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Photosynthesis 2 - Pigments
Photons are Absorbed by Photosynthetic Pigments = The First Step in Photosynthesis
• The photosynthetic pigments absorb the energy of the photons.
excited state

Chl
ground state

↑

Energy 

• Photon absorption process:

Chl*
excited state

This is the
energy that
powers
photosynthesis.

Chl*

I

goes

Chl

grounda

Chl
Time 

back

to

down

ground
ChI

• In Chl* an electron has received the energy of a photon, and transiently moves to a
higher energy electron orbital (Chl* has a very short lifetime).

Absorption of a photon leads to the movement of
an electron ( ) to a higher energy orbital (further
away from the nucleus).

Nucleus

Higher energy orbital
Lower energy orbital

State

Photosynthesis 2 - Pigments
• The lifetime of the excited state is very brief.
• The electron quickly drops back to the lower
energy orbital (= the ground state).
• In photosynthesis, the energy of the excited
state is passed in to an adjacent Chl (more
about that very soon).
Higher energy orbital

Nucleus

Lower energy orbital

• In Chl* an electron has received the energy of a photon, and transiently moves to a
higher energy electron orbital (Chl* has a very short lifetime).

Car
ground state

Car*
excited state

Energy 

• Same deal with carotenoids:
Car*

Car

Time 
• All of this is happening in the thylakoids.
• All of the photosynthetic pigments (Chl & Car) are in the thylakoids.

Car

Photosynthesis 2 - Pigments

• Photosynthesis uses the energy of Chl* and
Car* to perform work.

Energy 

Photons are Absorbed by Photosynthetic Pigments = The First Step in Photosynthesis
• Chl* and Car* represent potential energy;
excited state
-Chl* and Car* represent the energy of a photon
• Chl and Car do not represent potential energy.
Chl*

Chl
Time 

• The ultimate goal of photosynthesis is to
produce carbohydrates (sucrose, starch);
-many sub-processes

ground state

Energy 

• The energy represented by carbohydrates
comes from photons.
• (The electrons in carbohydrates come from
water; the “water-splitting reaction”)

Chl

Car*

Car

Car
Time 

Photosynthesis 2 - Pigments
• Photosynthetic pigments are in the thylakoid membranes; nowhere else.
• Thylakoid membranes are green; nothing else in a leaf is green.
• The thylakoid lumen does not have pigments.

Modified from Chow (2003) Journal
of Biological Physics 29: 447-459

Photosynthesis 2 - Pigments
Energy is Transferred Between Pigments (in the thylakoids)
• This is not electron transfer (that’s later).
• Energy transfer:

ChlChlChl

CarChl

Chl*ChlChl

Car*Chl

ChlChl*Chl

ChlChlChl*

CarChl*

• There are a LOT of pigments, packed tightly together in the thylakoids.
• Energy always ends up at Chl (Chla to be precise);
-if Chlb absorbs photon  energy transferred to Chla
• The energy being transferred originally came from a photon.
• The energy transfer is the transfer of the excited state from one pigment to an
adjacent pigment.

Photosynthesis 2 – Light Reactions
Concept of a Photosystem
• The photosynthetic pigments are organized into photosystems.
• Lots of chlorophylls and also some carotenoids.
• One “job” of a photosystem is “light harvesting” (= photon absorption).
• The absorbed photons are funnelled to the reaction centre chlorophyll.
energy transfer
e- transfer

PS ETC

Regular Chlorophyll Molecules

Reaction Centre
Chlorophyll

PS ETC = photosynthetic electron transport chain

Photosynthesis 2 – Light Reactions - Photosystems
• In a photosystem, a lot of regular Chl molecules
funnel energy to the reaction centre Chl.
• At the reaction centre Chl, the energy is used to
convert a low energy electron to a high energy
electron.
• The high energy electron enters the PS
ETC.

e- transfer

Reaction Centre Chlorophyll

• There are two types of photosystems (PSII and
PSI).
• The general outline of how they work is the
same, but the details are different.

Photosynthesis 2 – Concept of a Photosystem
= energy of a photon moving from Chl to Chl to Chl until the energy reaches the RChl
A, B, C = electron carriers (for high energy e-s); RChl = reaction centre chlorophyll
stroma – site of the Calvin cycle

photon (particle of light)

B
A

transfer of high
energy electrons

C

thylakoid

RChl

light-harvesting
complex

reaction centre
complex

lumen of thylakoids

There are two sub-types of photosystems: PSI and PSII, which differ in their proteins and electron
carriers. Photosystems are in the thylakoid membrane.

Photosynthesis 2 – Concept of a Photosystem
= energy of a photon moving from Chl to Chl to Chl until the energy reaches the RChl
A, B, C = electron carriers (for high energy e-s); RChl = reaction centre chlorophyll
stroma – site of the Calvin cycle

photon (particle of light)

B
A

transfer of high
energy electrons

C

thylakoid

RChl

light-harvesting
reaction centre
complex
complex
• Lots of Chl + less Car.
• Pigments tightly packed in, side by side.
• Pigment-binding proteins.
• Energy transferred from pigment to pigment.

lumen of thylakoids

Photosynthesis – Concept of a Photosystem
= energy of a photon moving from Chl to Chl to Chl until the energy reaches the RChl
A, B, C = electron carriers (for high energy e-s); RChl = reaction centre chlorophyll
stroma – site of the Calvin cycle

photon (particle of light)

B
A

transfer of high
energy electrons

C

thylakoid

RChl

light-harvesting
complex

lumen of thylakoids
reaction centre
complex
• Some Chl + Car (less than LHC).
• Reaction centre Chl (RChl).
• Electron carriers.
• Many different proteins.

Photosynthesis 2 – Reaction Centre Chlorophylls
• Most Chl molecules have two possible states:
1) ground state
2) excited state
Energy 

excited state
Chl*

Chl

Chl
Time 
ground state

• Reaction centre chlorophylls (RChl) have three possible states:
RChl

RChl*

RChl+

ground state  excited state  oxidized state (= loss of an e-)

Photosynthesis 2 – Reaction Centre Chlorophylls
• RChl has three possible states:
RChl

RChl*

RChl+

• For RChl+, the e- that was lost was the high energy e- (HEE) that was in the higher
energy orbital.
• That HEE is transferred through various e- carriers in the photosystem and in the rest
of the photosynthetic electron transport chain; it is replaced by a low energy e- (LEE).

Chl*

Chl

RChl

RChl*

A reaction centre Chl (RChl)
cycles through three states.

A

e(low E)

A = e- acceptor
A- = acceptor with a high energy eRChl+

A-

Photosynthesis 2– Photosynthetic Electron Transport Chain & ATP Synthase
• There are two types of photosystems: PSII and PSI.
• The photosystems are embedded in the thylakoid.
• The photosystems contain e- carriers, and are also linked by additional e- carriers.
ATP synthase
stroma – site of the Calvin cycle
low [H+]
light
PSII
e-

nH+

ATP

NADPH

nH+
light

high E e-s
e-

ADP + Pi

high E e-s

e-

thylakoid
e-

4elow E e-s
2H2O

OEC
4H+ + O2

water-splitting reaction

low E e-s

nH+

ePSI
nH+

thylakoid
lumen
high [H+]

OEC = oxygen-evolving complex.
Both PSII and PSI are composed of a reaction centre complex and light-harvesting complexes.

Photosynthesis 2 – Photosystems
Photosystem II (PSII)
• HEE = high energy e-s
• LEE = low energy e-s

• P680 is the RChl for PSII
stroma – site of the Calvin cycle

photon (particle of light)

PSII reaction centre
complex

C

A

transfer of high
energy electrons

B

HEE

thylakoid

P680

LHCII

LEE
2H2O

OEC
4H+

lumen of thylakoids
+ O2

water-splitting reaction
• OEC = oxygen-evolving complex
• OEC is a multi-subunit protein attached to the PS reaction centre complex.
• OEC catalyzes the water-splitting reaction (2H2O  4e- + 4H+ + O2), and supplies low
energy e-s to P680.

Photosynthesis 2 – Photosystems
Photosystem II (PSII) has the Oxygen-Evolving Complex (OEC)
• Multi-protein complex that also contains metal ions.
• Attached to PSII, but protrudes into the thylakoid lumen.
• Catalyzes the water-splitting reaction.
• The water-splitting reaction produces:
1) LEEs – which are supplied to P680 and converted into HEEs and enter the PS ETC
2) H+s – released into the thylakoid lumen, contributing to the Δ[H+]
3) O2 – by-product (plant doesn’t care about this)

Water-splitting reaction:

2H2O  4e- + 4H+ + O2

Photosynthesis 2 – Photosystem II (PSII)
• The RChl in PSII is P680.
• Cycling of P680 through three states (ground state, excited state, oxidized state):

Chl*

Chl

P680

P680*
A

water-splitting
reaction

e(low E)
OEC

water

A = e- acceptor
A- = acceptor with a high energy eP680+

A-

Water-splitting reaction:
2H2O  4e- + 4H+ + O2
important

not important/
a by-product

Photosynthesis 2 – Electron Travel Between Photosystems
• The HEEs leave PSII and enter PSI as LEEs.
• The energy was used to pump H+s from the stroma to the thylakoid lumen;
 contributes to the Δ[H+]

Photosynthesis 2 – Photosystem I (PSI)
Photosystem I (PSI)
• LEE = low energy e-s
• HEE = high energy e-s

• P700 is the RChl for PSI
photon (particle of light)

stroma – site of the Calvin cycle
HEE

B
A

LEE

transfer of high
energy electrons

C

thylakoid

P700

lumen of thylakoids
PSI reaction
centre complex

LHCI

Photosystem I (PSI) RChl = P700
• The RChl in PSI is P700.
• PSI does not have an OEC; low energy electrons are from the photosynthetic electron
transport chain (ultimately from PSII, via the water-splitting reaction).
• Cycling of P700 through three states (ground state, excited state, oxidized state):

Chl*

Chl

P700

P700*
A

e(low E)
PSII

PS ETC

P700+

A-

A = e- acceptor
A- = acceptor with a high energy e-

Photosynthesis 2 – Photosynthetic Electron Transport Chain & ATP Synthase
• HEEs leave PSI.
• Stroma also has a pool of NADP, a two e- carrier similar to NAD.
• NADP+ + 2HEE (from PSI) + H+
NADPH (= e- source for the Calvin cycle)
ATP synthase
stroma – site of the Calvin cycle
low [H+]
light
PSII
e-

nH+

ATP

NADPH

nH+
light

high E e-s
e-

ADP + Pi

high E e-s

e-

thylakoid
e-

4elow E e-s
2H2O

OEC
4H+ + O2

low E e-s

nH+

ePSI
nH+

thylakoid
lumen
high [H+]

OEC = oxygen-evolving complex.
Both PSII and PSI are composed of a reaction centre complex and light-harvesting complexes.

Photosynthesis 2
Water-Soluble Electron Carriers in the Stroma
• NADP is a two e- carrier, structurally very similar to NAD (which we saw in ACR).
• NADP+ + 2e- + H+
NADPH

• NADPH = a pair of high energy electrons = chemical potential energy.
• NADPH is the molecule used to reduce C in photosynthesis.

Photosynthesis 2 – Photosynthetic Electron Transport Chain & ATP Synthase
•
•
•
•

ATP synthase regenerates ATP: ADP + Pi
ATP
ΔG = +7.3 kcal/mole
Need a coupling reaction  H+s moving down ΔC (Δ[H+])
Δ[H+] = CPE.
Two mechanisms that lead to the Δ[H+].

mechanism #1 for the Δ[H+]

mechanism #2 for the Δ[H+]

OEC = oxygen-evolving complex.
Both PSII and PSI are composed of a reaction centre complex and light-harvesting complexes.

Photosynthesis 2 – Photosynthetic Electron Transport Chain & ATP Synthase
• ATP synthase is located in the thylakoids.
• Same location as the PS ETC, but not part pf the PS
ETC.
• Very similar in structure and function to the
mitochondrial ATP synthase that is part of oxidative
phosphorylation.
• ATP synthase regenerates ATP for use in the Calvin
cycle.

Chloroplast ATP Synthase Reaction:
ADP + Pi + nH+lumen

ATP + nH+stroma (+ H2O)

There are two mechanisms that lead to the Δ[H+].

Relative Electron Energy Levels in the Photosynthetic Electron
Transport Chain (PS ETC) – The “Z Scheme”
P700*

Relative Energy of Electrons 

P680*

high energy electrons
NADPH

photon
photon

H2O
P680

P700
PSI

PSII
Path of Electrons Through the PS ETC 

low energy electrons

Photosynthesis 2 – Photosynthetic Electron Transport - HEEs

Photosynthesis 2 – Photosynthetic Electron Transport & ATP Synthase
• There are a lot of electron carriers in the photosynthetic electron transport chain.
• ATP synthase is a very complex multi-protein enzyme.

ATP synthase.

By Somepics - Own work, CC BY-SA 4.0,
https://commons.wikimedia.org/w/index.php?curid=38088695

These diagrams are far more detailed than
you need to know.

By The original uploader was Asw-hamburg at German Wikipedia. Transferred from de.wikipedia to Commons by Leyo using
CommonsHelper., CC BY-SA 3.0,
https://commons.wikimedia.org/w/index.php?curid=8993938

Photosynthesis 2
Chloroplast ATP Synthase Reaction (Complete Reaction, and Energy Transformations)
ADP + Pi
nH+lumen
ADP + Pi + nH+lumen

ATP
nH+stroma

ΔG > 0
ΔG < 0

ATP + nH+stroma ΔG < 0

The ATP synthase reaction.

• The chloroplast and mitochondrial ATP
synthases are very similar.
• Both are located in a membrane.
• Both the chloroplast and mitochondrial ATP
synthase convert the CPE of a Δ[H+] into the
CPE of ATP.

(coupling reaction)
n ≈ 4 H+/ATP

Photosynthesis 2 – Photosynthetic Electron Transport - HEEs
Quick Review – Why/How is There a Δ[H+]?
• Two mechanisms for generating the Δ[H+]:
1) water-splitting reaction by the OEC at PSII
2) H+ pumping by the PS ETC
• Reason for producing a Δ[H+]:
-ATP synthase needs a Δ[H+] in order to regenerate ATP

Mechanism #1

Mechanism #2

Photosynthesis 2
Energy Transformations So Far
photons @ PSII

water-splitting
H+ pumping

photons @ PSI

NADPH

Δ[H+]

ATP

The Light Reactions Convert the Energy of Photons into the Chemical Potential Energy
of ATP and NADPH
• The light reactions are all of the reactions/processes that are directly light-dependent:
-photon absorption by pigments, and transfer of energy to the RChls
-photosynthetic electron transport chain
-water-splitting reaction
-H+ pumping
-NADPH production
-ATP synthase activity
• But we have not fixed/reduced any inorganic carbon (CO2) yet.

Photosynthesis 2 – Enzymatic Reactions
• Photosynthesis takes place in two stages: light-dependent reactions (= the light
reactions) and the Calvin cycle (= the photosynthetic carbon reduction cycle = several
other names as well) and associated reactions.
• Both stages take place in chloroplasts, although in different parts of that organelle.
• The light reactions, which take place in the thylakoid membrane, use light energy to
regenerate ATP and NADPH. The Calvin cycle, which takes place in the stroma, uses
energy derived from these compounds to make 3C sugars from CO2.
+ other enzymatic reactions

3C sugars
Starch

Modified from OpenStax
Biology 2e

Sucrose

Photosynthesis 2 – Enzymatic Reactions
• The light reactions produce ATP and NADPH for the enzymatic reactions, and it’s the
enzymatic reactions (we will focus on the Calvin cycle) that fix CO2 and produce
carbohydrate.
• The enzymatic reactions occur in the stroma.
• The enzyme Rubisco catalyzes the first reaction of the Calvin cycle:
RuBP + CO2
5C sugar

2 3-PGA
3C molecule

• Rubisco is considered to be the most abundant protein on earth by mass.
• Rubisco is a large enzyme, with 16 subunits of two types (has 4° structure).
• Rubisco does not actually use either of the products of the photosynthetic light
reactions (NADPH, ATP), but subsequent steps in the Calvin cycle use NADPH and ATP
to produce a 3C sugar.
• Calvin cycle only operates in the light because it requires the products of the light
reactions.

Photosynthesis 2 – Enzymatic Reactions

CO2
RuBP

Rubisco

(high energy electrons)

nNADPH

2 3-PGA
nATP

nADP + nPi

nNADP+

Calvin cycle

3-Carbon
Sugars
Not part of the Calvin cycle
(but still very important)

Starch
(polymer of
glucose)

Sucrose
(12C Sugar)
Export to rest of plant

Photosynthesis 2 – Enzymatic Reactions
• Starch is insoluble, and serves as a temporary energy storage molecule.
Modified from Zhou et al. (2019) PeerJ 7(1):e7938
• The stroma contains starch grains.
Electron micrograph of a
chloroplast with a starch grain.

• Starch is also found in the roots and
in underground storage organs (e.g.
potato tubers).
• Sucrose is water-soluble, and is used
by plants as an energy transport
molecule;
 can be moved from leaves to
other parts of the plant
 sucrose is continually exported
from leaves in the daytime
• Chloroplast starch is converted to
sucrose at night;
 exported from the leaves

starch grain
(glucosen)

Sucrose

By NEUROtiker - Own work, Public Domain,
https://commons.wikimedia.org/w/index.php?curid=2951918

Photosynthesis 2 – Enzymatic Reactions
What does the Calvin cycle actually do? Why is it important?
• The Calvin cycle converts CO2 (inorganic C) into carbohydrate (organic C).
• To do this, it uses the products of the light reactions of photosynthesis (NADPH, ATP).
• The operation of the Calvin cycle depends on the operation of the light reactions.
• The light reactions capture the energy of light (photons) as the energy of NADPH and
ATP.
• The Calvin cycle converts the energy of NADPH and ATP into the form of carbohydrates.

Photosynthesis 2
• Overall: photosynthesis converts energy of photons into chemical potential energy
(C-C and C-H bonds of carbohydrate)
-takes 2 NADPH to reduce one CO2 (i.e. 4 e-s)
-takes 12 NADPH to produce the equivalent of one glucose
 split 12 water molecules
Energy Transformations During Photosynthesis
1) Energy of photons
CPE of the Δ[H+] across the thylakoids
CPE of NADPH
+ Heat
`

2) Chem pot E of the Δ[H+]

3) Chem pot E of NADPH
Chem pot E of ATP

Overall: Energy of photons

`

CPE of ATP
+ Heat

CPE of carbohydrate
+ Heat

`

light
reactions

CPE of carbohydrate
+ Heat

Calvin
cycle &
associated
reactions

Summary of Light Reactions and Enzymatic Reactions
Modified from
OpenStax Biology 2e.

Chloroplast
envelope

3C
Sugars

Starch

A summary of photosynthesis, as it takes place in the chloroplast. Photosynthesis may be
conceptually divided into the light reactions and the enzymatic reactions (carbon fixation via
the Calvin cycle & associated reactions). Light reactions harness energy from the sun to
produce ATP and NADPH. These energy-carrying molecules are made in the stroma where
carbon fixation (Calvin cycle) takes place.

Sucrose

A Comparison of Electron Transport Chains
• The photosynthetic and respiratory electron transport chains (PS ETC and RS ETC
respectively) have a lot in common.
• Both create a Δ[H+] across a membrane, and both pump H+s against a Δ[H+], which
requires energy.
• In both cases, the Δ[H+] is used to power ATP synthase (catalyzes ATP regeneration from
ADP and Pi).
• In both cases, ATP synthase is in the same membrane as the ETC (it must be, in order to
use the Δ[H+].
• Differences between the PS ETC and the RS ETC:
1) Source of energy is photons for the PS ETC, and NADH/FADH2 for the RS ETC.
2) The Δ[H+] is really the only “product” of the RS ETC, while the PS ETC produces both
a Δ[H+] and NADPH.
3) High energy electrons (NADH/FADH2) enter the RS ETC, and leave as low energy
electrons (O2 as the garbage can). Low energy electrons (from H2O) enter the PS ETC,
and leave as high energy electrons (NADPH).
4) The ETC and the Δ[H+] is thylakoid-based in the PS ETC, and based on the
mitochondrial inner membrane for the RS ETC.

Chloroplast Trivia: Kleptoplasty (= theft of plastids)
• There are several groups of animals that feed on marine algae and retain the algal
chloroplasts for a period of time; these chloroplasts maintain their capacity for
photosynthesis and provide reduced carbon to the organism (i.e. photosynthetic animals).
• The sea slug Elysia chlorotica, which acquires chloroplasts by eating the marine
filamentous alga Vaucheria litorea, can live 10-12 months without ingesting food (in the
presence of light).
This will not be on a test.

https://www.nature.com/articles/sdata201922

https://alchetron.com/Vaucheria-litorea

Atmospheric Carbon Dioxide – Photosynthesis and Fossil Fuels

southern summer

northern summer

https://gml.noaa.gov/ccgg/trends/

• There is more
vegetation north of the
equator.
The info on this slide
will not be on a test.
Modified from
https://earthobservatory.nasa.
gov/images/1863/globalenhanced-vegetation-index