The effect of light intensity on the amount of chlorophyll in “Cicer arietinum”
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Provision with minerals. One of the most common reason for shortage of
chlorophyll is absence of some important chemical elements. Shortage of
nitrogen is the most common reason for lack of chlorophyll in old leaves.
Another one is shortage of ferrum, mostly in young leaves and plants. And
ferrum is important element for chlorophyll synthesis. And magnesium is a
component of chlorophyll therefore its shortage causes lack of production
of chlorophyll.
Water. Relatively low water stress lowers speed of chlorophyll synthesis and high dehydration of plants tissues not only disturbs synthesis of chlorophyll, but even causes destruction of already existing molecules.
Oxygen. With the absence of oxygen plants do not produce chlorophyll even on high light intensity. This shows that aerobic respiration is essential for chlorophyll synthesis.
Chlorophyll.[2] The synthesis of chlorophyll is induced by light.
With light, a gene can be transcripted and translated in a protein.
The plants are naturally blocked in the conversion of protochlorophyllide
to chlorophyllide. In normal plants these results in accumulation of a
small amount of protochlorophyllide which is attached to holochrome
protein. In vivo at least two types of protochlorophyllide holochrome are
present. One, absorbing maximally at approximately 650 nm, is immediately
convertible to chlorophyllide on exposure to light. If ALA is given to
plant tissue in the dark, it feeds through all the way to
protochlorophyllide, but no further. This is because POR, the enzyme that
converts protochlorophyllide to chlorophyllide, needs light to carry out
its reaction. POR is a very actively researched enzyme worldwide and a lot
is known about the chemistry and molecular biology of its operation and
regulation. Much less is known about how POR works in natural leaf
development.
ALA Portoporphyrine
Protochlorophyllide
Chlophyllide
Chlorophyll b Chlorophyll a
Chlorophyll[3] is a green compound found in leaves and green stems of
plants. Initially, it was assumed that chlorophyll was a single compound
but in 1864 Stokes showed by spectroscopy that chlorophyll was a mixture.
If dried leaves are powdered and digested with ethanol, after concentration
of the solvent, 'crystalline' chlorophyll is obtained, but if ether or
aqueous acetone is used instead of ethanol, the product is 'amorphous'
chlorophyll.
In 1912, Willstatter et al. (1) showed that chlorophyll was a mixture
of two compounds, chlorophyll-a and chlorophyll-b:
[pic]
Chlorophyll-a (C55H72MgN4O5, mol. wt.: 893.49). The methyl group marked with an asterisk is replaced by an aldehyde in chlorophyll-b (C55H70MgN4O6, mol. wt.: 906.51).
The two components were separated by shaking a light petroleum
solution of chlorophyll with aqueous methanol: chlorophyll-a remains in the
light petroleum but chlorophyll-b is transferred into the aqueous methanol.
Cholorophyll-a is a bluish-black solid and cholorophyll-b is a dark green
solid, both giving a green solution in organic solutions. In natural
chlorophyll there is a ratio of 3 to 1 (of a to b) of the two components.
The intense green colour of chlorophyll is due to its strong
absorbencies in the red and blue regions of the spectrum, shown in fig. 1.
(2) Because of these absorbencies the light it reflects and transmits
appears green.
[pic]
Fig. 1 - The uv/visible adsorption spectrum for chlorophyll.
Due to the green colour of chlorophyll, it has many uses as dyes and pigments. It is used in colouring soaps, oils, waxes and confectionary.
Chlorophyll's most important use, however, is in nature, in photosynthesis. It is capable of channelling the energy of sunlight into chemical energy through the process of photosynthesis. In this process the energy absorbed by chlorophyll transforms carbon dioxide and water into carbohydrates and oxygen:
CO2 + H2O [pic](CH2O) + O2
Note: CH2O is the empirical formula of carbohydrates.
The chemical energy stored by photosynthesis in carbohydrates drives biochemical reactions in nearly all living organisms.
In the photosynthetic reaction electrons are transferred from water to
carbon dioxide, that is carbon dioxide is reduced by water. Chlorophyll
assists this transfer as when chlorophyll absorbs light energy, an electron
in chlorophyll is excited from a lower energy state to a higher energy
state. In this higher energy state, this electron is more readily
transferred to another molecule. This starts a chain of electron-transfer
steps, which ends with an electron being transferred to carbon dioxide.
Meanwhile, the chlorophyll which gave up an electron can accept an electron
from another molecule. This is the end of a process which starts with the
removal of an electron from water. Thus, chlorophyll is at the centre of
the photosynthetic oxidation-reduction reaction between carbon dioxide and
water.
Treatment of cholorophyll-a with acid removes the magnesium ion replacing it with two hydrogen atoms giving an olive-brown solid, phaeophytin-a. Hydrolysis of this (reverse of esterification) splits off phytol and gives phaeophorbide-a. Similar compounds are obtained if chlorophyll-b is used.
[pic]
Chlorophyll can also be reacted with a base which yields a series of phyllins, magnesium porphyrin compounds. Treatment of phyllins with acid gives porphyrins.
[pic]
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