The Vascular Structure of Plants (Edexcel International A Level Biology): Revision Note
The Vascular Structure of Plants
Plant stems have two main functions in a plant
They provide support
They transport various materials around the plant
Support
Leaves are attached to stems and are responsible for carrying out photosynthesis
Stems ensure that leaves are positioned in order to receive maximum levels of sunlight to perform this task
It also supports flowers in a way that will attract the attention of pollinators
Plant stems need to be strong, but also flexible, in order to withstand the forces of nature (wind, rain etc.)
Transport
Leaves require water and mineral ions in order to photosynthesise and carry out other important functions
The transport tissue in stems provide a route for these substances to travel from the roots to the leaves
The products of photosynthesis also need to be transported from the tissue where photosynthesis happens to where these substances are needed
Stems provide a transport route for this to occur
Vascular structure of plants
Plant stems are made up of different types of plant tissue
The focus will be on the following tissue types:
Xylem
Phloem
Sclerenchyma
Xylem and phloem are collectively known as vascular tissue
They are responsible for transporting various substances around the plant
Sclerenchyma fibres are associated with the vascular bundles and provide additional support to a stem
Xylem and phloem are arranged in structures known as vascular bundles
The arrangement of xylem and phloem differs in the different plant organs
In a stem, the xylem vessels are always located towards the middle of the stem, while the phloem can be found closer towards the outside of the stem
The arrangement of vascular tissue (xylem and phloem) in roots, stems and leaves
Sclerenchyma
Sclerenchyma fibres are not involved in the transport of substances, they provide support
They consist of bundles of dead cells which form long, hollow tubes, but they do have end walls present
Lignification of cell walls occur, which provides structural support to allow the plant to bear the load of its own mass
They have more cellulose in their walls compared to other plant cells
Xylem
Xylem vessels
The functions of xylem tissue in a plant are:
Vascular tissue that transports dissolved minerals and water around the plant
Structural support
Their cell walls contain lignin, which enables the vessels to withstand the pressure created by the moving column of water
Xylem vessels form long, hollow straw-like structures that are formed by dead cells (due to lignification of cell walls)
This means that they do not contain any cytoplasm or organelles that could slow down the flow of water
There are small regions in the walls that are not lignified, known as pits, which allows for lateral movement of water and minerals between xylem vessels
Images of xylem vessel elements: A = photomicrograph (drawing) in longitudinal section (lignin is stained red), B = scanning electron micrograph (drawing) in transverse section, C = microscope image (drawing) in transverse section (lignin is stained purple)
Structure and Function of Xylem Vessels Table
Phloem
Phloem tissue
The functions of phloem tissue in a plant are:
Transport organic compounds (assimilates), particularly sucrose, from sources (e.g. leaves) to sinks (e.g. roots). The transport of these compounds can occur up and down the plant
This is known as translocation
Phloem has no support function in a plant
The organic compounds are dissolved in water to form sap
Phloem is a complex tissue made up of various cell types; its bulk is made up of sieve tube elements which are the main conducting cells and companion cells
Other cell types of phloem tissue also include parenchyma for storage, and strengthening fibres
Mature phloem tissue contains living cells, unlike xylem tissue
Structure of phloem tissue: A = microscope slide image (and below drawing) of a sieve tube element and companion cell in transverse section, B = photomicrograph image (and below drawing) of a sieve tube element and companion cell in longitudinal section
Structure of phloem tissue: C = transmission electron micrograph image (and drawing) of a sieve tube element and companion cell in transverse section
Sieve tube elements
Sieve tube elements line up end to end to form a continuous tube
Phloem Sieve Tube Elements Structure & Function Table
Companion cells
Each sieve tube element has a companion cell associated with it as companion cells control the metabolism of their associated sieve tube member
They also play a role in loading and unloading of sugars into the phloem sieve tube elements
Phloem Companion Cells Structure & Function Table
Examiner Tips and Tricks
Understand the difference between sieve tube elements and companion cells, and how they are different to xylem tissue. Remember that mature xylem tissue is dead, so there is no evidence of organelles, and they have lignified cell walls, whereas sieve tube elements have no lignin, have sieve plates and companion cells that contain nuclei and cytoplasm.
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