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Plant Nutrition
The uptake of nutrients occurs at both the roots
and the leaves.
• Roots, through mycorrhizae
and root hairs, absorb water
and minerals from the soil.
• Carbon dioxide diffuses into
leaves from the surrounding
air through stomata.
• About 80 - 85% of a herbaceous plant is water
• Of the 15-20% of a herbaceous plant that is not
water, about 95% of the dry weight is organic
substance and the remaining 5% is inorganic
substance.
• Most of the dry weight of a plant is the result of
uptake of CO2 through stomata in leaves.
•Carbon, hydrogen, and oxygen are the most
abundant (an important) elements in the dry weight
of a plant
• Hydroponic
cultures can be
used to
determine
essential
nutrients
• Air is bubbled
into the solute
to provide
oxygen to root
cells
Plants require 9 macronutrients
and at least 8 micronutrients
•A particular chemical element is considered an
essential nutrient if it is required for a plant
to grow from a seed and complete the life
cycle.
Plants require 9 macronutrients
and at least 8 micronutrients
• Elements required by plants in relatively
large quantities are macronutrients.
• Elements that plants need in very small
amounts are micronutrients.
Macronutrients
CHNOPS KCaMg
• Carbon, oxygen, hydrogen, nitrogen, sulfur, and phosphorus,
potassium, calcium, and magnesium.
• General Role: They are cofactors in enzymatic reactions.
Element
Taken in as
Needed for
Nitrogen
Nitrates; ammonium salts; as organic
compounds (Nitrogen-fixing bacteria)
To make proteins and nucleic
acids
Phosphorus
Phosphates
nucleic acids, phospholipids, ATP,
several coenzymes
Potassium
Potassium salts
cofactors in protein synthesis;
osmosis; operation of stomata
Magnesium
Magnesium salts
To make chlorophyll
Sulfur
Sulphates
For making proteins; for healthy
root growth
CHNOPS KCaMg
N, P, K
Micronutrients.
Fe, Cl, Cu, Zn, Mn, Mo, B, Ni
• Iron, chlorine, copper, zinc, manganese, molybdenum,
boron, and nickel.
• Required in relatively small amounts.
• Required for a plant to grow from a seed and complete its life cycle.
• Overdoses of them can be toxic
• FUNCTION:
• Most function as cofactors
enzymatic reactions.
(catalytic function)
of
• EX: Fe is a component in cytochromes
• proteins that function in the electron transfer chains of chloroplasts
and mitochondria.
• While the requirement for these micronutrients is so modest
(only one atom of molybdenum for every 16 million hydrogen atoms
in dry materials), a deficiency of a micronutrient can weaken or
The symptoms of a mineral deficiency depend on
the function and mobility of the element
• The symptoms of a mineral deficiency depend
partly on the function of that nutrient in the
plant.
• Ex: Mg deficiency, an ingredient of chlorophyll,
causes yellowing of the leaves, or chlorosis.
Healthy
PO4-deficient
K-deficient
N-deficient
Most Common
Symptoms
Nutritional
Adaptations
• Rhizobium.
Nitrogen Fixation
•Plants cannot use nitrogen in the form of N2.
•It must first be converted to ammonium (NH4+) or
nitrate (NO3-).
Root nodule formation
animation
• The common agricultural practice of crop
rotation exploits symbiotic nitrogen
fixation.
• One year a nonlegume crop such as corn is planted, and the
following year alfalfa or another legume is planted to restore
the concentration of fixed soil nitrogen.
• Often, the legume crop is not harvested but is plowed under
to decompose as “green manure.”
• To ensure the formation of
nodules, the legume seeds
may be soaked in a culture
of the correct Rhizobium
bacteria or dusted with
bacterial spores before
sowing.
Almost all plant species produce mycorrhizae
• Mycorrhizae take two major forms:
ectomycorrhizae, and endomycorrhizae.
• In ectomycorrhizae, the mycelium forms a
dense sheath over the surface of the root and some
hyphae grow into the cortex in extracellular spaces
between root cells.
• In endomycorrhizae, the
fungus makes extensive
contact with the plant
through branching of
hyphae (arbuscles) that
form invaginations in the
host cells, increasing
surface area for exchange
of nutrients.
Parasitic Plants
Indian pipe
Dodder
Mistletoe
Carnivorous Plants
Sun
Dew
Video
Clip
supplement the plant's supply of
minerals…usually nitrogen
Attenboro
ugh
Video Clip
Epiphytes
• Plants that grow
on other plants
but do not obtain
nutrients from
their hosts
• Derives its
moisture &
nutrients from the
air and rain
(sometimes from
debris
The Role of Soil in Plant Nutrition
• The texture and
chemical composition
of soil are major
factors determining
what kinds of plants
can grow well in a
particular location.
FUNCTIONS
1) Support & anchorage
2) Supplies mineral
nutrients
3) Supplies water
4) Allows gas exchange
- especially 02 and CO2, but
also ethylene
• Inadequate drainage can
dramatically impact
survival of many plants.
– Plants can suffocate if air spaces are
replaced by water.
– Roots can also be attacked by molds
favored by the soaked soil.
– High Clay content can also reduce
gas exchange
• Some plants are adapted
to waterlogged soil.
– For example, mangroves
• Some areas have become unfit for
agriculture or wildlife as the result of
human activities that contaminate the soil
or groundwater with toxic heavy metals or
organic pollutants.
• In place of costly and disruptive remediation
technologies, such as removal and storage of
contaminated soils, phytoremediation takes
advantage of the remarkable abilities of some
plant species to extract heavy metals and
other pollutants from the soil.
• These are concentrated in the plant tissue
where they can be harvested.
• For example, alpine pennycress (Thlaspi
caerulescens) can accumulate zinc in its
shoots at concentrations that are 300 times
the level that most plants tolerate.