Differentiated by its location and function. Plant Tissue Differentiated by its location and function. 1. Dermal (outermost layer) 2. Ground (bulk of the cell – between dermal and vascular) 3. Vascular (venous system)
Main Tissue Systems 1. Dermal 2. Vascular 3. Ground
Dermal Tissue Epidermis or "skin" of the plant Often has a cuticle, a waxy coating to prevent water loss Functions: Prevent water loss Protects ground tissue Place of gas exchange Usually 1 cell layer thick
Dermal Tissue: Stomata (mouth) Regulated by Guard Cells Turgid: Swell - open stomata. Flaccid: Shrink - close stomata. Controlled by K+ conc. Turgid - Open Flaccid - Closed
Turgor Pressure of Guard Cells Controlled by K+ concentrations
Vascular Tissue Made of Xylem and Phloem Functions: Transport and support Xylem – Water - Phloem - Sugar
Ground Tissue: Mesophyll 1. Palisade upright cells 2. Spongy loosely organized cells with air spaces Function: major sites for Ps
Differentiated by structure. Fundamental Tissues Differentiated by structure. 1. Parenchyma (soft tissue) 2. Collenchyma (glue tissue) 3. Sclerenchyma (hard tissue)
Parenchyma Cells Primary wall only Thin cell wall Alive when mature “Typical" plant cell Function: Ps (photosynthesis) Storage "Filler" cells Cell division (mitosis)
Collenchyma Cells Primary wall only Wall is thickened, especially in the corners Alive when mature Function: Support of non-woody plant parts Ex: veins, stems
Sclerenchyma Cells Secondary wall present Wall strengthened with lignin Dead when mature Function: Support and transport Types: 1. Fibers 2. Sclereids 3. Xylem cells a. tracheids b. vessel members
Observe the different types of tissues in these images!!
How do plants acquire and move materials from one location to another? Transpiration Lab How do plants acquire and move materials from one location to another?
ψ = ψρ + ψs Water Potential The potential energy of water to move from one location to another. Abbreviated as ψ Has two components: Pressure potential: ψρ Solute potential: ψs ψ = ψρ + ψs (Greek letter = psi)
Water always moves from an area of higher water potential (closer to 0) to an area of lower water potential (more negative #).
Water Potential Practice Problems If a plant cell’s ψρ = 2 bars and its ψs = -3.5 bars, what is the resulting ψ (inside the cell)? If this plant is placed in a beaker of sugar water with ψs = -4.0 bars, in which direction will the net flow of water be? Hint: an open beaker has a ψρ = 0 Lastly, the plant is placed in a beaker of sugar water with ψs = -0.15 MPa (megapascals). We know that 1 MPa = 10 bars. In which direction will the net flow of water be?
Answers to Water Potential Practice Problems ψ = ψρ + ψs = 2 bars + (-3.5 bars) = -1.5 bars The ψρ of a solution open to the air is 0. Therefore, the water potential of the sugar water is -4.0 bars [ψ = 0 bars + (-4.0) bars]. Since free water always flows towards the solution with a lower water potential (more negative #), the flow of water would be OUTSIDE of the cell. -1.5 bars (inside cell) > -4.0 bars (beaker) -0.15 MPa = -1.5 bars The water potential of the sugar water is -1.5 bars [ψ = 0 bars + (-1.5) bars]. Since the ψ of the original cell is also -1.5 bars, there would be no net flow of water. The cell and sugar water are in equilibrium.
Bulk Flow The movement of water between two locations due to fluid pressure or tension. Bulk flow is a mechanism for long distance transport in plants. Important in both xylem and phloem sap transport.
How do plants get water to the tops of trees?? TCTM Theory How do plants get water to the tops of trees?? Transpiration Cohesion Tension Mechanism Water evaporates from leaves because water potential of the air is usually much less than that of the cells. Water always moves from an area of higher water potential (closer to 0) to an area of lower water potential (more negative #).
2 Main Factors of Xylem Sap Transport Transpiration (Ts) Root Pressure
Transpiration (Ts) Evaporation of water from aerial plant parts is the major force that pulls xylem sap up tall trees. Xylem sap replaces the water lost due to evaporation. The loss of water from the leaves creates “tension” or negative pressure between the air and the water in the plant.
Xylem Sap (= water, nutrients, inorganic ions) Xylem sap is “pulled” by the resulting tension all the way down the plant to the roots and soil. air (pulls on water in) - leaf - stem - roots – soil Other forces help water flow upward, such as Cohesion: water molecules sticking together by H bonds. Adhesion: water molecules sticking to other materials (cell walls)
Root pressure also assists in the upward movement of xylem sap. Root cells actively transport minerals (solute) into xylem Water potential (ψ) is lowered in roots Higher solute concentration, more -ψ Water potential (ψ) is higher in soil Water flows into roots from soil (roots) (soil)
Guttation is a result of root pressure At night, little transpiration, but water is still entering into roots Excess water may leave plant through guttation.
Environmental Factors In our lab, we learned about some of the environmental factors that affect movement of water through a plant. What are these factors? 1. Humidity 2. Temperature 3. Light 4. Soil Water Content 5. Wind
Phloem Transport Moves sugars (food) Transported in live cells Ex: Sieve & Companion Cells
Source - Sink Transport Model for movement of phloem sap from a Source to a Sink. Source: Sugar production site Sink: Sugar usage site - growth, reproduction, storage Transport around the plant happens in multiple directions
Phloem Transport Source - builds pressure Sink - reduces pressure Pressure caused by: Sugar content changes Water potential changes