Translocation in Plants
- Translocation is the biological term used to describe the transport of organic solutes in the phloem tissue
- The liquid that is being transported within the phloem can be referred to as phloem sap
- This phloem sap consists of sugars in the form of sucrose, along with water and other dissolved substances such as amino acids
- These dissolved substances are sometimes referred to as assimilates
- Translocation within phloem tissue transports these organic compounds from regions known as ‘sources’ to regions known as ‘sinks’
Sources and sinks
- Sources are the regions of plants in which organic solutes originate; they can include
- Mature green leaves and green stems
- Photosynthesis in these regions produces glucose which is converted into sucrose before being transported
- Storage organs, e.g. tubers and tap roots, unloading their stored substances at the beginning of a growth period
- Food stores in seeds which are germinating
- Mature green leaves and green stems
- Sinks are the regions of plants where organic compounds are required for growth; they can include
- Meristems that are actively dividing
- Roots that are growing or actively taking up mineral ions
- Young leaves in bud
- Any part of the plant where organic compounds are being stored, e.g. developing seeds, fruits, or storage organs
- Note that sources can become sinks and vice versa, depending on the time of year and the processes taking place inside the plant
Sources and sinks diagram
Phloem adaptations
- The function of phloem tissue in a plant is to transport organic compounds, particularly sucrose, from sources to sinks
- The cells that make up the phloem tissue are highly specialised, meaning that their structure aids their function
- Phloem is a complex tissue made up of different cell types; it is mainly made up of sieve tube elements and companion cells
- Sieve tube cells, or elements, line up end-to-end to form a continuous tube through which phloem sap flows
- The cells are separated by perforated sieve plates which allow the passage of assimilates
- Sieve tube cells have reduced cytoplasm and few organelles to allow the free flow of phloem sap
- Companion cells are closely associated with the sieve tube and aid with the loading and unloading of dissolved substances, or assimilates
- Companion cells contain many mitochondria which generate ATP for the active loading of sucrose into the sieve tube
- Sieve tube cells, or elements, line up end-to-end to form a continuous tube through which phloem sap flows
- Sieve tubes and companion cells are linked by bridges of cytoplasm known as plasmodesmata
Phloem adaptations diagram
Phloem tissue contains sieve tube cells and companion cells
Sieve tube structure and function table
Structure | Function |
Sieve plates | Allows for the continuous movement of the organic compounds between cells |
Cellulose cell wall | Strengthens the wall to withstand the hydrostatic pressures that move the assimilates |
No nucleus, vacuole or ribosomes in mature cells | Maximises the space for the translocation of assimilates |
Thin cytoplasm | Reduces friction to facilitate the movement of assimilates |
Companion cell structure and function table
Structure | Function |
Nucleus and other organelles | Provides metabolic support to sieve tube elements |
Transport proteins in plasma membrane | Moves assimilates into and out of the sieve tube elements |
Many mitochondria | Provide ATP for the active transport of assimilates into or out of the companion cells |
Plasmodesmata | Link with sieve tube elements to allow assimilates to move from the companion cells into the sieve tubes |
Translocation
- The loading and unloading of sucrose and other organic compounds from the source to the phloem, and from the phloem to the sink is an active process, meaning that it requires energy in the form of ATP
- A summary of the process is
- Active transport is used to load organic compounds into the phloem at the source
- The high concentrations of solutes in the phloem at the source lower the water potential and cause water to move into the phloem vessels by osmosis
- Water can move in from the neighbouring xylem vessels
- This results in a raised hydrostatic pressure and generates a hydrostatic pressure gradient between the source and the sink; this causes the contents of the phloem to flow towards the sink down a pressure gradient
- Hydrostatic pressure refers to the pressure exerted by a fluid on the walls of its container; in this case the walls of the phloem
- At the same time sucrose is being unloaded from the phloem at the sink, lowering the water potential of the cells of the sink
- Water follows by osmosis, maintaining the hydrostatic pressure gradient between the source and the sink
Exam Tip
Remember that direction of movement in the phloem is determined by the locations of the source and the sink, so can be either upward or downward.
Understand the difference between sieve tube elements and companion cells, and make sure that you can describe how the structure of sieve tube cells is related to their function