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Plant nutrition

Plant nutrition. What you need to know about Plant Nutrition. The important elements required by plants. How those elements become available in the soil. How plants take those elements up from the soil. Nitrogen fixation in the soil and its importance. What is meant by “plant nutrition”.

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Plant nutrition

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  1. Plant nutrition

  2. What you need to know about Plant Nutrition The important elements required by plants How those elements become available in the soil How plants take those elements up from the soil Nitrogen fixation in the soil and its importance

  3. What is meant by “plant nutrition” Uptake from the soil of mineral elements “Plant nutrition” specifically does not refer to photosynthesis. In this lecture the uptake of nutrients from the soil directly by roots In the next lecture mutualistic relationships between plants and fungi and microrganisms Minerals

  4. The chemical elements required by plants Plants require 13 mineral nutrient elements for growth. The elements that are required or necessary for plants to complete their life cycle are called essential plant nutrients. Each has a critical function in plants and are required in varying amounts in plant tissue, see table on next slide for typical amounts relative to nitrogen and the function of essential nutrients . The nutrient elements differ by their functions in the plant, by their mobility in the plant, and by the plant deficiency or toxicity symptoms characteristic of the nutrient.

  5. 4 5 6 3 Essential Chemical Relative Function in plant Elements symbol % in plant to N Primary macronutrients Nitrogen N 100 Proteins, amino acids Phosphorus P 6 Nucleic acids, ATP Potassium K 25 Catalyst, ion transport Secondary macronutrients Calcium Ca 12.5 Cell wall component Magnesium Mg 8 Part of chlorophyll Sulfur S 3 Amino acids Iron Fe 0.2 Chlorophyll synthesis Micronutrients Copper Cu 0.01 Component of enzymes Manganese Mn 0.1 Activates enzymes Zinc Zn 0.03 Activates enzymes Boron B 0.2 Cell wall component Molybdenum Mo 0.0001 Involved in N fixation Chlorine Cl 0.3 Photosynthesis reactions 1 2

  6. How plants take up mineral elements from soil A. Bulk flow: Uptake in the transpiration stream Nutrients diffuse to regions of low concentration and roots grow into and proliferate in soil zones with high nutrient concentrations (horse manure in sand). Dominant in mineral soils: B. Mycorrhizae: symbiotic relationship with fungi Roots are slow growing but mycorrhizal fungi proliferate and ramify through the soil. Symbiotic relationship: carbon-nitrogen exchange. Dominant in organic soils:

  7. Soil Structure and Development Soil Structure O HORIZON Fallen leaves and other material littering the surface of mineral soil A HORIZON Topsoil, which contains some percentage of decomposed organic material and which is variably deep (only a few centimeters deep in deserts, but elsewhere extending as far as thirty centimeters below the soil surface B HORIZON Compared with the A horizon, larger soil particles, not much organic material, but greater accumulation of minerals; extends thirty to sixty centimeters below soil surface C HORIZON No organic material, but partially weathered fragments and grains of rock from which soil forms; extends to underlying bedrock BEDROCK Fig. 30.3, p. 518

  8. Mineral soils H2OOH- + H+ Mineral soils Nutrients are available through WATER in the soil Soil acidity determines how nutrients become available to plants Small quantities of water molecules dissociate: The concentration of dissociated water in freshly-distilled water is 10-7 M. This is used to describe acidity-alkalinity, originally called the pouvoir Hydrogéne, which we know now as pH. pH = - log [H+] = - log [10-7M] = 7 for fresh distilled water Small values for acid, e.g., the water in Sphagnum bogs can be ~3 Large values for alkaline, e.g., soils on limestone ~8

  9. How clay particles provide nutrients 2H+ Ca2+ A clay particle (much enlarged here) is covered with negative charges, anions: Opposites attract, so metal ions with positive charge(s), cations, stick all over the surface of the clay particle: The root hair cells of plant roots secrete H+ into the water around nearby clay particles. These smaller H cations replace the larger macro- and micro-nutrient cations: The released cations are now available for uptake into roots.

  10. Summary of soil water chemistry In this summary occurrence of H+ in soil water is shown as the result of respiration of CO2 and disassociation of carbonic acid H2CO3 that forms Water flow Hydrogen ions released into the water by respiration or decomposition of organic material exchange with cations on soil particles so releasing them into the soil water solution

  11. root hair epidermis root hairs root (soil) Fig. 30.6, p. 521

  12. Single cell root hairs

  13. Apoplastic and Symplastic Transport • apoplastically, i.e. through the cell walls and intercellular spaces, 2. symplastically, i.e. from protoplast to protoplast via plasmodesmata However, at the endodermis the apoplastic pathway is blocked by a waxy deposit of the wall called the Casparian strip. Water and cations can be taken up by roots: In some plants is the Casparian strip located in the exodermis so that the barrier to apoplastic works sooner.

  14. Casparian strip Cross section of endodermis with the Casparian strip stained pink. The Casparian strip contains suberin and lignin Cross section of Smilax root showing heavily thickened endodermis walls Cross section of Zea mays root using fluorescence microscopy showing thickened cell walls on the inside of endodermis

  15. conducting cell of primary phloem endodermis exodermis root hair conducting cell of primary xylem epidermis newly forming vascular cylinder cells of endodermis Root vascular cylinder cortex In root cortex; water molecules pass through and between walls of cells Casparian strip (gold) within all the abutting walls of cells of the endodermis Casparian strip (gold) vascular cylinder Location of Casparian strip Casparian strip Fig. 30.5, p. 520

  16. Water uptake by the root The ions that have passed through the endodermis are contained within the vascular tissue. Water can then be drawn into the root from the soil by osmosis, the endosmotic root pressure. This can be sufficient to force water up through the xylem and may be particularly important when there is not a strong water potential gradient due to transpiration Some plants have hydathodes at their leaf margins that secrete water as droplets, a process called guttation.

  17. Nitrogen is the element most required by plants, in terms of weight. It is not a product of weathering of soil particles. There are two sources: fixation of atmospheric nitrogen by bacteria decomposition of organic matter, usually decaying plant material.

  18. N-fixing bacteria Nitrogen fixing bacteria Denitrifying bacteria NH4+ammonium Nitrifying bacteria Nitrate Ammonifying bacteria Most uptake from the soil is in the form of nitrate

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