Measures of Dispersion and Variability: Range, QD, AD and SD
The dark reaction of photosynthesis in plants
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3. Dark Reaction In Photosynthesis
Photorespiration
Calvin Cycle
Advantages of C4 plants
4. Dark reactions don't require light, but they aren't inhibited by it, either. For most plants, the dark
reactions take place during daytime. The dark reaction occurs in the stroma of the chloroplast. This reaction is
called carbon fixation or the Calvin cycle. In this reaction, carbon dioxide is converted to sugar using ATP and
NADPH. Carbon dioxide is combined with a 5-carbon sugar to form a 6-carbon sugar. The 6-carbon sugar is
broken into two sugar molecules, glucose and fructose, which can be used to make sucrose. The reaction
requires 72 photons of light.
The efficiency of photosynthesis is limited by environmental factors, including light, water, and
carbon dioxide. In hot or dry weather, plants may close their stomata to conserve water. When the stomata are
closed, the plants may start photorespiration. Plants called C4 plants maintain high levels of carbon dioxide
inside cells that make glucose, to help avoid photorespiration. C4 plants produce carbohydrates more
efficiently than normal C3 plants, provided the carbon dioxide is limiting and sufficient light is available to
support the reaction. In moderate temperatures, too much of an energy burden is placed on the plants to make
the C4 strategy worthwhile (named 3 and 4 because of the number of carbons in the intermediate reaction). C 4
plants thrive in hot, dry climates.
5. As its name suggests, RUBISCO catalyzes two different reactions:
• adding CO2 to ribulose bisphosphate — the carboxylase activity
• adding O2 to ribulose bisphosphate — the oxygenase activity.
Which one predominates depends on the relative concentrations of O2 and CO2 with
• high CO2, low O2 favoring the carboxylase action,
• high O2, low CO2 favoring the oxygenase action.
The light reactions of photosynthesis liberate oxygen and more oxygen dissolves in the cytosol of the cell at
higher temperatures. Therefore, high light intensities and high temperatures (above ~ 30°C)
favor the second reaction.
6. The Calvin cycle or Calvin–Benson-Bassham cycle or reductive pentose phosphate cycle or C3
cycle or CBB cycle is a series of biochemical redox reactions that take place in the stroma of chloroplasts in
photosynthetic organisms. It is also known (erroneously) as the "dark reaction" or "dark stage.―
The cycle was discovered by Melvin Calvin, James Bassham, and Andrew Benson at the University
of California, Berkeley by using the radioactive isotope carbon-14. It is one of the light-independent (dark)
reactions, used for carbon fixation.
Photosynthesis occurs in two stages. In the first stage, light-dependent reactions capture the
energy of light and use it to make the energy-storage molecules ATP and NADPH. The light-independent Calvin
cycle uses the energy from short-lived electronically excited carriers to convert carbon dioxide and water into
organic compounds[2] that can be used by the organism (and by animals that feed on it). This set of reactions is
also called carbon fixation. The key enzyme of the cycle is called RuBisCO. In the following biochemical
equations, the chemical species (phosphates and carboxylic acids) exist in equilibria among their various
ionized states as governed by the pH.
The enzymes in the Calvin cycle are functionally equivalent to many enzymes used in other
metabolic pathways such as gluconeogenesis and the pentose phosphate pathway, but they are to be found in
the chloroplast stroma instead of the cell cytoplasm, separating the reactions. They are activated in the light
(which is why the name "dark reaction" is misleading), and also by products of the light-dependent reaction.
These regulatory functions prevent the Calvin cycle from being respired to carbon dioxide. Energy (in the form
of ATP) would be wasted in carrying out these reactions that have no net productivity.
7. The series of reactions in the Calvin Cycle comprise the third major step in photosynthesis. This
step involves the storage of chemical energy in glucose. In this step, CO2 combines with hydrogen in NADPH,
with ATP and NADPH supplying the needed energy. The end product is glucose.
It is important to remember that glucose has much more energy than the raw materials, CO 2 and
water. This is because energy from sunlight has been eventually stored in the glucose molecules. The reactions
in the Calvin Cycle complete the series of changes that light energy undergoes in photosynthesis.
8.
9. Over 8000 species of angiosperms have developed adaptations which minimize the losses to
photorespiration.
They all use a supplementary method of CO2 uptake which forms a 4-carbon molecule instead of the two 3-
carbon molecules of the Calvin cycle. Hence these plants are called C4 plants. (Plants that have only the Calvin
cycle are thus C3 plants.)
• Some C4 plants — called CAM plants — separate their C3 and C4 cycles by time. CAM plants are discussed
below.
• Other C4 plants have structural changes in their leaf anatomy so that
• their C4 and C3 pathways are separated in different parts of the leaf with
• RUBISCO sequestered where the CO2 level is high; the O2 level low.
These adaptations are described now...