PP-Photosynthesis and Cellular Respiration-0.ppt
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Oct 29, 2025
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About This Presentation
Photosynthesis & Cellular Respiration
Slide Content
Outline
•Overview
•Photosynthesis
I.Properties of light and pigments
II.Chloroplast structure and function
III.Light reactions
IV.“Dark” or Carbon reactions
V.Summary and conclusions
• Respiration
I.Processes
II.Energy and food chains
III.Carbon Cycle
•Overview
•Photosynthesis
I.Properties of light and pigments
II.Chloroplast structure and function
III.Light reactions
IV.“Dark” or Carbon reactions
V.Summary and conclusions
• Respiration
I.Processes
II.Energy and food chains
III.Carbon Cycle
Photosynthesis and Cellular
Respiration
Photosynthesis and respiration are complementary
processes in the living world. Photosynthesis uses
the energy of sunlight to produce sugars and other
organic molecules.
These molecules in turn serve as food for other
organisms that carry out respiration to obtain the
chemical bond, a process that uses O
2 to form CO
2
from the same carbon atoms that had been taken
up as CO
2 and converted into sugars by
photosynthesis.
Respiration
Photosynthesis and respiration are complementary
processes in the living world. Photosynthesis uses
the energy of sunlight to produce sugars and other
organic molecules.
These molecules in turn serve as food for other
organisms that carry out respiration to obtain the
chemical bond, a process that uses O
2 to form CO
2
from the same carbon atoms that had been taken
up as CO
2 and converted into sugars by
photosynthesis.
CO
2 + H
2O O
2 + C
6H
12O
66 6 6 1
PHOTOSYNTHESIS
SUNLIGHT
CHLOROPLASTS
2 + H
2O O
2 + C
6H
12O
66 6 6 1
PHOTOSYNTHESIS
SUNLIGHT
CHLOROPLASTS
C
6H
12O
6 + O
2 H
2O + CO
2 + ATP66 61
RESPIRATION
MITOCHONDRIA
6H
12O
6 + O
2 H
2O + CO
2 + ATP66 61
RESPIRATION
MITOCHONDRIA
What came first, photosynthesis
or respiration?
The first cells on the earth are thought to have been
capable of neither photosynthesis nor respiration.
However, photosynthesis must have preceded
respiration on the earth, since there is strong
evidence that billions of years of photosynthesis
were required before O
2
had been released in
sufficient quantity to create an atmosphere rich in
this gas. (The earth's atmosphere presently
contains 20% O
2
.)
or respiration?
The first cells on the earth are thought to have been
capable of neither photosynthesis nor respiration.
However, photosynthesis must have preceded
respiration on the earth, since there is strong
evidence that billions of years of photosynthesis
were required before O
2
had been released in
sufficient quantity to create an atmosphere rich in
this gas. (The earth's atmosphere presently
contains 20% O
2
.)
Introduction to photosynthesis
•From the Greek
PHOTO = produced by light
SYNTHESIS = a whole made of parts put
together.
Definition: PHOTOSYNTHESIS is the process
whereby plants, algae, some bacteria,
use the energy of the sun to synthesize organic
compounds (sugars) from inorganic compounds
(CO
2 and water).
•From the Greek
PHOTO = produced by light
SYNTHESIS = a whole made of parts put
together.
Definition: PHOTOSYNTHESIS is the process
whereby plants, algae, some bacteria,
use the energy of the sun to synthesize organic
compounds (sugars) from inorganic compounds
(CO
2 and water).
WHY IS PHOTOSYNTHESIS
SO IMPORTANT?
PHOTOSYNTHESIS is one of the most
important biological process on earth!
• Provides the oxygen we breathe
• Consumes much of the CO
2
• Food
• Energy
• Fibers and materials
SO IMPORTANT?
PHOTOSYNTHESIS is one of the most
important biological process on earth!
• Provides the oxygen we breathe
• Consumes much of the CO
2
• Food
• Energy
• Fibers and materials
GENERAL FORMULA FOR
PHOTOSYNTHESIS
light
6 CO
2
+ 12 H
2
O ---------> C
6
H
12
O
6
+ 6 O
2
+ 6 H
2
O
pigments, enzymes
* *
• Oxygen on earth allowed for the evolution of aerobic
respiration and higher life-forms.
• Respiration: extracting energy from compounds (sugars)
C
6
H
12
O
6
+ O
2
6 CO
2
+ ATP
PHOTOSYNTHESIS
light
6 CO
2
+ 12 H
2
O ---------> C
6
H
12
O
6
+ 6 O
2
+ 6 H
2
O
pigments, enzymes
* *
• Oxygen on earth allowed for the evolution of aerobic
respiration and higher life-forms.
• Respiration: extracting energy from compounds (sugars)
C
6
H
12
O
6
+ O
2
6 CO
2
+ ATP
PROPERTIES OF LIGHT
Virtually all life depends on it!
•Light moves in waves, in energy units
called PHOTONS
• Energy of a PHOTON inversely proportional
to its wavelength
• Visible light (between UV and IR) occurs in
a spectrum of colors
Virtually all life depends on it!
•Light moves in waves, in energy units
called PHOTONS
• Energy of a PHOTON inversely proportional
to its wavelength
• Visible light (between UV and IR) occurs in
a spectrum of colors
Visible light contains just the right amount of
energy for biological reactions
energy for biological reactions
Light is absorbed by pigments
•The primary pigment for photosynthesis is
chlorophyll a
•It absorbs blue and red light, not green (green
light is reflected back!)
Absorption spectrum
of chlorophyll a
•The primary pigment for photosynthesis is
chlorophyll a
•It absorbs blue and red light, not green (green
light is reflected back!)
Absorption spectrum
of chlorophyll a
Chlorophyll a is the primary
photosynthetic pigment that drives
photosynthesis.
Accessory pigments absorb at
different wavelengths,
extending the range of light
useful for photosynthesis.
photosynthetic pigment that drives
photosynthesis.
Accessory pigments absorb at
different wavelengths,
extending the range of light
useful for photosynthesis.
•Absorption spectrum of chlorophyll a:
BLUE & RED
•Action spectrum of photosynthesis closely
matches absorption spectrum of
chlorophyll a, but not perfectly (due to
accessory pigments)
BLUE & RED
•Action spectrum of photosynthesis closely
matches absorption spectrum of
chlorophyll a, but not perfectly (due to
accessory pigments)
Chloroplast structure
•Football shaped
•Double membrane
•Stroma
•Thylakoid
membrane
•Grana (stacks)
•Lumen
(inside thylakoid)
stroma
Grana
thylakoids
lumen
•Football shaped
•Double membrane
•Stroma
•Thylakoid
membrane
•Grana (stacks)
•Lumen
(inside thylakoid)
stroma
Grana
thylakoids
lumen
Chloroplast structure and function:
solar chemical factory
solar chemical factory
Chloroplast Membrane Structure
•The thylakoid is the structural unit of
photosynthesis containing photosynthetic
chemicals.
•Thylakoids are stacked like pancakes in
stacks known collectively as grana. The
areas between grana are referred to as
stroma.
•While the mitochondrion has two
membrane systems, the chloroplast has
three, forming three compartments.
•The thylakoid is the structural unit of
photosynthesis containing photosynthetic
chemicals.
•Thylakoids are stacked like pancakes in
stacks known collectively as grana. The
areas between grana are referred to as
stroma.
•While the mitochondrion has two
membrane systems, the chloroplast has
three, forming three compartments.
Chloroplast Structure & Function
•The chloroplast has three membranes:
inner, outer, and thylakoid . It has three
compartments: stroma, thylakoid space, and
inter-membrane space.
•These compartments and the membranes
that separate them serve to isolate different
aspects of photosynthesis.
–Dark reactions take place in the stroma.
–Light reactions take place on the thylakoid
membranes.
•The chloroplast has three membranes:
inner, outer, and thylakoid . It has three
compartments: stroma, thylakoid space, and
inter-membrane space.
•These compartments and the membranes
that separate them serve to isolate different
aspects of photosynthesis.
–Dark reactions take place in the stroma.
–Light reactions take place on the thylakoid
membranes.
Inside a Chloroplast
•Remember: Structure correlates to function!
•Remember: Structure correlates to function!
Overview of photosynthesis:
Note: The Light and “Dark”or Carbon
reactions happen at different sites in the
chloroplast
LIGHT
REACTIONS
(Thylakoids)
“DARK” or CARBON
REACTIONS
(Stroma)
light
ATP
NADPH
(ENERGY)
H2O
O2
(OXYGEN GAS)
CO2
C6H12O6
(GLUCOSE)
Note: The Light and “Dark”or Carbon
reactions happen at different sites in the
chloroplast
LIGHT
REACTIONS
(Thylakoids)
“DARK” or CARBON
REACTIONS
(Stroma)
light
ATP
NADPH
(ENERGY)
H2O
O2
(OXYGEN GAS)
CO2
C6H12O6
(GLUCOSE)
The Light Reactions
1. Light dependent
2. Occur in the thylakoid membrane of
chloroplast
4. Use light energy (photons) to generate two
chemical energy compounds: ATP &
NADPH
3. Water is split into oxygen gas (O
2) and H
+
1. Light dependent
2. Occur in the thylakoid membrane of
chloroplast
4. Use light energy (photons) to generate two
chemical energy compounds: ATP &
NADPH
3. Water is split into oxygen gas (O
2) and H
+
The“Dark” or Carbon Reactions
1. Light independent (can occur in light or dark;
some enzymes require activation by light)
2. Occur in the stroma of chloroplasts
3. Use the chemical energy produced in Light
Reactions (ATP; NADPH) to reduce CO
2
to
carbohydrate (sugar).
4.CO
2 is converted to sugar by entering the
Calvin Cycle
1. Light independent (can occur in light or dark;
some enzymes require activation by light)
2. Occur in the stroma of chloroplasts
3. Use the chemical energy produced in Light
Reactions (ATP; NADPH) to reduce CO
2
to
carbohydrate (sugar).
4.CO
2 is converted to sugar by entering the
Calvin Cycle
Efficiency & Photosynthesis
•Photosynthesis is not perfect.
•Depending upon the plant type, it ranges
from being only 1 - 4 % efficient to having
7% efficiency
•Photosynthesis is not perfect.
•Depending upon the plant type, it ranges
from being only 1 - 4 % efficient to having
7% efficiency
Summary of Photosynthesis:
1.Light energy absorbed by chlorophyll a
drives the reactions of photosynthesis.
2. Converts light energy into chemical
energy to make organic compounds.
3. CO
2 and H
2O used to produce
C
6H
12O
6 (glucose) and O
2 (gas).
1.Light energy absorbed by chlorophyll a
drives the reactions of photosynthesis.
2. Converts light energy into chemical
energy to make organic compounds.
3. CO
2 and H
2O used to produce
C
6H
12O
6 (glucose) and O
2 (gas).
4. Light Reactions occur in thylakoids of the
chloroplasts; ATP and NADPH are formed;
water is split to O
2
(gas) and protons.
5. Carbon Reactions occur in stroma – Calvin
Cycle fixes CO
2 to produce C
6H
12O
6 (glucose).
6. Low efficiency, about 1- 7%
7. Nevertheless, PHOTOSYNTHESIS is still
the most important biological process on
earth!
chloroplasts; ATP and NADPH are formed;
water is split to O
2
(gas) and protons.
5. Carbon Reactions occur in stroma – Calvin
Cycle fixes CO
2 to produce C
6H
12O
6 (glucose).
6. Low efficiency, about 1- 7%
7. Nevertheless, PHOTOSYNTHESIS is still
the most important biological process on
earth!
Without
photosynthesis,
virtually all
plants and
animals would
become extinct.
photosynthesis,
virtually all
plants and
animals would
become extinct.
RESPIRATION
•Process of making energy of food available in
the cell…
•Involves breaking down
•Complicated molecules into simple molecules
(C
6
H
12
O
6
, sugars) (CO
2
, water)
•Process of making energy of food available in
the cell…
•Involves breaking down
•Complicated molecules into simple molecules
(C
6
H
12
O
6
, sugars) (CO
2
, water)
Chloroplast –vs- Mitochondria
•Both are surrounded by a double membrane
with an intermembrane space.
•Both have their own DNA .
•Both are involved in energy metabolism.
•Both have membrane reticulations filling
their inner space to increase the surface area
on which reactions with membrane-bound
proteins can take place.
•Both are surrounded by a double membrane
with an intermembrane space.
•Both have their own DNA .
•Both are involved in energy metabolism.
•Both have membrane reticulations filling
their inner space to increase the surface area
on which reactions with membrane-bound
proteins can take place.
Mitochondria Structure
•The outer membrane to protect the organelle
•The intramembranous space of the
mitochondria (the space between the inner
and outer membranes)
•The inner membrane is folded into a series
cristae or long folds that greatly increase the
surface area of the inner membrane allowing
more area for energy production.
•The outer membrane to protect the organelle
•The intramembranous space of the
mitochondria (the space between the inner
and outer membranes)
•The inner membrane is folded into a series
cristae or long folds that greatly increase the
surface area of the inner membrane allowing
more area for energy production.
RESPIRATION
The energy held by complicated molecules is held
temporarily as ATP (energy currency)
C
6
H
12
O
6
+ 6 O
2
6CO
2
+ 6 H
2
O + 36 ATP
(glucose) (energy)
Respiration occurs mainly in
Mitochondria and Cytoplasm
The energy held by complicated molecules is held
temporarily as ATP (energy currency)
C
6
H
12
O
6
+ 6 O
2
6CO
2
+ 6 H
2
O + 36 ATP
(glucose) (energy)
Respiration occurs mainly in
Mitochondria and Cytoplasm
Stages of Respiration
Cellular Respiration has three main stages:
•Glycolysis
•Krebs Cycle
•Electron transport system
Cellular Respiration has three main stages:
•Glycolysis
•Krebs Cycle
•Electron transport system
3 Stages of cellular respiration
•Glycolysis: Splitting of glucose – 2 net ATP generated
•Krebs Cycle: Energy of glucose molecule is harvested
as ATP (2) – it occurs in the mitochondria (matrix)
•Electron Transport System: also happens in the
mitochondria, more ATP are generated (32).
•For each glucose molecule, total ATP = 36
•Only 39% efficient, rest is lost as heat.
•Glycolysis: Splitting of glucose – 2 net ATP generated
•Krebs Cycle: Energy of glucose molecule is harvested
as ATP (2) – it occurs in the mitochondria (matrix)
•Electron Transport System: also happens in the
mitochondria, more ATP are generated (32).
•For each glucose molecule, total ATP = 36
•Only 39% efficient, rest is lost as heat.
Photosynthesis Respiration
•Reaction: CO2+H2O+sunC6H12O6+O2+H2O C6H12O6+O2CO2+H2O+36ATP
•Reactants: Carbon dioxide, water, sun Glucose, oxygen
•Products: Glucose Energy
•By-products: Oxygen Carbon dioxide, water
•Cellular location: Chloroplasts Cytoplasm, mitochondria
•Energetics: Requires energy Releases energy
•Chemical paths: Light reactions & Glycolysis, Krebs cycle
Calvin cycle & Electron Transport Syst.
•Summary: Sugar synthesized using Energy released from
energy from the sun sugar breakdown
•Reaction: CO2+H2O+sunC6H12O6+O2+H2O C6H12O6+O2CO2+H2O+36ATP
•Reactants: Carbon dioxide, water, sun Glucose, oxygen
•Products: Glucose Energy
•By-products: Oxygen Carbon dioxide, water
•Cellular location: Chloroplasts Cytoplasm, mitochondria
•Energetics: Requires energy Releases energy
•Chemical paths: Light reactions & Glycolysis, Krebs cycle
Calvin cycle & Electron Transport Syst.
•Summary: Sugar synthesized using Energy released from
energy from the sun sugar breakdown
Photosynthesis and respiration
•Photosynthesis and respiration are
complimentary reactions…
•Photosynthesis and respiration are
complimentary reactions…
PHOTOSYNTHESIS RESPIRATION
CO
2
+ H
2
O O
2
+ SUGARS SUGARS + O
2
H
2
O + CO
2
PLANTS, PLANTS,
ALGAE, ALGAE,
BACTERIABACTERIA
MOST LIVING
ORGANISMS
H
2
O H
2
O
O
2
O
2CO
2
CO
2
SUGARS
Sunlight
energy
USEFUL CHEMICALUSEFUL CHEMICAL
ENERGY (ATP)ENERGY (ATP)
CO
2
+ H
2
O O
2
+ SUGARS SUGARS + O
2
H
2
O + CO
2
PLANTS, PLANTS,
ALGAE, ALGAE,
BACTERIABACTERIA
MOST LIVING
ORGANISMS
H
2
O H
2
O
O
2
O
2CO
2
CO
2
SUGARS
Sunlight
energy
USEFUL CHEMICALUSEFUL CHEMICAL
ENERGY (ATP)ENERGY (ATP)
Respiration, Energy & Carbon Cycle
•Energy
•Virtually all organisms require energy of food for:
•Making chemicals
(proteins, carbs, etc.)
•Movement
•Cell division
•Heat, electricity and light production
•The way living organisms obtain energy is through
Cell respiration
•Energy
•Virtually all organisms require energy of food for:
•Making chemicals
(proteins, carbs, etc.)
•Movement
•Cell division
•Heat, electricity and light production
•The way living organisms obtain energy is through
Cell respiration
ENERGY: ability to do work
Newton’s First Law of Thermodynamics:
“Energy cannot be created or destroyed, it
can only be transformed from one form
to another”
•Once a cell has used energy to do work, it cannot
be used again by any organism.
(1701)
Newton’s First Law of Thermodynamics:
“Energy cannot be created or destroyed, it
can only be transformed from one form
to another”
•Once a cell has used energy to do work, it cannot
be used again by any organism.
(1701)
ENERGY
ENERGY FLOW IS LINEAR
Sun Earth Producers 1
o
consumers 2
o
consum
heat resp, heatresp, heat resp, heat
Energy flows into ecosystem from the sun
Energy travels in a straight line by way of
food chains.
ENERGY FLOW IS LINEAR
Sun Earth Producers 1
o
consumers 2
o
consum
heat resp, heatresp, heat resp, heat
Energy flows into ecosystem from the sun
Energy travels in a straight line by way of
food chains.
ENERGY
However, much energy is lost as heat along the
way – as a result of respiration.
Approximately 90% energy is lost on each step!
•Newton’s Second Law of
Thermodynamics:
“In any transfer of energy there is always a
loss of useful energy to the system, usually in
the form of heat”
However, much energy is lost as heat along the
way – as a result of respiration.
Approximately 90% energy is lost on each step!
•Newton’s Second Law of
Thermodynamics:
“In any transfer of energy there is always a
loss of useful energy to the system, usually in
the form of heat”
Food Chains
Food chains demonstrate linear nature of energy
•Producers are the base of the food chain, they
include photosynthetic organisms like:
•Plants
•Algae
•Certain bacteria
Food chains demonstrate linear nature of energy
•Producers are the base of the food chain, they
include photosynthetic organisms like:
•Plants
•Algae
•Certain bacteria
Food chains
•Primary
consumers –
all plant eaters
(herbivores).
Secondary
consumers –
Eat primary
consumers,
(carnivores)
•Primary
consumers –
all plant eaters
(herbivores).
Secondary
consumers –
Eat primary
consumers,
(carnivores)
Food chains
•Decomposers – obtain energy by breaking
down remaining organic material of the
other members of the food chain.
•Fungi and bacteria.
•Decomposers – obtain energy by breaking
down remaining organic material of the
other members of the food chain.
•Fungi and bacteria.
Matter
•All important elements move in cycles;
Environment Organisms
Cycles called biogeochemical cycles:
Water cycle
Carbon cycle
Nitrogen cycle
•All important elements move in cycles;
Environment Organisms
Cycles called biogeochemical cycles:
Water cycle
Carbon cycle
Nitrogen cycle
The Carbon Cycle
•Carbon from the atmosphere (CO
2) enters the
biosphere by way of plants!
–CO
2 used in photosynthesis
–Carbon moves into food chain
•Carbon is released to the physical environment by
respiration
–Release CO
2 during respiration
–Amount CO
2
fixed in photosynthesis = the amount
released by respiration
•Carbon from the atmosphere (CO
2) enters the
biosphere by way of plants!
–CO
2 used in photosynthesis
–Carbon moves into food chain
•Carbon is released to the physical environment by
respiration
–Release CO
2 during respiration
–Amount CO
2
fixed in photosynthesis = the amount
released by respiration
Carbon Cycle
•Carbon moves from atmosphere to plants to
animals and back to atmosphere.
•Carbon moves from atmosphere to plants to
animals and back to atmosphere.
“Look deep into nature,
and then you will
understand everything
better.”
Albert Einstein
and then you will
understand everything
better.”
Albert Einstein
•http://www.biologie.uni-hamburg.de/b-
online/library/falk/CellStructure/
cellStructure.htm
online/library/falk/CellStructure/
cellStructure.htm
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