein Catabolism Protein Amino acids Krebs cycle Organic acid
Extracellular proteases
Krebs cycle
Deamination, decarboxylation, dehydrogenation, desulfurization
Organic acid

72. Figure 5.22 Detecting amino acid catabolizing enzymes in the lab.

73. Figure 5.24 Use of peptone iron agar to detect the production of H2S.

74. Protein Catabolism
Urease
NH3 + CO2
Urea

75. Figure B The urease test.
Clinical Focus: Human Tuberculosis – Dallas, Texas
Figure B The urease test.

76. Biochemical Tests
Used to identify bacteria

77. Clinical Focus: Human Tuberculosis – Dallas, Texas
Figure A An identification scheme for selected species of slow-growing mycobacteria.

78. Photosynthesis
Photo: conversion of light energy into chemical energy (ATP)
Light-dependent (light) reactions
Synthesis:
Carbon fixation: fixing carbon into organic molecules
Light-independent (dark) reaction: Calvin-Benson cycle
ANIMATION Photosynthesis: Overview

79. Chromatophores Figure 4.15 Chromatophores.
© 2013 Pearson Education, Inc.

80. Photosynthesis Oxygenic: Anoxygenic:
ANIMATION: Photosynthesis: Comparing Prokaryotes and Eukaryotes

81. (a) Cyclic photophosphorylation
Figure 5.25a Photophosphorylation.
Electron
transport
chain
Energy for
production
of ATP
Light
Excited
electrons
Electron carrier
In Photosystem I
(a) Cyclic photophosphorylation

82. (b) Noncyclic photophosphorylation
Figure 5.25b Photophosphorylation.
Electron
transport
chain
Light
Energy for
production
of ATP
Excited
electrons
In Photosystem I
Light
Excited
electrons
In Photosystem II
H+ + H+ 1 2
(b) Noncyclic photophosphorylation

83. Figure 5.26 A simplified version of the Calvin-Benson cycle.
Input
Ribulose diphosphate
3-phosphoglyceric acid
1,3-diphosphoglyceric acid
Calvin-Benson cycle
Glyceraldehyde
3-phosphate
Glyceraldehyde
3-phosphate
Output
Glyceraldehyde 3-phosphate
Glyceraldehyde 3-phosphate

84. Table 5.6 Photosynthesis Compared in Selected Eukaryotes and Prokaryotes

85. Chemotrophs Use energy from chemicals Chemoheterotroph
Energy is used in anabolism
Glucose
NAD+
ETC
Pyruvic acid
NADH
ADP + P
ATP

86. Chemotrophs Use energy from chemicals
Chemoautotroph, Thiobacillus ferrooxidans
Energy is used in the Calvin-Benson cycle to fix CO2
2Fe2+
NAD+
ETC
2Fe3+
NADH
ADP + P
ATP
2 H+

87. Phototrophs Use light energy
Photoautotrophs use energy in the Calvin-Benson cycle to fix CO2
Photoheterotrophs use energy
Chlorophyll
Chlorophyll oxidized
ETC
ADP + P
ATP

88. Figure 5.27 Requirements of ATP production.

89. Figure 5.28 A nutritional classification of organisms.
Chemical
Light
Organic compounds
CO2
Organic compounds
CO2 O2
Not O2
Yes No
Organic
compound
Inorganic
compound

90. Metabolic Diversity among Organisms
Nutritional Type
Energy Source
Carbon Source
Example
Photoautotroph
Light
CO2
Oxygenic: Cyanobacteria, plants
Anoxygenic: Green bacteria, purple bacteria
Photoheterotroph
Organic compounds
Green bacteria, purple nonsulfur bacteria
Chemoautotroph
Chemical
Iron-oxidizing bacteria
Chemoheterotroph
Fermentative bacteria
Animals, protozoa, fungi, bacteria

91. Figure 5.29 The biosynthesis of polysaccharides.
Glycogen
(in bacteria)
Glycogen
(in animals)
Peptidoglycan
(in bacteria)

92. Figure 5.30 The biosynthesis of simple lipids.
Krebs
cycle

93. Amination or transamination
Figure 5.31a The biosynthesis of amino acids.
Krebs
cycle
Amination or transamination
Amino acid biosynthesis

94. Transamination Oxaloacetic acid α-Ketoglutaric acid Aspartic acid
Figure 5.31b The biosynthesis of amino acids.
Transamination
Glutamic acid
Oxaloacetic
acid
α-Ketoglutaric
acid
Aspartic acid
Process of transamination

95. Figure 5.32 The biosynthesis of purine and pyrimidine nucleotides.
Krebs
cycle

96. The Integration of Metabolism
Amphibolic pathways: metabolic pathways that have both catabolic and anabolic functions

97. Figure 5.33 The integration of metabolism.
Krebs cycle
CO2