1. ATP, Photosynthesis & Cellular Respiration1

2. Living things need energy to survive and function. 2
Living things need energy to survive and function.
You get the energy you need from the food you eat.
Where does that energy come from?
Sun  Plants  You !!!

3. You must eat food to get energy (you are a heterotroph).
When you breakdown your food you store the energy in the bonds of ATP.
Plants can make their own food (they are autotrophs).
Plants store sunlight energy in the chemical bonds of glucose (a carbohydrate).
ATP 3
glucose

4. ATP: Energy Storage WHAT IS ATP? 4 Universal Energy Molecule
The cell’s “Energy Bank”
Adenosine Triphosphate (ATP)
Consist of
a sugar called ribose
N containing Adenine
Three phosphate groups

5. 5
ATP
Adenine
Ribose
3 Phosphate groups

6. When the energy is used the ATP is converted into ADP6 P P
ADP
ATP
Partially
charged
battery
Fully
charged
battery
The Bonds between the phosphate groups in ATP are VERY HIGH ENERGY.
When a phosphate group is removed-energy is released
CLIP

7. Using ATP in Active Transport Animation7
Using ATP in Active Transport Animation

8. ATP Cell can make ATP from ADP by using the energy from carbohydrates.8
Cell can make ATP from ADP by using the energy from carbohydrates.
This means that the energy in carbohydrates is then stored in ATP until needed by cells.
Breaking down Carbohydrates releases energy
ADP
ATP
Energy from the Carbohydrates is stored in ATP!!!

9. 9
. ATP is the major energy link between energy-using and energy releasing reactions.
CLIP

10. Trapping Energy 10
glucose
Clip

11. Plants store sunlight energy in Glucose!
Photosynthesis is the process by which plants: 11
Use
sunlight, carbon dioxide & water
Produce
high energy carbohydrates such as sugars (glucose) &starches.
Plants store sunlight energy in Glucose!

12. Where does photosynthesis take place?12

13. Leaf Structure The leaves of plants: a.stomata b.cells CO2 13
Photosynthesis Location:
The leaves of plants:
a.stomata
b.cells
Cell
Chloroplast
Stomata
Goes in
CO2

14. The Internal Structure of a Leaf14
The Internal Structure of a Leaf
Section 23-4
CO2 enters through the stomata
Epidermis
Chloroplasts
Stomata
Goes in
Guard cells
CO2

15. Chloroplasts are only found in photosynthetic, eukaryotic cells.
Chloroplast Structure
Chloroplasts are only found in photosynthetic, eukaryotic cells. 15
Using the energy from the sunlight, chloroplasts
are able to form ATP as well as synthesizing sugars from H20 & CO2.

16. Chloroplast Structure16
Organelle where photosynthesis takes place.
Stroma
Outer Membrane
Thylakoid
Inner Membrane

18. Chloroplast Structure
Chloroplast Picture 17

19. Things to know about Chloroplasts
Have a double membrane the inner membrane the outer membrane
Have their own DNA this carries the information to make the enzymes
18.1

20. Things to know about Chloroplasts
Have a double membrane the inner membrane the outer membrane
Have their own DNA this carries the information to make the enzymes
Have their own ribosomes more like the ribosomes of prokaryotes than eukaryotes make their own enzymes required for photosynthesis require carbon dioxide and water produce glucose
Contain chlorophyll this green chemical (pigment) "traps" sunlight energy
Pigments are molecules that absorb light energy
18.2

21. 19 Plants absorb certain wavelengths of light. Blue and Red.
Pigments are molecules that absorb light.
Main pigment is Chlorophyll.
When they absorb light, they are absorbing Energy. b a 19

22. Photosynthesis: Products &Reactants20
Photosynthesis: Products &Reactants
SUN
SUN
Light Energy
Chloroplast
CO2 + H2O
Glucose & O2

23. Formula For Photosynthesis
6 _____ ______ __________
______ + ______
Reactants
Products 21

24. Photosynthesis Takes Place in 2 Steps.22

25. Step 1: Light Dependent Reaction. Energy captured from Sunlight.
The light reaction is the photo part of photosynthesis.
Step 1: Light Dependent Reaction.
Energy captured from Sunlight. 
H2O is split into H+, electrons, & Oxygen (O2). 
The O2 diffuses out of the Chloroplasts.
MADE: O2 , ATP & NADPH.
Takes place: Thylakoid 23

26. This process is known as carbon fixation.
The Calvin cycle is the synthesis part of photosynthesis. 24
Step 2: Light Independent
Reaction (CALVIN CYCLE).
The Chemical Energy Stored in ATP and NADPH is used to make Glucose using CO2.
This is a light independent reaction.
MADE: Glucose
Takes place: Stroma
Sunlight
Water
ATP
NADPH
Oxygen
Step 1:
Light Dependent Reaction
This process is known as carbon fixation.

27. 25 Photosynthesis: An Overview LIGHT REACTION
DARK REACTION-Light Independent
Section 8-3
Thylakoid Membrane
Stroma
Water O2
Sugars
CO2
SUNLIGHT
Chloroplast
Chloroplast
NADP+
ADP + P
Light-
Dependent
Reactions
Calvin
Cycle
ATP
NADPH
Go to Section: 25

28. Light dependent Reaction Dark Reaction/ Calvin Cycle
6CO2 + 6H2O + energy from sunlight → C6H12O6 + 6O2
Photosynthesis
Occurs in two Steps
Light dependent Reaction
Dark Reaction/ Calvin Cycle
Occurs (location)
Occurs (location)
Produces
Produces
Oxygen
ATP
NADPH
Thylakoid Membrane
Stroma
Glucose 26

29. PLANTS STORE ENERGY FROM THE SUN IN THE BONDS OF GLUCOSE !!!!
CLIP 27

30. Where does each reactant enter the plant???28

31. Once plants use light energy to form carbohydrates, other organisms, called Heterotrophs, can then use this carbohydrate energy for their own life processes.
One way carbohydrate energy is used by organisms is through the process of cellular respiration.
Sun  Plants  You!! 29

32. Major Concept
How it’s all connected.

33. Cellular Respiration 30

34. Breaking down food for energy.
Cellular Respiration
Process that occurs in cells in which cells break down Glucose for ENERGY!
Occurs in cytoplasm and Mitochondria. 
Breaking down food for energy. 31

35. Cellular Respiration Overview:
Plants are producers and make glucose by the process of photosynthesis.
Heterotrophs breakdown glucose for energy.
There are two important ways a cell can harvest energy from food: fermentation and cellular respiration. 36
Breaking down food for energy. 32

36. Cellular Respiration Takes Place in 3 Steps.
Step 1: Glycolysis
Step 2: Krebs Cycle Step 3: Electron Transport 33

37. Glycolysis does not need oxygen!
Step 1: Glycolysis 34
Means “Splitting Glucose”
Glycolysis starts with Glucose.
Glucose is broken down into 2 molecules called Pyruvate (aka pyruvic acid ).
Happens in the Cytoplasm.
Clip
Glycolysis does not need oxygen!

38. Mitochondria Anatomy 35 2 membranes
Steps 2 & 3 Occur in the Mitochondria
Mitochondria Anatomy
2 membranes
Own ribosomes
Own DNA 35

40. In the presence of Oxygen: Step 2: Krebs Cycle Step 3: Electron Transport36
Happens in the Mitochondria
Starts with Pyruvate.
Pyruvate moves into the mitochondria and is broken down into CO2,H2O & ATP.

41. 37

42. Cellular Respiration Review38
With oxygen
Glucose
Krebs cycle
Electron transport
Glycolysis
Alcohol or lactic acid
Fermentation (without oxygen) 36
Go to Section:

43. Breaking down glucose without oxygen39
Glucose
Krebs cycle
Electron transport
Glycolysis
With out oxygen
Alcohol or lactic acid
Fermentation (without oxygen)
Ethanol and Carbon Dioxide
Go to Section:
Pyruvic Acid
Lactic Acid

44. Fermentation 40
Without oxygen: Pyruvate is converted into Lactic Acid or Alcohol during Fermentation.
Lactic Acid- Muscle cells
Alcohol- Yeast

45. 41 In the presence of oxygen: 1 Glucose is converted into 36 ATP.
Without oxygen:
1 Glucose is converted into 2 ATP.
C6H12O6 + 6 O2 => 6 CO2 + 6 H2O + 36 ATP

46. 42

47. Photosynthesis vs. Respiration43
Photosynthesis
Respiration
produces food
stores energy
Uses H2O
uses CO2
releases O2
occurs in sunlight
uses food
releases energy
Produces H2O
produces CO2
uses O2
occurs in the dark as well as light

48. 44
Energy Converters video. Click picture.