The equation for photosynthesis is a
deceptively simple summary of a very complex process. Actually, photosynthesis
is not a single process, but two processes, each with multiple steps. These two
stages of photosynthesis are known as the light reactions (the photo part of
photosynthesis) and the Calvin cycle (the synthesis part).
The diagram above
is an overview of photosynthesis: cooperation of the light reactions and the
Calvin cycle. In the chloroplast, the thylakoid membranes are the sites of the
light reactions, whereas the Calvin cycle occurs in the stroma. The light
reactions use solar energy to make ATP and NADPH, which function as chemical
energy and reducing power, respectively, in the Calvin cycle. The Calvin cycle
incorporates CO2 into organic
molecules, which are converted to sugar.
The light
reactions are the steps of photosynthesis that convert solar energy to chemical
energy. Light absorbed by chlorophyll drives a transfer of electrons and
hydrogen from water to an acceptor called NADP+ (nicotinamide adenine
dinucleotide phosphate), which temporarily stores the energised electrons. Water
is split in the process, and thus it is the light reactions of photosynthesis
that give off O2 as a by–product. The
electron acceptor of the light reactions, NADP+, is first cousin to NAD+, which
functions as an electron carrier in cellular respiration; the two molecules
differ only by the presence of an extra phosphate group in the NADP+ molecule.
The light reactions use solar power to reduce NADP+ to NADPH by adding a pair of
electrons along with a hydrogen nucleus, or H+. The light reactions also
generate ATP, using chemiosmosis to power the addition of a phosphate group to
ADP, a process called photophosphorylation. Thus, light energy is initially
converted to chemical energy in the form of two compounds: NADPH, a source of
energised electrons (“reducing power”), and ATP, the versatile energy currency
of cells. Notice that the light reactions produce no sugar; that happens in the
second stage of photosynthesis, the Calvin cycle.
The Calvin cycle is named for Melvin Calvin,
who, along with his colleagues, began to elucidate its steps in the late 1940s.
The cycle begins by incorporating CO2
from the air into organic molecules already present in the chloroplast. This
initial incorporation of carbon into organic compounds is known as carbon
fixation . The Calvin cycle then reduces the fixed carbon to carbohydrate by the
addition of electrons. The reducing power is provided by NADPH, which acquired
energized electrons in the light reactions. To convert CO2 to carbohydrate, the Calvin cycle also
requires chemical energy in the form of ATP, which is also generated by the
light reactions. Thus, it is the Calvin cycle that makes sugar, but it can do so
only with the help of the NADPH and ATP produced by the light reactions. The
metabolic steps of the Calvin cycle are sometimes referred to as the dark
reactions, or light–independent reactions, because none of the steps requires
light directly. Nevertheless, the Calvin cycle in most plants occurs during
daylight, for only then can the light reactions provide the NADPH and ATP that
the Calvin cycle requires. In essence, the chloroplast uses light energy to make
sugar by coordinating the two stages of photosynthesis.
The thylakoids of the chloroplast are the sites
of the light reactions, while the Calvin cycle occurs in the stroma. In the
thylakoids, molecules of NADP+ and ADP pick up electrons and phosphate,
respectively, and then are released to the stroma, where they transfer their
high–energy cargo to the Calvin cycle. The two stages of photosynthesis are
treated in this figure as metabolic modules that take in ingredients and crank
out products. Our next step toward understanding photosynthesis is to look more
closely at how the two stages work, beginning with the light reactions.
The light reactions convert solar energy to the
chemical energy of ATP and NADPH.
Chloroplasts are chemical factories powered by
the sun. Their thylakoids transform light energy into the chemical energy of ATP
and NADPH. To understand this conversion better, we need to know about some
important properties of light.
Chlorophyll and
light absorption
Chlorophyll absorbs light from the visible part
of the electromagnetic spectrum. Chlorophyll is made up of a number of different
pigments: chlorophyll a, chlorophyll b, chlorophyll c along with other pigments
such as carotenoids. Each of these absorb different wavelengths of light so that
the total amount of light absorbed is greater than if a single pigment were
involved. Not all wavelengths of light are absorbed equally. An absorption
spectrum is a graph showing the percentage absorption plotted against wavelength
of light (Fig 1). An action spectrum is a graph showing the rate of
photosynthesis plotted against wavelength of light (Fig 1). The similarity
between the absorption spectrum and the action spectrum shows that red (650-
700nm) and blue (400-450nm) wavelengths, which are absorbed most strongly, are
also the wavelengths which stimulate photosynthesis the most. Green light
(550mm) is mostly reflected.
1. Light energy is
absorbed by chlorophyll molecules in PSI and PSII.
2. The electrons in the chlorophyll molecules
are boosted to a higher energy level and are emitted.
3. The loss of electrons from PSII stimulates
the loss of electrons from water i.e. it stimulates the splitting or photolysis
of water. O2 is given off.
4. The electron from PSII passes through a
series of electron carriers. At each transfer some energy is released.
5. This energy is used by cytochromes to pump
protons (H+ ions) from the stroma across the thylakoid membranes. This sets up
an electrochemical or H+ gradient. The H+ ions then diffuse back through a
protein which spans the thylakoid membrane. Part of this protein acts as an
enzyme - ATP synthetase - which uses the diffusion of H+ to synthesise
ATP.
6. The electrons emitted from PSI may:
a) Pass down through the same carrier molecules
as the electrons from PSII, again generating ATP. Before returning to PSI. Thus
electrons are cycled (PSI i carriers i PSI i carriers etc. The energy to begin
this cycle came from light (photo) and is used to convert ADP to ATP i.e. to
phosphorylate ADP (add a phosphate). Hence this process is called cyclic
photophosphorylation (CPP). Or
b) Combine with the hydrogen ions (protons)
released from the photolysis of water to reduce nicotinamide adenine
dinucleotide phosphate (NADP), forming NADPH. Non cyclic photophosphorylation
(NCP) occurs when electrons are emitted from water and then pass to PSII i
carrier (with ATP production) i PSI i carriers i NADPH.
7. Reactions 1-6 make up the Light Dependent
Stage. The ATP and NADPH produced diffuse into the stroma where the Light
Independent Stage occurs (7-11).
8. CO2
combines with a 5C compound called ribulose bisphosphate. This reaction is
catalysed by the enzyme RuBPC.
9. The 6C compound formed immediately splits
into two molecules of glycerate-3-phosphate (GP).
10. The GP molecules are converted into
molecules of triose phosphate (TP) using energy from ATP and the hydrogen atom
from NADPH i.e. the two useful products of the LDS are now used up in the
LIS.
11. Some of the TP is used to regenerate
RuBP.
12. The rest of the TP is used to produce other
essential substances which the plant needs - fats, proteins etc.
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