Plant Transport

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Vascular tissue = term used to describe xylem and phloem vessels
Stele of plant helps resist vertical stress and anchors the plant in the soil
In dicotyledon stem, xylem provides flexible support and resist bending the stem
What plants transport and why:
water - for transport of other solutes, cooling via evaporation, photosynthesis
nitrates - to synthesise amino acid, nucleic acids (ATP)
magnesium - chlorophyll, phosphates (synthesis ATP + phospholipids), calcium (strength in cell wall)
Root hair cells in plants have a very large surface area, allowing more water to enter via osmosis down a water potential gradient
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The soil solution, a dilute solution of mineral ions, has a higher water potential than the vacuole, creating a water potential gradient for diffusion to occur
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When there is low water potential in the soil, water needs to be transported via active transport through carrier proteins using energy in the form of ATP
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High mineral ion concentration is transported across a cell membrane by facilitated diffusion through channel or carrier proteins down the concentration gradient
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From root hair to xylem:
apoplast pathway - water + solutes travel through the cell wall -> once it hits the casparian strip, it diffuses into the cytoplasm and continues travelling in the symplast pathway
symplast pathway - water + solutes travel through cytoplasm and plasmodesmata
vacuolar pathway - water + solutes travel through vacuolar, cytoplasm and plasmodesmata
Casparian strip - made of Suberin and is impermeable to water (hydrophobic)
From endodermis, water moves into the xylem via osmosis down a water potential gradient
From endodermis, mineral ions are actively transported using ATP into xylem which lowers the water potential in the xylem -> water moves in by osmosis down a water potential gradient

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