1. Transformation of Energy
Section 1
Cellular Energy
How Organisms Obtain Energy – Chapter 8
Transformation of Energy
Energy is the ability to do work.
Thermodynamics is the study of the flow and transformation of energy in the universe.

2. Laws of Thermodynamics
Section 1
Cellular Energy
How Organisms Obtain Energy
Laws of Thermodynamics
First law—energy can be converted from one form to another, but it cannot be created nor destroyed.
Second law—energy cannot be converted without the loss of usable energy.

3. Autotrophs vs. Heterotrophs
Section 1
Autotrophs vs. Heterotrophs
Use light energy from sun to make own food
Obtain energy from other organisms
ALL ORGANISMS NEED ENERGY TO CARRY OUT LIFE FUNCTIONS AND MUST RELEASE ENERGY FROM SUGARS AND OTHER COMPOUNDS!!

4. Metabolism - all of the chemical reactions in a cell
Section 1
Cellular Energy
How Organisms Obtain Energy
Metabolism - all of the chemical reactions in a cell
Two types of metabolic pathways
1. Anabolic – Take in energy to build large molecules
2. Catabolic – Release energy when breaking down large molecules

5. Photosynthesis—light energy from the Sun is converted to chemical energy for use by the cell
Cellular respiration—organic molecules are broken down to release energy for use by the cell

6. Adenosine Triphosphate (ATP)
One of principal chemical compounds that cells use to store and release energy
Adenine
3 Phosphate groups
Ribose
(5-carbon sugar)

7. ATP How is energy stored and released?
ADP
Energy
Energy
Adenosine Triphosphate (ATP)
Adenosine Diphosphate (ADP) + Phosphate
Partially charged battery
Fully charged battery
What is ATP used for in the cell?

8. Process of turning light energy from the sun into chemical energy
Photosynthesis
Process of turning light energy from the sun into chemical energy

9. Overview of Photosynthesis
Section 2
Cellular Energy
Photosynthesis
Overview of Photosynthesis
Photosynthesis occurs in two phases.
Light-dependent reactions
Light-independent reactions or the Calvin Cycle.

10. Photosynthesis: Overview
CO2
Light
NADP+
ADP + P
Light- dependent reactions
Calvin Cycle
Calvin cycle
Chloroplast O2
Sugars

11. Photosynthesis: Overview
LIGHT-DEPENDENT REACTIONS
Require light / use energy from light to produce oxygen gas and convert ADP and NADP+ into the energy carriers ATP and NADPH
CALVIN CYCLE
Does NOT require light / uses ATP and NADPH from light-dependent reactions to produce high-energy sugars that can be stored for a long time

12. Electron Carriers
When a potato is very hot, you wouldn’t dare grab it with your bare hand, rather you use an oven mitt to carry the potato. As the potato cools, you no longer need the oven mitt.
This is similar to an electron carrier. Once an electron receives energy from the sun, it is considered a “high-energy electron.” The electron does not travel on its own from place to place. Another substance (in this case NADP) carries the electron to its destination. As the electron loses it’s high energy levels, it no longer needs an electron carrier.
An electron carrier then is “a compound that can accept a pair of high-energy electrons and transfer them, along with most of their energy, to another molecule.”

13. Light-Dependent Reactions
ATP synthase
+ O2
2H2O
ADP
2 NADP+ 2 2
NADPH

14. 5-Carbon Molecules Regenerated
Calvin Cycle 12
12 ADP
6 ADP 12
NADPH 6
12 NADP+
5-Carbon Molecules Regenerated

15. Section 2
Cellular Energy
Photosynthesis
Electron Transport
Light energy excites electrons in the photosystems and also causes a water molecule to split, releasing an electron and O2 is released as a waste product.

16. Phase Two: The Calvin Cycle
Section 2
Cellular Energy
Photosynthesis
Phase Two: The Calvin Cycle
In the second phase of photosynthesis, called the Calvin cycle, energy is stored in organic molecules such as glucose.

17. CO2 molecules combine with a 6 carbon molecule with an enzyme.
Section 2
Cellular Energy
Photosynthesis
CO2 molecules combine with a 6 carbon molecule with an enzyme.
The chemical energy stored in ATP and NADPH is transferred to make a glucose molecule.

18. Section 2
Cellular Energy
Photosynthesis
Alternative Pathways - in hot, dry environments plants have adapted to a different way to perform photosynthesis
C4 plants – are able to make glucose in different cells. Ex: Corn and sugarcane
CAM plants – are able to make glucose at different time of the day. Ex: Pineapples and cati

19. Overview of Cellular Respiration
Section 3
Cellular Energy
Cellular Respiration
Overview of Cellular Respiration
Organisms obtain energy in a process called cellular respiration.
The equation for cellular respiration is the opposite of the equation for photosynthesis.

20. Cellular respiration occurs in three main parts. Glycolysis
Section 3
Cellular Energy
Cellular Respiration
Cellular respiration occurs in three main parts.
Glycolysis
Krebs Cycle
Electron Transport

21. NET GAIN OF HOW MANY ATP MOLECULES?
Glycolysis
Process in which one molecule of glucose is broken in half, producing pyruvic acid and a small amount of energy in the cytoplasm
2 ATP
2 ADP
4 ADP
4 ATP
2NAD+
2 Pyruvic
acid 2
NET GAIN OF HOW MANY ATP MOLECULES?

22. Section 3
Cellular Energy
Cellular Respiration
Krebs Cycle
Most of the energy from the glucose is still contained in the pyruvate.
The series of reactions in which pyruvate is broken down into carbon dioxide is called the Krebs cycle.

23. The net yield from the Krebs cycle: 6 CO2 molecules 2 ATPs 8 NADH
Section 3
Cellular Energy
Cellular Respiration
The net yield from the Krebs cycle:
6 CO2 molecules
2 ATPs
8 NADH
2 FADH2

24. Krebs Cycle
CoA
CO2
NAD
NADH
ADP
ATP P
FAD
FADH2

25. Electron Transport Chain
Section 3
Cellular Energy
Cellular Respiration
Electron Transport Chain
Final step in the breakdown of glucose
Point at which ATP is produced
Produces about 24 ATP

26. Electron Transport Chain
Uses high-energy electrons from the Krebs Cycle to convert ADP into ATP
Channel
ATP synthase
ATP

27. Anaerobic Respiration
Section 3
Cellular Energy
Cellular Respiration
Anaerobic Respiration
The anaerobic pathway that follows glycolysis
Two main types
Lactic acid fermentation
Alcohol fermentation
Cellular Respiration

28. Releases energy from food by producing ATP in the absence of oxygen
Fermentation
Releases energy from food by producing ATP in the absence of oxygen
WHY IS THIS IMPORTANT TO CELLS?

29. Two Types of Fermentation
ALCOHOLIC
Used by yeasts and microorganisms, producing alcohol and carbon dioxide (as well as NAD+)
NO OXYGEN! NAD+ PRODUCED FOR BOTH!
LACTIC ACID
Conversion of pyruvic acid into lactic acid (as well as NAD+)

30. Chapter Resource Menu Chapter Diagnostic Questions
Cellular Energy
Chapter Resource Menu
Chapter Diagnostic Questions
Formative Test Questions
Chapter Assessment Questions
Standardized Test Practice
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Glencoe Biology Transparencies
Image Bank
Vocabulary
Animation
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31. Which statement describes the law of conservation of energy?
Chapter
Cellular Energy
Chapter Diagnostic Questions
Which statement describes the law of
conservation of energy?
Energy cannot be converted or destroyed.
Energy can be converted and destroyed.
Energy can be converted but not destroyed.
Energy can be destroyed but not converted. A B C D
CDQ 1

32. In which metabolic process are molecules
Chapter
Cellular Energy
Chapter Diagnostic Questions
In which metabolic process are molecules
broken down to produce carbon dioxide and
water?
photosynthesis
cellular respiration
homeostasis
fermentation A B C D
CDQ 2

33. At the end of the Calvin cycle, where is energy stored?
Chapter
Cellular Energy
Chapter Diagnostic Questions
At the end of the Calvin cycle, where is energy
stored?
NADPH
ATP
chloroplast
glucose A B C D
CDQ 3

34. Chapter
Cellular Energy
Section 1 Formative Questions
Which law of thermodynamics explains why the ladybug receives the least amount of usable energy? A B
the first law of thermodynamics
the second law of thermodynamics
FQ 1

35. All of the energy from the food you eat comes from the sun.
Chapter
Cellular Energy
Section 1 Formative Questions
All of the energy from the food you eat comes from the sun.
true
false A B
FQ 2

36. Why is cellular respiration a catabolic pathway?
Chapter
Cellular Energy
Section 1 Formative Questions
Why is cellular respiration a catabolic pathway?
Energy is used to form glucose and oxygen.
Energy is converted from water to carbon dioxide.
Energy that is lost is converted to thermal energy.
Energy is released by the breakdown of molecules. A B C D
FQ 3

37. Why is adenosine triphosphate (ATP) such an
Chapter
Cellular Energy
Section 1 Formative Questions
Why is adenosine triphosphate (ATP) such an
important biological molecule?
It captures light energy from the sun.
It is produced in anabolic pathways.
It stores and releases chemical energy.
It converts mechanical energy to thermal energy. A B C D
FQ 4

38. Where in the plant cell does photosynthesis take place?
Chapter
Cellular Energy
Section 2 Formative Questions
Where in the plant cell does photosynthesis take place?
chloroplasts
Golgi apparatus
mitochondria
vacuoles A B C D
FQ 5

39. Which range of wavelengths is reflected by chlorophylls a and b?
Chapter
Cellular Energy
Section 2 Formative Questions
Which range of wavelengths is reflected by chlorophylls a and b? nm nm nm A B C
FQ 6

40. Which mechanism of photosynthesis uses
Chapter
Cellular Energy
Section 2 Formative Questions
Which mechanism of photosynthesis uses
the movement of hydrogen ions (H+) across
a concentration gradient to synthesize ATP?
absorption
chemiosmosis
electron transport
C2 pathway A B C D
FQ 7

41. How are the C4 pathway and the CAM pathway
Chapter
Cellular Energy
Section 2 Formative Questions
How are the C4 pathway and the CAM pathway
an adaptive strategy for some plants?
They accelerate photosynthesis.
They release more oxygen.
They help the plant conserve water.
They reduce the requirement for ATP. A B C D
FQ 8

42. What is the overall purpose of cellular respiration?
Chapter
Cellular Energy
Section 3 Formative Questions
What is the overall purpose of cellular
respiration?
to make ATP
to process H2O
to store glucose
to deliver oxygen A B C D
FQ 9

43. Which represents the general sequence of cellular respiration?
Chapter
Cellular Energy
Section 3 Formative Questions
Which represents the general sequence of
cellular respiration?
TCA cycle  chemiosmosis  glycolysis
glycolysis  Krebs cycle  electron transport
electron absorption  catalysis  phosphorylation
aerobic pathway  anaerobic pathway  fermentation A B C D
FQ 10

44. Which stage of cellular respiration is the anaerobic process?
Chapter
Cellular Energy
Section 3 Formative Questions
Which stage of cellular respiration is the
anaerobic process?
glycolysis
Krebs cycle
electron transport A B C
FQ 11

45. CoA CO2 FADH2 NADH Which molecule generated by the Krebs
Chapter
Cellular Energy
Section 3 Formative Questions
Which molecule generated by the Krebs
cycle is a waste product?
CoA
CO2
FADH2
NADH A B C D
FQ 12

46. Chapter
Cellular Energy
Chapter Assessment Questions
Look at the following figure. Which part of the chloroplast is a sac-like membrane arranged in stacks?
grana
stroma
thylakoids
Golgi apparatus A B C D
CAQ 1

47. pyruvate is broken down into what compound?
Chapter
Cellular Energy
Chapter Assessment Questions
During the Krebs cycle,
pyruvate is broken down
into what compound?
H2O O2 CO
CO2 A B C D
CAQ 2

48. Chapter
Cellular Energy
Chapter Assessment Questions
Look at the following figure. Which molecule is released when ATP becomes ADP?
phosphate group
water molecule
ribose sugar
energy cells A B C D
CAQ 3

49. A B Which metabolic process is photosynthesis?
Chapter
Cellular Energy
Standardized Test Practice
Which metabolic process is photosynthesis? A B A B
STP 1

50. At the beginning of photosynthesis, which
Chapter
Cellular Energy
Standardized Test Practice
At the beginning of photosynthesis, which
molecule is split to produce oxygen (O2) as
a waste product?
CO2
H2O
C6H12O6
3-PGA A B C D
STP 2

51. Which molecule helps provide the energy that drives this cycle?
Chapter
Cellular Energy
Standardized Test Practice
Which molecule helps provide the energy that drives this cycle?
3-PGA
CO2
NADPH
rubisco A B C D
STP 3

52. Which product of the Calvin cycle is used for
Chapter
Cellular Energy
Standardized Test Practice
Which product of the Calvin cycle is used for
the production of glucose and other organic compounds?
ADP
CO2
G3P
NADP+ A B C D
STP 4

53. What is the final step of cellular respiration?
Chapter
Cellular Energy
Standardized Test Practice
What is the final step of cellular respiration?
O2 and H+ form H2O.
Electrons and H2O generate ATP.
C6H12O6 is broken down into CO2.
NADH and FADH2 gain electrons. A B C D
STP 5

54. an increased demand for ATP
Chapter
Cellular Energy
Standardized Test Practice
What prevents pyruvate from entering the Krebs cycle and instead results in this pathway?
a buildup of CO2
a lack of oxygen
an excess of glucose
an increased demand for ATP A B C D
STP 6

55. Which is not a process that occurs in both
Chapter
Cellular Energy
Standardized Test Practice
Which is not a process that occurs in both
cellular respiration and glycolysis?
chemiosmosis
electron transport
glycolysis
production of G3P A B C D
STP 7

56. Glencoe Biology Transparencies
Chapter
Cellular Energy
Glencoe Biology Transparencies

57. Chapter
Cellular Energy
Image Bank

58. Section 1 Vocabulary energy thermodynamics metabolism Photosynthesis
Cellular Energy
Vocabulary
Section 1
energy
thermodynamics
metabolism
Photosynthesis
cellular respiration
adenosine triphosphate (ATP)

59. Section 2 Vocabulary thylakoid granum stroma pigment NADP+
Cellular Energy
Vocabulary
Section 2
thylakoid
granum
stroma
pigment
NADP+
Calvin cycle
rubisco

60. Section 3 Vocabulary anaerobic process aerobic respiration
Cellular Energy
Vocabulary
Section 3
anaerobic process
aerobic respiration
aerobic process
glycolysis
Krebs cycle
fermentation

61. Visualizing Electron Transport The Krebs Cycle (Citric Acid Cycle)
Chapter
Cellular Energy
Animation
ATP
The Calvin Cycle
Visualizing Electron Transport
The Krebs Cycle (Citric Acid Cycle)

62. Chapter
Cellular Energy

63. Chapter
Cellular Energy

64. Chapter
Cellular Energy