Chapter 10 - Photosynthesis (ML) PDF

Summary

This document is a chapter on the scientific topic of photosynthesis, detailing an outline, learning outcomes, overview and key concepts of the subject. There will be numerous questions to help with understanding this chapter.

Full Transcript

Chapter 10: Photosynthesis
 Outline

An overview of photosynthesis.

Light absorption by pigments.

The photosynthetic electron transport chain.
– Light reaction - reaction centre.

The Calvin cycle.

Readings: Chapter 10, p212 - p232.
 Learning outcomes
By the end of this lesson, you should be able to

1. describe the biological function of photosynthesis.

2. describe the two major stages of photosynthesis.

3. describe the structure of chloroplasts, mesophyll cells, and leaves.

4. characterize the nature of light.

5. explain the function of photosynthetic pigments.

6. describe the structure and function of a photosystem.

7. describe the similarities and differences between oxidative
phosphorylation in mitochondria and photophosphorylation in
chloroplasts.

8. describe the three phases of the Calvin cycle.
 Plants are photoautotrophic organisms
An autotroph is an organism that produces organic molecules using CO2 as a
carbon source.
Autotrophs produce their own food to sustain themselves without eating other organisms.

Plants, some protists, algae and cyanobacteria are photoautotrophs.
 Photosynthesis
Photoautotrophs use the energy of sunlight and carbon from
CO2 to make carbohydrates by the process of photosynthesis.

What does CO2
contribute to
photosynthesis?

6 6 6
Which is the reducing
agent? CO2 or H2O?

Is photosynthesis an endergonic or exergonic reaction?

Is photosynthesis a catabolic process or an anabolic process?
 Photosynthesis is a series of redox reactions
During photosynthesis, CO2 molecules are reduced to form carbohydrate
molecules.
─ The electron donor (reducing agent) is water. The oxidation of water results
in the production of electrons, protons, and O2.
The electrons and protons are incorporated into carbohydrates, and O2
is a by-product.

Where does CO2 come from?
So which molecule produced the O2 in the reaction?
 Photosynthesis occurs in the chloroplasts
Photosynthesis occurs mostly in leaves of plants which contain the
chloroplasts.
Which plant cells perform photosynthesis?
What are the functions of the phloem and xylem tissue?

What are the functions of
the guard cells?
 The chloroplast

Chloroplasts are
enclosed by a double
membrane.

Inside the chloroplast is
a third, highly folded
membrane known as the
thylakoid membrane.
─ The photosynthetic
electron transport chain
is located at the
thylakoid membrane.
 Photosynthesis occurs in two stages linked
by ATP and NADPH
– Photosynthesis occurs in two metabolic stages:
1. The light harvesting reactions
2. The Calvin cycle

The light harvesting
reaction occurs at
the thylakoid
membranes.

The Calvin cycle
occurs in the stroma.
 The light harvesting reactions
H 2O

Light
Light is absorbed by
protein-pigment
NADP+ complexes known as
ADP photosystems to drive
+ Pi
the transfer of electrons
Light
from water to NADP+
Reactions reducing it to NADPH.
ATP
ATP is synthesized by
NADPH using an electron
transport chain.
Chloroplast
O2 is a byproduct.
O2
The Calvin cycle H2O CO2

Light Return ADP, P and NADP to
The Calvin the light reaction
cycle uses ATP NADP+
and NADPH ADP
produced from + Pi
the light Calvin
Light Cycle
reactions to Reactions
convert CO2 ATP
into sugars.
NADPH

Chloroplast

O2 [CH2O]
(sugar)
 Photosynthesis uses light energy to make food molecules
H2O CO2 About half of the
Chloroplast sugars made by
Light photosynthesis are
consumed as fuel for
NADP+ cellular respiration in
ADP plant cells.
P
Light
Reactions
RuBP
Photosystem II Calvin
Cycle 3-PGA
Electron (in stroma)
transport chain
Thylakoids
Photosystem I ATP Stroma

NADPH Triose phosphate
Cellular
respiration
Cellulose
Starch
O2 Sugars Other organic
compounds

Why do plants need mitochondria for ATP production?
Starch granules in a chloroplast

Excess carbohydrates
are converted to starch
and stored temporarily in
the chloroplasts.
 Light absorption
Light is a type of electromagnetic energy with wave-like properties.
Wavelength is the distance between crests of waves.
– Wavelength determines the type of electromagnetic energy.
– The amount of energy is inversely related to the wavelength of
the light.
Visible radiation absorbed by pigments drives the light
reactions
Pigments are molecules that absorb wavelengths of visible light.
Pigments look colored because they reflect or transmit light
wavelengths that they do not absorb.

Explain why leaves
appear green? Light
Reflected
light

Chloroplast Absorbed
Thylakoid light
Transmitted
light
The absorption spectra of pigments in chloroplasts
An absorption spectrum is a graph plotting a pigment’s light
absorption versus wavelength.
– The absorption spectrum of chlorophyll suggests that violet-blue and red
wavelengths of light work best for photosynthesis.

What wavelength of light to chlorophyll a and chlorophyll b reflect?

Carotenoids are able to

1. absorb light from regions of
the visible spectrum that are
poorly absorbed by chlorophyll.

2. It can also protect chlorophyll
from high-energy photons, which
can be damaging.
 Chlorophyll

Chlorophyll has

a large, light-absorbing head.
The light-absorbing head absorbs violet-blue
light and red light while reflecting green light.
a long hydrocarbon tail.
The hydrocarbon tail allows the chlorophyll
pigment to be anchored in the lipid
membrane.
 Chlorophyll light absorption in the lab
When chlorophyll molecules absorb light, one of its electrons goes from a
ground state to an excited state.
For isolated chlorophyll in the lab, most of the light energy absorbed by the electron is
rapidly released as heat and as fluorescent light.

Why is heat released when the excited electron returns to the ground state?
Chlorophyll light absorption in a plant cell
When electrons in a chlorophyll
molecule of a plant cell absorbs light
and becomes excited, the electron
can transfer the absorbed energy to
another electron in an adjacent
chlorophyll molecule.
The excited electron in the second
chlorophyll molecule can then
transfer the energy to another
electron in another adjacent
chlorophyll molecule.

The chlorophyll molecules that
absorb and transfer the energy from
light are called antenna chlorophylls.
The reaction centre converts light to chemical energy

The energy from the absorbed light is
passed from antenna chlorophyll to
antenna chlorophyll molecules until
it reaches a specially configured pair
of chlorophyll molecules known as
the reaction centre.

The reaction centre chlorophylls
have a distinct configuration and can
transfer the high-energy electron to
an electron acceptor.
When the electron transfer takes place,
the reaction centre becomes oxidized,
and the electron acceptor is reduced.

The electron acceptor now enters
the photosynthetic electron
transport chain.
 The reaction centre converts light to chemical energy
In order for the photosystem II to continue capturing light energy, another
electron must be delivered to the reaction center to replace the one that was
lost.

Which molecule is the electron donor in photosynthesis?
A O 2.
B CO2.
C H2O.

H2O
 The photosynthetic electron transport chain contains two photosystems

The photosynthetic electron transport chain connects photosystem II to
photosystem I.
Two photosystems are necessary to provide enough energy to pull electrons from water and
then use them to reduce NADP+ to form NADPH.
 Photosystem II and photosystem I
Photosystem II supplies electrons to the beginning of the photosynthetic
electron transport chain. When photosystem II loses an electron, it can pull
another electron from water.

Photosystem I energizes the electrons with a second input of light energy, so
they have enough energy to reduce NADP+ to form NADPH.

What do you think this
structure is?
 Proton accumulate in the thylakoid lumen
1. The oxidation of H2O in the thylakoid lumen form O2 and H+, increasing the H+
concentration.
2. Cytochrome b6f complex works as a H+ pump to move H+ from the stroma to the
lumen as electrons pass through the complex, releasing energy.
2
1 Protons flow back into the stroma
During electron through the ATP synthase, driving the
transport, protons synthesis of ATP.
Stroma accumulate in the
ATP
thylakoid lumen. ADP + Pi
Light Light
H+ ATP
synthase H+

PS II Cyt-b6f PS I

Pq H+

O2 H+
H2 O
H+ H+
Lumen
This type of ATP production is called photophosphorylation.
 Photosystem I
Photosystem II
The Z Scheme
As an electron is transferred
from water (1) in photosystem
II, its energy level is initially
H2O high (2), but as the electron
NADP+ + H+
travels through the electron
e- e- e- e-
transport chain, its energy
NADPH level decreases (3).
1/2 O2 + 2 H+

4
The Z energy trajectory 5 It takes a second input of light
2 energy in photosystem I to
ET
Energy of
electrons

C 3 raise the electron energy level
1 high (4) enough so that it can
be used to reduce NADP+ (5).
Absorption of light energy A second input... so that
by PS II energizes electrons of light energy they can
pulled from water, allowing by PS I raises the be used to
them to enter the electrons reduce
photosynthetic electron to an even NADP+.
transport chain. higher level...
 Mitochondrion Chloroplast

H+ c.

a.

d.

b. e.

Compare chemiosmosis and electron transport in mitochondria and chloroplast. In each
case, answer the following questions below.

What do each of the labels represent in the mitochondrion vs. the chloroplast?
Where do the electrons come from?
How do the electrons get their high potential energy?
What picks up the electrons at the end of the chain?
How is the energy from the electrons used to do work?
 The Calvin cycle: reducing CO2 to sugar
The Calvin cycle makes sugar in the chloroplast.
The Calvin cycle occurs in the stroma of the
CO2
chloroplast. Input ATP
NADPH
To produce sugar, the key molecules are
– CO2.
– ATP and NADPH generated by the light
reactions.
Calvin
The Calvin cycle uses these three molecules to Cycle
produce a three-carbon sugar called
glyceraldehyde 3-phosphate (G3P)/triose
phosphate.
A plant cell may then use G3P to make glucose and
other carbohydrates.
Output: G3P
Can the Calvin cycle occur in the dark?
 The 3 main steps of the Calvin cycle
The Calvin cycle consists of three main steps:

1. Carboxylation: CO2 is added to a 5-carbon molecule, ribulose-1,5-
bisphosphate (RUBP).
I. This reaction is catalyzed by the enzyme rubisco.
II. The 6-carbon molecule formed is immediately broken down into two 3-carbon molecules of
3-phosphoglycerate (3-PGA).

2. Reduction: The 3-PGA is then reduced by the electron carrier NAPDH to
form G3P.
I. First, ATP is used to phosphorylate 3-PGA.
II. Then NADPH transfers electrons resulting in the formation of the high-energy molecule
glyceraldehyde 3-phosphate (G3P)/triose phosphate. G3P is a precursor for glucose.

3. Regeneration: The RuBP needed for carboxylation is regenerated which
involves 12 steps. ATP is also required for this step.
 The Calvin cycle

Rubisco
G3P

For every 6 glyceraldehyde
The 5 remaining 3-carbon 3-phosphate/triose
triose phosphates are phosphate molecules that
reshuffled to produce three are produced, only one can
5-carbon RuBP molecules. be withdrawn from the
Calvin cycle.