Lecture 7: Capturing and Using Energy PDF

Summary

This document presents lecture notes on the topic of capturing and using energy, covering photosynthesis, aerobic respiration, and anaerobic respiration. It details the processes involved, including important concepts like light-dependent and light-independent reactions.

Full Transcript

Lecture 7: Capturing and Using Energy
 Today
Photosynthesis
– Sunlight and pigments
– Chemical reactions
– Photosynthetic pathways

Aerobic respiration
– Chemical reactions

Anaerobic respiration (fermentation)
 Energy Acquisition

 Define “food” according to what we’ve learned so far.
 Energy Acquisition

Autotrophs (producers)
– Produce organic compounds from CO2

– Photoautotrophs –
sunlight as energy source
Plants
Some bacteria
Some protists
 Energy Acquisition

Heterotrophs (consumers)
– Consume organic compounds originally made by autotrophs
 Sunlight and Pigments
Light contains energy
– Photons – packets of light energy
– Photons travel in waves according to their energy

Higher energy, shorter wavelength

Lower energy, longer wavelength
 Sunlight and Pigments
Pigments – light-absorbing molecules
– Only absorb specific wavelengths
– Reflected wavelengths seen as color

 Is the entire
spectrum of visible
light used for
photosynthesis?
 Sunlight and Pigments
Chlorophylls
– Main pigments used by photoautotrophs
– Chlorophyll a and chlorophyll b
 Sunlight and Pigments
Beta-carotene

Carotenoids CH3
CH3
– Found in all photoautotrophs CH3

 What color do carotenoids appear? CH3

CH3

CH3

CH3
CH3
CH3
CH3
 Sunlight and Pigments
Plants use a variety of pigments to absorb light
 What is the advantage of using
multiple pigments?
 Photosynthesis

Energy from sunlight used to Sunlight
synthesize sugar from CO2

Oxygen

Provides most biologically Carbon
dioxide
available energy on Earth
Water
 Photosynthesis

Photosynthesis occurs in leaf mesophyll cells
leaf’s upper surface photosynthetic cells

central vacuole

mesophyll

chloroplast

photosynthetic cell

vein stoma (gap) in lower surface
leaf cross section

Stomata
 Photosynthesis

Inside the chloroplast:
– Stroma – semifluid interior
– Thylakoid membrane – folded, stacked inner membrane

two outer membranes  How did chloroplasts
evolve?
inner
thylakoid
membrane
system

stroma
 Photosynthesis

Inside the chloroplast:
– Photosystems – clusters of pigments and proteins
embedded in thylakoid membrane
– Capture light energy
light harvesting electron
complex transfer chain

PHOTOSYSTEM II PHOTOSYSTEM I

thylakoid thylakoid
membrane compartment
 Chemical Reactions of Photosynthesis

Two stages of photosynthesis:
sunlight H2O CO2
energy (water) (carbon dioxide)

ATP
1. light- 2.
light-
Capturing dependent
ADP + Pi independent Making
reactions
sunlight reactions sugar
NADPH
(photo) NADPH+
(synthesis)

glucose

O2 H2O (metabolic water)
 Chemical Reactions of Photosynthesis

Two stages of photosynthesis:

1. Light-dependent reactions – light energy captured and
stored in ATP & NADPH
– Occur at thylakoid membrane
– Electron transfer chains

2. Light-independent reactions – ATP & NADPH used to
convert CO2 into sugar
– Occur in stroma
– Calvin-Benson cycle
 Light-Dependent Reactions
Process:

– Pigments in photosystem absorb light energy

– Light energy causes photosystem to release electrons

– Electrons enter electron transfer chains on membrane

– Energy from electron transfer used to produce ATP &
NADPH
 Light-Dependent Reactions
Process:

light 8
1 light energy electron 5 energy electron
transfer 4 transfer
3 chain 6 chain ATP
synthase ADP,
photosystem phosphate

thylakoid 2
compartment H O
2
7

stroma
O2
 Light-Dependent Reactions
ATP formation by electron transfer phosphorylation:

– Energy from ETC used to actively transport H+ into
thylakoid compartment

– H+ concentration gradient forms

– H+ flows down gradient through ATP synthase

– Flow of H+ drives formation of ATP
 Light-Independent Reactions
Calvin-Benson Cycle:

– “Fixes” inorganic CO2
carbon (from CO2)
into glucose PGA
RuBP

Calvin ATP
– Uses ATP and ATP Cycle
NADPH NADPH

– Catalyzed by
rubisco sugars
 Light-Independent Reactions
Calvin-Benson Cycle:
6CO2
1 2 Intermediate
Rubisco adds
CO2 to RuBP compounds
(ribulose ATP (PGA and PGAL)
biphosphate) 6 RuBP 12 PGA form
12

6 ADP
Calvin-Benson 12 ADP +
ATP cycle 12 Pi

12 NADPH
Using ATP, RuBP 4 3 Using ATP and
is regenerated 4 Pi NADPH, PGAL is
12 NADP+
converted into
10 PGAL 12 PGAL
glucose
1 Pi

1 glucose-6-1-phosphate
 Photosynthesis Summary

sunlight

Light-
Dependent 12H2O 6O2
Reactions

ADP + Pi ATP NADPH NADP+

6CO2
Calvin-
6 RuBP Benson 12 PGAL
cycle
Light-
6H2O
Independent
Reactions
phosphorylated glucose

end products (e.g., sucrose, starch, cellulose)
 Photosynthetic Pathways
C3 photosynthesis
– CO2 captured by rubisco,
fixed into 3-C molecule

– Rubisco also catalyzes
photorespiration RuBP PGA

(consumes O2 and Calvin-
Benson
releases CO2) cycle

– Photorespiration is a
net energy loss sugar
 Photosynthetic Pathways
C4 photosynthesis
– CO2 fixed first in mesophyll
cell
mesophyll cells C4 oxaloacetate
cycle

– Moved to interior
bundle
bundle sheath cells CO2
sheath
for Calvin Cycle RuBP PGA
cell
Calvin-
Benson
– Reduces cycle
photorespiration
sugar
 Photosynthetic Pathways
CAM photosynthesis
CO2 uptake at night only
– CO2 taken up only at night,
stored until daytime
runs
C4
at
 Where is it stored? cycle
night

– Calvin Cycle proceeds
Calvin-
during daytime Benson
runs
during
cycle
day

 Benefit?
sugar
Photosynthetic Pathways

Spatial separation

C3 default
C4 reduces
photorespiration
CAM reduces
evaporation
Temporal separation
Photosynthetic Pathways
C3: 85% of global plant species,
tropical – temperate

CAM: 8%,
dry deserts

C4: 3%,
hot/dry grasslands
 Cellular Respiration
Cellular respiration – metabolic reactions that
convert stored energy in food to usable energy

 What is “food”? What is “usable energy”?

– Aerobic respiration – occurs in presence of oxygen

– Anaerobic respiration – occurs without oxygen
 Aerobic Respiration
Process of aerobic respiration:

1. Glycolysis breaks down glucose

2. Krebs Cycle produces coenzymes

3. Electron transfer chain powers ATP formation

C6H12O6 + 6O2 → 6CO2 + 6H2O + 36 ATP
 Aerobic Respiration
cytoplasm glucose

2 ATP ATP
GLYCOLYSIS
energy input to
start reactions e- + H+ (2 ATP net)
2 pyruvate
2 NADH

mitochondrion
e- + H+ 2 CO2
2 NADH
e- + H+
8 NADH 4 CO2
e- + H+ Krebs
2 ATP
2 FADH2 Cycle

e- ELECTRON
TRANSPORT 32 ATP
PHOSPHORYLATION

H+ water

e- + oxygen
TYPICAL ENERGY YIELD: 36 ATP
 Aerobic Respiration
1. Glycolysis
– Occurs in cytoplasm
– Glucose converted to two pyruvates  How many carbons
in pyruvate?
– Produces 2 ATP plus 2 NADH
 Aerobic Respiration
2. Acetyl-CoA formation and Krebs Cycle
– Occurs in mitochondria
– Pyruvate broken down into acetyl-CoA, then CO2
– Produces 2 ATP plus 8 NADH and 2 FADH2
inner outer
mitochondrial mitochondrial
membrane membrane

inner outer
compartment compartment
 Aerobic Respiration
2. Acetyl-CoA formation and Krebs Cycle
Acetyl-CoA pyruvate
Formation
coenzyme A NAD+
(CO2) NADH
CoA
acetyl-CoA

Krebs Cycle
CoA

oxaloacetate citrate

NAD+ (CO2)
NADH
NAD+ NADH

FADH2 NAD+ (CO2)
FAD
NADH

ATP ADP +
phosphate
group
 Aerobic Respiration
3. Electron transfer chain

– Occurs at inner mitochondrial membrane

– NADH and FADH2 deliver electrons

– Electron transfer sets up H+ concentration gradient

– Flow of H+ down gradient drives ATP formation
 Aerobic Respiration
3. Electron transfer chain

ATP synthase
 Summary of Aerobic Respiration
glucose
ATP

2 PGAL
ATP

2 NADH
Glycolysis:
2 pyruvate 2 ATP
glycolysis
+
2 FADH2
Krebs cycle:
2 CO2 e– 2 ATP
2 acetyl-CoA
2 NADH
H+ +
H+
2 ATP Krebs
6 NADH
H+
Electron transfer:
ATP
Cycle
2 FADH2
ATP H+
~32 ATP
4 CO2 34 ATP
H+

H+
ADP
electron + Pi
transfer H+
H+
phosphorylation 36 ATP
H+
 Anaerobic Respiration
Fermentation – anaerobic metabolism of
carbohydrates

Produces much less ATP than aerobic pathways

Two types:
– Alcoholic fermentation
– Lactate fermentation
 Anaerobic Respiration
Steps of fermentation:
1. Glycolysis – produces 2 ATP
2. Processes that regenerate coenzyme NAD+

ATP formed by glycolysis only
Occurs in cytoplasm only
Cyclic pathways
 Anaerobic Respiration
Alcoholic glycolysis

fermentation: ATP
C6H12O6
2
energy input 2 ADP 2 NAD+

– Converts pyruvate 2 NADH
4 ATP
to ethanol energy output 2 pyruvate

2 ATP net
– Ex: baking, ethanol
2 H2O
formation
wine & beer 2 CO2

production 2 acetaldehyde

electrons, hydrogen
from NADH

2 ethanol
 Anaerobic Respiration
Lactate
fermentation: glycolysis
C6H12O6

2 ATP

– Converts pyruvate energy input 2 ADP 2 NAD+

to lactate 2 NADH
4 ATP

energy output 2 pyruvate

– Ex: cheese, yogurt, 2 ATP net
some skeletal lactate
muscles formation
electrons, hydrogen
from NADH

2 lactate
 Food and Energy
Glucose is not the only molecule used to make ATP

Carbohydrates, fats, and proteins can all be used for
cellular respiration
– May enter glycolysis
– May enter acetyl-CoA formation
– May enter Krebs Cycle
Food and Energy
 Study Questions
What is an autotroph? What is a heterotroph?
What is the energy source that drives photosynthesis?
What are the “goals” of the light-dependent and light-independent
stages (Calvin Cycle) of photosynthesis? What products does each
produce? Where specifically does each occur?
Describe in detail the process of the light-dependent reactions.
Explain how electron transfer chains and ATP synthase work to
produce ATP in both photosynthesis and aerobic respiration.
What is photorespiration, and under what conditions does it occur at
high rates? What are C3, C4, and CAM? What sort of plants do each?
Describe the steps involved in aerobic respiration. What are the
“goals” of each step? Where does each step occur?
Compare and contrast aerobic and anaerobic respiration.