“Transportation is the process that involves the movement of water and necessary nutrients to all parts of the plant for its survival. “
Transportation is a vital process in plants. Trees transport all the nutrients and water it needs for survival from its roots to the tips of the leaves.
In the case of transportation in plants, the biggest constraint is water as it ends up being a limiting factor in growth. To overcome this problem, trees and other plants have the perfect system for the absorption and translocation of water.
Plants contain a vast network of conduits which consist of xylem and phloem. This is more like the circulatory system that transports blood throughout the human body. Similar to the circulatory system in humans, the xylem and phloem tissues extend throughout the plant. These conducting tissues originate from the roots and move up through the trunks of trees. Later they branch off into the branches and then branching even further into every leaf, like spider webs.
Transportation occurs in three levels in the case of plants:
- Transportation of substance from one cell to another.
- Long-Distance transport of sap within phloem and xylem.
- The release and uptake of solute and water by individual cells.
Let us have a detailed look at the process of absorption and transportation in plants.
Water Absorption In Plants
The water is absorbed in two ways by the plants:
Active Absorption
In the case of active absorption, water moves through symplast and it is absorbed according to the Diffusion Pressure Deficit changes. The rate of absorption is slow. It comprises osmotic and non-osmotic forces.
Humidity and temperature can have an impact. The force required for the absorption of water is mainly generated in the root cells itself. There would be a decrease in the rate of water absorption if the metabolic inhibitors are applied.
Passive Absorption
The rate of absorption is fast. It occurs in rapidly transpiring plants. The movement of plants is through apoplast and it is absorbed due to transpiration pull and it is created due to the stress created in xylem sap. The rate of absorption significantly depends upon the rate of transpiration. The force required for the absorption of water is mainly generated in the mesophyll cells.
Transportation in Plants
The water and minerals are transported in plants by two types of conducting tissues:
- Xylem
- Phloem
Xylem
Xylem is a long, non-living tube running from the roots to the leaves through the stem. The water is absorbed by the root hair and undergoes cell to cell movement by osmosis until it reaches the xylem. This water is then transported through the xylem vessels to the leaves and is evaporated by the process of transpiration.
The xylem is also composed of elongated cells like the phloem. However, xylem is especially accountable for transporting water to all plant parts from the roots. Since they serve such an important function, a single tree would have a lot of xylem tissues.
Phloem
The phloem is responsible for translocation of nutrients and sugar like carbohydrates, produced by the leaves to areas of the plant that are metabolically active. It is made up of living cells. The cells walls of these cells form small holes at the ends of the cells known as sieve plates.
Means of Transportation in Plants
Transportation in plants is by three means, they are as stated below:
- Diffusion
- Facilitated diffusion
- Active Transport
Diffusion
It is a transportation process that involves the passive movement of a substance from cell-to-cell or from one plant part to the cell. Its outcome does not entail energy-expenditure. Here molecules move in a random manner. It is a slow process.
Here the substance moves from higher concentration region to lower concentration region. The diffusion is the only means of transport for gases in case of plants. The rate of diffusion depends on the temperature, pressure, and mainly on a gradient of concentration.
Facilitated Diffusion
The gradient is a vital component for the process of diffusion. Hence, a smaller substance has to be diffused faster when compared to large ones. Facilitated Diffusion is a passive process that comprises antiport, uniport, and symport.
Antiport proteins exchange the solutes by transporting them in and out of the cell. The main function of uniport protein is to carry single solute across the membrane. Symport proteins transfer two different solutes simultaneously in the same direction.
Active Transport
Active transport pumps molecules against the concentration gradient. Here the energy of ATP is used to drive the pump. The ATP donates a phosphate to a particular gateway molecule which then pumps the desired molecule across the membrane.
Driving Forces Responsible For Transportation in Plants
The driving forces responsible for the transportation of water and minerals in plants include:
- Transpiration
- Force of surface tension
- Water potential gradient
- The force of hydrogen bonding between water molecules
Transpiration
Transpiration is the driving force behind uptake and transport of water. It is the process of water evaporation through openings called stomata. This creates a pull by replacing the water that has evaporated. This pull in the xylem tissues extends all the way down due to the cohesive forces. This negative water pressure that occurs in the roots will eventually result in an increase of water uptake from the soil.
Force of Surface Tension
As more molecules evaporate from the water film, there is an increase in the curvature of the meniscus which in turn increases the surface tension. Water from the surrounding cells is pulled towards this area to reduce the tension.
Water Potential Gradient
Water moves from the roots to the leaves because of the water potential gradient. The water potential gradient is the highest in the water surrounding the roots and lowest in the airspace within the spongy parenchyma.
The force of Hydrogen Bonding between Water Molecules
The water molecules stick to each other by hydrogen bonds. The above forces are communicated to water molecules within the xylem through the hydrogen bonds.
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