Water Loss
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Jun 02, 2014
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About This Presentation
Principles of plant physiology , Jimma university college of Agr,
2008
Slide Content
WATER LOSS
Water is the most abundant constituent of plant
tissue
Except in dry seeds
Large amount of water is absorbed by the roots
Carried to the top of the plant
Lost by the aerial part in the form of water vapour or
rely in the form of liquid
The loss of water from the living tissue of aerial parts
of the plant in the form of water vapour is termed
TRANSPIRATIN
Beira H.Meressa , 2008
tissue
Except in dry seeds
Large amount of water is absorbed by the roots
Carried to the top of the plant
Lost by the aerial part in the form of water vapour or
rely in the form of liquid
The loss of water from the living tissue of aerial parts
of the plant in the form of water vapour is termed
TRANSPIRATIN
Beira H.Meressa , 2008
Transpiration is due to the anatomical features of plants
Those of leaves
Transpiration is the phenomenon most responsible for
excessive water loss from plants
Other process are also involved
Guttation
Secretion – loss of solution from glands
Bleeding - the slow exudation of water solution from a cut made
in a plant tissue
Beira H.Meressa , 2008
Those of leaves
Transpiration is the phenomenon most responsible for
excessive water loss from plants
Other process are also involved
Guttation
Secretion – loss of solution from glands
Bleeding - the slow exudation of water solution from a cut made
in a plant tissue
Beira H.Meressa , 2008
GUTTATION
Explains the relationship of root pressure to the rate of
water loss from the top of the plant
It the exudation of water from plants in the form of liquid
along the margin or tip of the leaf blade
The amount of water lost by this process is negligible
Beira H.Meressa , 2008
Explains the relationship of root pressure to the rate of
water loss from the top of the plant
It the exudation of water from plants in the form of liquid
along the margin or tip of the leaf blade
The amount of water lost by this process is negligible
Beira H.Meressa , 2008
Factors favouring Guttation
High water absorption
High root pressure
Low or no transpiration
Under these conditions water absorption greatly
exceeds transpiration
Water is forced up the xylem ducts and out through
endings in the leaves
Does as a result of hydrostatic pressure developed in
the sap of xylem duct
Beira H.Meressa , 2008
High water absorption
High root pressure
Low or no transpiration
Under these conditions water absorption greatly
exceeds transpiration
Water is forced up the xylem ducts and out through
endings in the leaves
Does as a result of hydrostatic pressure developed in
the sap of xylem duct
Beira H.Meressa , 2008
Guttation occurs
Through hydathodes – specialized pores at the
extreme tip of the leaf
As exudation directly through the epidermis
Herbaceous plants
Laminal guttation
Through leaf scar and lenticels (from stem)
Beira H.Meressa , 2008
Through hydathodes – specialized pores at the
extreme tip of the leaf
As exudation directly through the epidermis
Herbaceous plants
Laminal guttation
Through leaf scar and lenticels (from stem)
Beira H.Meressa , 2008
Guttation fluid is not pure
Chemical compassion
Mineral salts
Sugar
Amino acids
Enzymes
Vitamins
Hence considerable injury
To leaves when salts are concentrated on the leaves
surface when the guttated liquid evaporates rapidly
To messopyll tissues as minerals left by guttation are
dissolved and drawn back in to the interior of the leaf
Beira H.Meressa , 2008
Chemical compassion
Mineral salts
Sugar
Amino acids
Enzymes
Vitamins
Hence considerable injury
To leaves when salts are concentrated on the leaves
surface when the guttated liquid evaporates rapidly
To messopyll tissues as minerals left by guttation are
dissolved and drawn back in to the interior of the leaf
Beira H.Meressa , 2008
FEATURES
Usually small and occurs in the night and early in the
morning
Also during day time
In plants growing in humid air and moist warm soil
Lost in the form of liquid
Guttated water is not pure
Uncontrolled process
Mostly occurs through special pores called
hydathodes
Expression of positive root pressure
Beira H.Meressa , 2008
Usually small and occurs in the night and early in the
morning
Also during day time
In plants growing in humid air and moist warm soil
Lost in the form of liquid
Guttated water is not pure
Uncontrolled process
Mostly occurs through special pores called
hydathodes
Expression of positive root pressure
Beira H.Meressa , 2008
Does not occur in plants growing in:
Cold or dry soil
Soils with a high concentration of solute
Soils with poor aeration
Soil with mineral deficiency
Beira H.Meressa , 2008
Cold or dry soil
Soils with a high concentration of solute
Soils with poor aeration
Soil with mineral deficiency
Beira H.Meressa , 2008
Transpiration
Loss of water vapour from living plants
From any part of the plant exposed to the air
However the leaves are the principal organs of
transpiration
Incidental due to the structural arrangements of
plants for exit and entry of gasses
Photosynthesis–transpiration paradox
Beira H.Meressa , 2008
Loss of water vapour from living plants
From any part of the plant exposed to the air
However the leaves are the principal organs of
transpiration
Incidental due to the structural arrangements of
plants for exit and entry of gasses
Photosynthesis–transpiration paradox
Beira H.Meressa , 2008
General feature
Occurs during day time
The water is lost in the form of vapour
Water lost is pure
Takes place through stomata, lenticels and cuticle
Controlled by the activity of guard cells
Only living cells are involved in the process
Beira H.Meressa , 2008
Occurs during day time
The water is lost in the form of vapour
Water lost is pure
Takes place through stomata, lenticels and cuticle
Controlled by the activity of guard cells
Only living cells are involved in the process
Beira H.Meressa , 2008
Magnitude of water lost by transpiration
Is very high
Zea maize (ml)
Water occurring as constituent...............1872 ml
Water used in metabolic activities............250 ml
Water transpired ..................................202,106 ml
Total water used in growing season.....204,228 ml
Beira H.Meressa , 2008
Is very high
Zea maize (ml)
Water occurring as constituent...............1872 ml
Water used in metabolic activities............250 ml
Water transpired ..................................202,106 ml
Total water used in growing season.....204,228 ml
Beira H.Meressa , 2008
Is transpiration vital or lethal phenomena ?
‘‘ is a necessary evil’’
Beira H.Meressa , 2008
‘‘ is a necessary evil’’
Beira H.Meressa , 2008
Dangerous
Plants die because transpiration exceeds the amount
of water absorbed
Consumes energy of the plant
Causes un necessary absorption of excess water by
plant root
PLANTS SERVE AS A PIPE CONECTING THE SOIL
AND THE AIR
Beira H.Meressa , 2008
Plants die because transpiration exceeds the amount
of water absorbed
Consumes energy of the plant
Causes un necessary absorption of excess water by
plant root
PLANTS SERVE AS A PIPE CONECTING THE SOIL
AND THE AIR
Beira H.Meressa , 2008
Significance
It is the ‘engine’ that pulls water up from the root
helps in the ascent of sap
Brings mineral salts and water from the root
Relief to the plant : evaporates excess amount of water
Translocation of food from one portion of the plant to the
other
Affects the opening and closing of stomata : influences
the process of photosynthesis and respiration
Beira H.Meressa , 2008
It is the ‘engine’ that pulls water up from the root
helps in the ascent of sap
Brings mineral salts and water from the root
Relief to the plant : evaporates excess amount of water
Translocation of food from one portion of the plant to the
other
Affects the opening and closing of stomata : influences
the process of photosynthesis and respiration
Beira H.Meressa , 2008
Maintains a suitable temperature for the leaves
Leaves exposed to direct sun light absorb large
quantities of radiant energy which, unless dissipated in
some other way, will be converted in to heat energy and
rise the temperature of the leaves
But since transpiration is energy consuming process, the
loss of water from leaves dissipates most of the excess
energy absorbed by the leaves
Eg. Euphorbia remains 10-20
o
C higher than the air
because of low transpiration due to structural
modification
Beira H.Meressa , 2008
Leaves exposed to direct sun light absorb large
quantities of radiant energy which, unless dissipated in
some other way, will be converted in to heat energy and
rise the temperature of the leaves
But since transpiration is energy consuming process, the
loss of water from leaves dissipates most of the excess
energy absorbed by the leaves
Eg. Euphorbia remains 10-20
o
C higher than the air
because of low transpiration due to structural
modification
Beira H.Meressa , 2008
Kinds of Foliar transpiration
I.Stomatal transpiration
Stomatal pores are involved
Controlled by guard cells
Maximum transpiration of water vapour takes
place through stomata ......80-90 % of total loss
Beira H.Meressa , 2008
I.Stomatal transpiration
Stomatal pores are involved
Controlled by guard cells
Maximum transpiration of water vapour takes
place through stomata ......80-90 % of total loss
Beira H.Meressa , 2008
II.Cuticular transpiration
Cuticles are wax-like layer covering on the epidermis
of leaves and herbaceous stem
Its thickness varies from plant to plant
Some cracks on the layer increases water loss..20%
Transpiration is high when the layer is thin
Pores are not involved
Herbaceous stem
Flower parts
Fruits
Beira H.Meressa , 2008
Cuticles are wax-like layer covering on the epidermis
of leaves and herbaceous stem
Its thickness varies from plant to plant
Some cracks on the layer increases water loss..20%
Transpiration is high when the layer is thin
Pores are not involved
Herbaceous stem
Flower parts
Fruits
Beira H.Meressa , 2008
III.Lenticular transpiration
Pores with uncontrolled opening and closing are
involved called lenticels
Lenticels are areas in the bark which are filled with
loosely arranged cells: complementary cells
Contributes about 0.1 % of the total loss
oNegligible in comparison to total loss by the whole plant
oFruits
oTubers
Beira H.Meressa , 2008
Pores with uncontrolled opening and closing are
involved called lenticels
Lenticels are areas in the bark which are filled with
loosely arranged cells: complementary cells
Contributes about 0.1 % of the total loss
oNegligible in comparison to total loss by the whole plant
oFruits
oTubers
Beira H.Meressa , 2008
The amount of water lost through cuticular and
lenticular transpiration is significant only under dry
conditions
WHY ???
Beira H.Meressa , 2008
lenticular transpiration is significant only under dry
conditions
WHY ???
Beira H.Meressa , 2008
Measurements of transpiration
The amount of water vapour transpired by a plant can
be measures by several methods:
Weighing method
Potometer
The water vapour given off by plants may be collected,
condensation and weighted
Cuvette method
Beira H.Meressa , 2008
The amount of water vapour transpired by a plant can
be measures by several methods:
Weighing method
Potometer
The water vapour given off by plants may be collected,
condensation and weighted
Cuvette method
Beira H.Meressa , 2008
Weighing method
Weigh a potted plant at the beginning of the experiment
Cover the soil surface and wrap with some water repellent
material such as Al foil to retard evaporation from the
surface other than the plant
Weigh the potted plant at the end of a prescribed period
of time
Then, the loss of weight by the plant over short period of
time will be due to transpiration
Beira H.Meressa , 2008
Weigh a potted plant at the beginning of the experiment
Cover the soil surface and wrap with some water repellent
material such as Al foil to retard evaporation from the
surface other than the plant
Weigh the potted plant at the end of a prescribed period
of time
Then, the loss of weight by the plant over short period of
time will be due to transpiration
Beira H.Meressa , 2008
Mechanisms of Stomatal movement
Stomata are microscopic pores and are bordered by
two specialized epidermal cells
Guard cell control the opening and closing of stomata
The immediate cause is a change in the turger of the
guard cells
Beira H.Meressa , 2008
Stomata are microscopic pores and are bordered by
two specialized epidermal cells
Guard cell control the opening and closing of stomata
The immediate cause is a change in the turger of the
guard cells
Beira H.Meressa , 2008
When turger develops with in the two guard cells
flanking each stoma, the thin outer walls bulge out
and force the inner walls in to a crescent shape that
opens the stoma.
When the guard cell lose turger , the elastic inner
walls regain their original shape and stoma close
Beira H.Meressa , 2008
flanking each stoma, the thin outer walls bulge out
and force the inner walls in to a crescent shape that
opens the stoma.
When the guard cell lose turger , the elastic inner
walls regain their original shape and stoma close
Beira H.Meressa , 2008
Behaviour of Stomatal movements
Beira H.Meressa , 2008
Beira H.Meressa , 2008
Beira H.Meressa , 2008
Factors affecting stomatal
movements
Beira H.Meressa , 2008
movements
Beira H.Meressa , 2008
Factors affecting Stomatal movements
1.Light
CARBOHYDRATE FORMATION
Sugar
formation
Osmotic pressure
of cell sap
Endosmosis
I
n
c
r
e
a
s
e
i
n
t
u
r
g
i
d
i
t
y
o
f
g
u
a
r
d
c
e
l
l
s
Stomata
open
Photosynthesis
Hydrolysis
of starch to
sugar
pH
rise
CO2
Beira H.Meressa , 2008
1.Light
CARBOHYDRATE FORMATION
Sugar
formation
Osmotic pressure
of cell sap
Endosmosis
I
n
c
r
e
a
s
e
i
n
t
u
r
g
i
d
i
t
y
o
f
g
u
a
r
d
c
e
l
l
s
Stomata
open
Photosynthesis
Hydrolysis
of starch to
sugar
pH
rise
CO2
Beira H.Meressa , 2008
Potassium uptake
ATP synthesis
proton (H+)pump in the plasma
membrane of the guard cell
increases negativity of the cell
interior
raising its osmotic
pressure of the
cell
Entrance of
water in to the
guard cell
guard cell
turgidity
increases
Beira H.Meressa , 2008
ATP synthesis
proton (H+)pump in the plasma
membrane of the guard cell
increases negativity of the cell
interior
raising its osmotic
pressure of the
cell
Entrance of
water in to the
guard cell
guard cell
turgidity
increases
Beira H.Meressa , 2008
2.Temperature
An increase in temperature causes an increase in stomatal opening up to 25-
30
o
C
Close higher than 30
o
C due to
higher intercellular CO2 concentration by higher rate of respiration
Decrease in enzymatic activities
2.CO
2
concentration
CO2 of the leaves intercellular space controls stomatal movement
Higher CO2 concentration above that fond in the air causes stomata to
close
But exposure to light causes the stomata to open
Why ????
Response of stomata of variegated leaves Vs green leaves
Beira H.Meressa , 2008
An increase in temperature causes an increase in stomatal opening up to 25-
30
o
C
Close higher than 30
o
C due to
higher intercellular CO2 concentration by higher rate of respiration
Decrease in enzymatic activities
2.CO
2
concentration
CO2 of the leaves intercellular space controls stomatal movement
Higher CO2 concentration above that fond in the air causes stomata to
close
But exposure to light causes the stomata to open
Why ????
Response of stomata of variegated leaves Vs green leaves
Beira H.Meressa , 2008
4.Water deficit and ABA accumulation
Water deficit is created in the plant when transpiration
exceeds absorption
Stomata closes to reduce further loss of water
ABA accumulates in the leaves of stressed plants
Triggers closing of the stomata
How ???
Beira H.Meressa , 2008
Water deficit is created in the plant when transpiration
exceeds absorption
Stomata closes to reduce further loss of water
ABA accumulates in the leaves of stressed plants
Triggers closing of the stomata
How ???
Beira H.Meressa , 2008
The receptor activates several
interconnecting pathways
ABA binds to receptor
at the surface of
plasma lemma
membrane of the
guard cells
A rise in pH of the cytosol
Transfer of CO2 from the
vacuole to the cytosol
Stimulates the loss of Cl
-
and organic ions from cell
Blocs the uptake of K+
in to the guard cell
Reduce the
osmotic pressure
of the cell
Reduce turgidity
of guard cell and
cause stomata to
close
Beira H.Meressa , 2008
interconnecting pathways
ABA binds to receptor
at the surface of
plasma lemma
membrane of the
guard cells
A rise in pH of the cytosol
Transfer of CO2 from the
vacuole to the cytosol
Stimulates the loss of Cl
-
and organic ions from cell
Blocs the uptake of K+
in to the guard cell
Reduce the
osmotic pressure
of the cell
Reduce turgidity
of guard cell and
cause stomata to
close
Beira H.Meressa , 2008
Plant factors affecting rate of transpiration
1.Root –shoot ratio
Efficiency of the absorbing surface and evaporating surface control the rate
of transpiration
Increase in root–shoot ratio increases the rate of transpiration
1.Leaf area
The greater the leaf area , the higher will be the magnitude of water loss
Small plants transpire at higher rate than do larger plants on a per unit area
basis
Pruning
Root system of pruned trees provides greater amount of water to a small number of
leaves thus increasing transpiration rate
if so what is the importance of pruning fruit trees ???
Beira H.Meressa , 2008
1.Root –shoot ratio
Efficiency of the absorbing surface and evaporating surface control the rate
of transpiration
Increase in root–shoot ratio increases the rate of transpiration
1.Leaf area
The greater the leaf area , the higher will be the magnitude of water loss
Small plants transpire at higher rate than do larger plants on a per unit area
basis
Pruning
Root system of pruned trees provides greater amount of water to a small number of
leaves thus increasing transpiration rate
if so what is the importance of pruning fruit trees ???
Beira H.Meressa , 2008
3.Leaf modifications
Plants native to dry habitat exhibit structural modification in their
leaves
The leaves of xerophytic plants possess:
Thick cuticle-transpiration is inversely related to cuticle thickness
Thick cell wall
Needle like leaves
Well developed palisade parenchyma
Sunken stomata surrounded by hairs –reduce diffusion rate
Presence hydrophobic compounds (gums, mucilage)
Orientation of leaf
Reduced number of stomata per unit leaf area
Beira H.Meressa , 2008
Plants native to dry habitat exhibit structural modification in their
leaves
The leaves of xerophytic plants possess:
Thick cuticle-transpiration is inversely related to cuticle thickness
Thick cell wall
Needle like leaves
Well developed palisade parenchyma
Sunken stomata surrounded by hairs –reduce diffusion rate
Presence hydrophobic compounds (gums, mucilage)
Orientation of leaf
Reduced number of stomata per unit leaf area
Beira H.Meressa , 2008
Environments factors
Beira H.Meressa , 2008
Beira H.Meressa , 2008
Beira H.Meressa , 2008
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