Factors Affecting Respiration
Respiration is a chemical reaction by which plant cells stay alive.
The process can be represented by the following formula: glucose + oxygen →
carbon dioxide + water (+ energy). Through respiration, plants use oxygen and
produce carbon dioxide.
(2) Effect
of Temperature:
The following eight points will highlight the eight major factors
affecting respiration in Plants.
The eight environmental factors effecting the rate of respiration
are:
(1) Oxygen Content of the Atmosphere
(2) Effect of Temperature
(3) Effect of Light
(4) Effect of Water
Contents
(5) Effect of Respirable
Material
(6) Effect of Carbon Dioxide Concentration
(7) Protoplasmic Conditions and
(8) Other Factors.
(1) Oxygen
Content of the Atmosphere:
The percentage of oxygen in the surrounding atmosphere greatly
influence the rate of respiration. But reduction of the oxygen content of the
air, however, causes no significant lowering in the respiratory rate until the
percentage drops to about 10%. At 5% oxygen definite retardation of respiration
occurs.
As shown in the graph(fig.1.0), with the increase of oxygen
concentration in the atmosphere, the rate of respiration also increases, but
this effect is not as accelerating as might be expected. This response of
plants and their parts depends upon several factors. The plant tissues which
ordinarily have low rate of respiration are not as seriously effected by low
concentration of oxygen as those which have higher rate of respiration.
In certain plants, like rice, on removal of oxygen the rate of
respiration in terms of total carbon dioxide produced actually increases. This
indicates that anaerobic respiration comes into action when oxygen is no longer
available and that the plant, if it has to make up for the relative inefficiency
of this system, has to respire faster.
Like most chemical reactions, the rate of respiration is greatly
influenced by temperature. Estimation of Q 10 of the process for a rise in
temperature from 8° to 18 °C gives a Q 10 of 2, indicating a chemical reaction.
If the rise is at a much higher starting temperature, say between 20° and 30°C,
then the Q 10 may fall below 2. It should be borne in mind that different
plants or plant parts may show considerable variation in regard to optimum
temperature for respiration.
In certain cases the rate of respiration increases at lower
temperature. E. F. Hopkins (1925) reported that the rate of respiration in
white potatoes increases if the temperature in lowered to just above freezing
point. This increase in the rate of respiration is primarily due to increase in
the quantity of respirable materials (such as soluble carbohydrates) which tend
to accumulate in Irish potato at temperature slightly above 0°C.
At temperatures higher than the optimum for respiration, the rate
of respiration (in terms of oxygen utilized and CO2 produced) falls due to
inter-conversions of respirable materials. For instance, fats may be formed
from carbohydrates by a reaction in which carbon dioxide is utilized and oxygen
produced. At very high temperatures, the rate of respiration falls significantly
and may even come to standstill because of protoplasmic injuries
(3) Effect
of Light:
Light has indirect effects on the rate of respiration. With the
increase in light intensity, the temperature of the surrounding atmosphere also
increases thus affecting the rate of respiration. Secondly, the quantity of
respirable material in the plant largely depends upon the rate of
photosynthesis which is directly influenced by light and thirdly, stomata
remain open during daylight and hence rapid exchange of gases takes place
through them.
(4) Effect
of Water Contents:
Over a certain range, water content of the plant tissue greatly
influence its rate of respiration. In most of the storage able seeds the
moisture content is kept below the point which allows a rapid respiration. With
the increase in moisture content, the rate of respiration is likely to go up
with the result a rapid loss of viability will occur and at the same time the
temperature will also rise and the grain may be spoiled (Fig. 4.0).
Unlike most green tissues, xerophytes, lichens and leafy mosses
(Sphagnum species) can be brought to an air-dry condition at low humidity
without any apparent loss in their viability.
(6) Effect
of Carbon Dioxide Concentration:
The rate of respiration is normally not affected by increase of
carbon dioxide concentration in the surrounding atmosphere up to 19%, but as
the concentration increases from 10% to 80%, a progressive decrease in
respiration occurs. Specific response to higher CO2 concentration
varies with the particular kind of tissue and plant. The effect of CO2
concentration is more significant when the temperature and oxygen supply are
low. At a very high concentration of CO2 the plant tissues are injured or even
killed.
(7)
Protoplasmic Conditions:
The young growing tissues which have greater amount of protoplasm
as compare to older tissues, show higher rate of respiration. Their higher rate
of respiration support the meristematic activities of the cells by supplying
large amount of energy. The degree of hydration of the protoplasm in the cells
affects the rate, and mechanical injury to plant tissues will accelerate
respiration.
(8) Other
Factors:
Various chemicals, such as cyanides, azides and fluorides, have
been reported to possess respiration retarding properties through their effect
on respiratory enzymes. Respiration rate may likely be accelerated by low
concentrations of the compounds like ethylene, carbon monoxide, chloroform and
ether.
Chlorides of various minerals, like sodium, potassium, calcium and
magnesium have pronounced effect on the rate of respiration. Monovalent
chlorides, like KCl and NaCl, increase the rate of respiration while the
divalent chlorides, such as MgCl2 and CaCl2 greatly decrease it. Steward and
Preston (1941) found cations to depress respiration and photosynthesis.
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