1. Botany: Part III Plant Nutrition

2. Figure 36.2-1 H 2 O and minerals H2OH2O Plant Nutrition and Transport Water and minerals in the soil are absorbed by the roots. Transpiration, the loss of water from leaves (mostly through stomata), creates a force within leaves that pulls xylem sap upward.

3. Transpiration 3

4. Set Up Transpiration Lab 4

5. Macro- and Micro- Nutrients Macronutrients are required by plants in relatively large amounts and compose much of the plant’s structure. (C, N, O, P, S, H, K, Ca, Mg, Si, etc. ) Micronutrients are needed in very small quantities. Typically function as cofactors. 5

6. Figure 36.2-2 H 2 O and minerals O2O2 CO 2 O2O2 H2OH2O Gas exchange occurs through the stomata. CO 2 is required for photosynthesis and O 2 is released into the atmosphere. Roots exchange gases with the air spaces in the soil, taking in O 2 and releasing CO 2.

7. Figure 36.2-3 H 2 O and minerals O2O2 CO 2 O2O2 H2OH2O Light Sugar Sugars are produced by photosynthesis in the leaves. Phloem sap(green arrows) can flow both ways. Xylem sap(blue arrows) transport water and minerals upward from roots to shoots.

8. Root pressure is caused by active distribution of mineral nutrient ions into the root xylem. Without transpiration to carry the ions up the stem, they accumulate in the root xylem and lower the water potential. At night in some plants, root pressure causes guttation or exudation of drops of xylem sap from the tips or edges of leaves as pictured here. 8 Water Is In The Root, So Now What?

9. Water then diffuses from the soil into the root xylem due to osmosis. Root pressure is caused by this accumulation of water in the xylem pushing on the rigid cells. Root pressure provides a force, which pushes water up the stem, but it is not enough to account for the movement of water to leaves at the top of the tallest trees. 9 Water Is In The Root, So Now What?

10. 10 Let’s Apply Some TACT To The Situation! A more likely scenario involves the Cohesion-Tension Theory ( also known as Tension-Adhesion-Cohesion-Transpiration or TACT Theory) T ension : Water is a polar molecule.  When two water molecules approach one another they form an intermolecular attraction called a hydrogen bond.  This attractive force, along with other intermolecular forces, is one of the principal factors responsible for the occurrence of surface tension in liquid water.  It also allows plants to draw water from the root through the xylem to the leaf.

11. 11 Let’s Apply Some TACT To The Situation! Adhesion occurs when water forms hydrogen bonds with xylem cell walls. Cohesion occurs when water molecules hydrogen bond with each other.

12. 12 Let’s Apply Some TACT To The Situation! Transpiration: Water is constantly lost by transpiration in the leaf. When one water molecule is lost another is pulled along by the processes of cohesion and adhesion. Transpiration pull, utilizing capillary action and the inherent surface tension of water, is the primary mechanism of water movement in plants.

13. 13 Generation of Transpiration Pull

14. Ode To The Hydrogen Bond

15. Ascent of Xylem Sap 15

16. Wilting Turgor loss in plants causes wilting – Which can be reversed when the plant is watered

17. Stomata Regulate Transpiration Rate 17 When water moves into guard cells from neighboring cells by osmosis, they become more turgid. The structure of the guard cells’ wall causes them to bow outward in response to the incoming water. This bowing increases the size of the pore (stomata) between the guard cells allowing for an increase in gas exchange.

18. Homeostasis and Water Regulation 18 By contrast, when the guard cells lose water and become flaccid, they become less bowed, and the pore (stomata) closes. This limits gas exchange.

19. Role Of Potassium Ion In Stomatal Opening And Closing 19 H2OH2O H2OH2O H2OH2O H2OH2O H2OH2O K+K+ H2OH2O H2OH2O H2OH2O H2OH2O H2OH2O The transport of K + (potassium ions, symbolized here as red dots) across the plasma membrane and vacuolar membrane causes the turgor changes of guard cells.

20. Homeostasis and Water Balance 20 Trees that experience a prolonged drought may compensate by losing part of their crown as a consequence of leaves dying and being shed. Resources may be reallocated so that more energy is expended for root growth in the “search” for additional water.

21. Natural Selection and Arid Environments 21

22. Natural Selection and Arid Environments 22 Plants that have adapted to arid environments have the following leaf adaptations: 1.Leaves that are thick and hard with few stomata placed only on the underside of the leaf 2.Leaves covered with trichomes (hairs) which reflect more light thus reducing the rate of transpiration 3.Leaves with stomata located in surface pits which increases water tension and reduces the rate of transpiration 4.Leaves that are spine-like with stems that carry out photosynthesis (cacti) and store water.

23. Natural Selection and Flooding 23 Plants that experience prolonged flooding will have problems. Roots underwater cannot obtain the oxygen needed for cell respiration and ATP synthesis. As a result, leaves may dry out causing the plant to die. Additionally, production of hormones that promote root synthesis are suppressed.

24. Adaptations to Water Environments 24

25. Adaptations to Water Environments 25 Plants that have adapted to wet environments have the following adaptations: 1.Formation of large lenticels (pores) on the stem. 2.Formation of adventitious roots above the water that increase gas exchange. 3.Formation of stomata only on the surface of the leaf (water lilies). 4.Formation of a layer of air-filled channels called aerenchyma for gas exchange which moves gases between the plant above the water and the submerged tissues.

26. Bulk Flow of Photosynthetic Products 26 Vessel ( xylem ) H2OH2O H2OH2O Sieve tube (phloem) Source cell (leaf) Sucrose H2OH2O Sink cell (storage root) 1 Sucrose Loading of sugar (green dots) into the sieve tube at the source reduces water potential inside the sieve-tube members. This causes the tube to take up water by osmosis. 2 4 3 1 2 This uptake of water generates a positive pressure that forces the sap to flow along the tube. The pressure is relieved by the unloading of sugar and the consequent loss of water from the tube at the sink. 3 4 In the case of leaf-to-root translocation, xylem recycles water from sink to source. Transpiration stream Pressure flow

27. Nutritional Adaptations in Plants Epiphytes- grow on other plants, but do not harm their host Parasitic Plants-absorb water, minerals, and sugars from their host Carnivorous Plants- photosynthetic but supplement their mineral diet with insects and small animals; found in nitrogen poor soils 27

28. Halophytes 28

29. Adaptations of Plants: Saline Environments 29 Soil salinity around the world is increasing. Many plants are killed by too much salt in the soil. Some plants are adapted to growing in saline conditions (halophytes) Have spongy leaves with water stored that dilutes salt in the roots Actively transport the salt out of the roots or block the salt so that it cannot enter the roots Produce high concentrations of organic molecules in the roots to alter the water potential gradient of the roots

30. Plant Adaptation Project Today, you will create a skit that focuses on a specific type of environment and the adapations that plants need to survive in that environment. The skit needs to be less than 5 mintues. Please include – Explanation of the specific type of environment – Summary of how the plant is adapted to the environment – Key molecules identified (ex: water, salt, etc.) – Support for how the adaptation ensures reproductive success – Relate the adaptations to specific real-world examples – Prediction of what would occur if the plant did not have that adapation 30