Ch. 4 Plant Physiology
Net flow in whole plants Fig. 36.1 overview of transport in plants Animation 36.1.4 Transpiration Pull (animation ~ 5)
Some Key Concepts Diffusion: movement of molecules from high to low concentration. Osmosis: diffusion across a semi-permeable membrane. Mass or bulk flow: movement of fluid due to pressure or gravity differences.
Long-distance movement of water Plants mostly obtain water & minerals from soil. Water moves up the xylem by bulk flow. Movement of water depends on transpiration pull, cohesion & adhesion of water molecules, capillary forces, and strong cell walls.
Fig. 39.12a
Fig. 39.12b
Ascent of xylem sap transpirational pull flow from greater to lower water concentration relies on cohesion & adhesion of water cavitation breaks chain of water molecules corresponding overheads: Fig. 36.10 roles of cohesion & adhesion in ascent of xylem sap Fig. 36.11 control of stomatal opening & closing
Figure 35.11 Water-conducting cells of xylem
Other mechanisms of water transport not important. Diffusion (note mosses, etc.) Capillary forces Osmotic pressure (guttation)
Fig. 39.11
The availability of soil water and minerals Animation 37.1. (animation~4) Mineral uptake in roots Long-distance transport of water from roots to leaves
Mineral Uptake Key Points Mineral movement to root by diffusion or bulk flow or root growth. Uptake controlled at root endodermis. Uptake by either simple diffusion (no protein), facilitated diffusion (protein channel), or active uptake (requires energy and a protein carrier). Organisms concentrate minerals and most other substances. Usually biggest energy expenditure of roots, cause nutrients are being concentrated.
Movement of sugars Sugars (etc.) move from the source To the sink Photosynthetic leaves Storage organ To the sink Growing organs Developing storage tissue Through mass flow in phloem Pressure Flow Hypothesis
Phloem transport pressure flow high sugar concentration at “source” sugar diluted with water from xylem creating pressure for flow sugar unloaded at “sink” where it is metabolized or converted to starch excess water flows to xylem back to “source” translocation: movement of food from “source” to “sink(s)” sinks may be new leaves, fruit, roots Animation 36.1.1 Transport (bulk flow model) - Animation ~ 6 associated overhead: fig. 36.14 Pressure Flow in a sieve tube Pressure flow in a sieve tube
Transport Movies
Some “hot” areas in plant water and nutrient research Improving plant water-use efficiency Improving salt tolerance Improving nutritional value of plants (e.g., golden rice, increasing Fe content) Phytoremediation
Life on Earth depends on flow of energy from sun
Life processes are driven by energy Plants are dynamic metabolic systems 1000s of reactions occur every second Processes can be energy consuming (endergonic) or energy releasing (exergonic) and catabolic (breakdown) or anabolic (synthesis)
Fig. 8.6
Fig. 8.7
The most common and important forms of cellular energy. Chemical bonds (e.g., ATP, CH2O) Electrons (redox reactions) Electrochemical gradients
Fig. 8.14
Cellular respiration Chemical-bond energy in sugars is converted to energy-rich compound ATP which can then be used for other metabolic reactions
Fig. 9.19
Energy yield depends on oxygen Aerobic (with oxygen) 36 ATP molecules per glucose molecule Anaerobic (without oxygen) 2 ATP molecules per glucose molecule