Transcript Slide 1

Photosynthesis
Chapter 10
Photosynthesis
• Light energy stored as chemical energy for
future use
• Original source of energy for other
organisms
• Except for a few species of bacteria, all life
depends on the energy-storing reactions
of photosynthesis
Discoveries Leading to the
Understanding of Photosynthesis
Until 17th century, scholars believed that
plants derived the bulk of their substance
from soil humus.
Discoveries Leading to the
Understanding of Photosynthesis
• Joannes van Helmont
– Disproved idea that plants get bulk of
substance from soil humus
• Planted 5 lb. willow in 200 lbs. of dried soil
• Over 5 year time span, only watered plant with
rainwater
• At end of 5 years
– Plant grew from 5 lbs. to 169 lbs.
– Soil only lost 2 oz. during the 5 years
• Reasoned plant substance must have come from
water
Discoveries Leading to the
Understanding of Photosynthesis
• Joseph Priestly
– 1772
– Reported sprig of mint could restore air that
had been made impure by a burning candle
– Plant changed air so mouse could live in it
– Experiment not always successful
• Sometimes didn’t provide adequate light for plant
Discoveries Leading to the
Understanding of Photosynthesis
• Jean Senebier
– 1780
– pointed out that “fixed air,” carbon dioxide was
required for photosynthesis
• Antoine Lavoisier
– Stated that green plants use carbon dioxide
and produce oxygen
Discoveries Leading to the
Understanding of Photosynthesis
• Jan Ingen-Housz
– 1796
– Found that carbon went into the nutrition of
the plant
• Nicolas de Saussure
– 1804
– Observed that water was involved in the
photosynthetic process
Discoveries Leading to the
Understanding of Photosynthesis
• Julius von Sachs
– Between 1862 and 1864 observed
• Starch grains are present in chloroplasts of higher
plants
• If leaves containing starch are kept in darkness for
some time, starch disappears
• If same leaves are exposed to light, starch
reappears in chloroplasts
• First person to connect appearance of starch
(carbohydrate) with both fixation of carbon in the
chloroplasts and the presence of light
Discoveries Leading to the
Understanding of Photosynthesis
• Cornelis van Niel
– 1930s
– Compared photosynthesis in different groups of
photosynthetic bacteria
• Green and sulfur bacteria use H2S instead of H2O to reduce
CO2
• Found that sulfur was liberated instead of O2
• Since sulfur could only come from H2S, van Niel reasoned
that O2 liberated by higher plants comes from H2O not CO2
Discoveries Leading to the
Understanding of Photosynthesis
• Cornelis van Niel
– His general equation for photosynthesis
light
6CO2 + 12H2A
Carbon
dioxide
Hydrogen
donor

C6H12O6 + 6H2O + 12A
carbohydrate
water
A
H2A could be H2O, H2S, H2 or any molecule capable of donating an
electron. Reaction requires energy input. When H2A gives up electrons, it
is oxidized to A.
Specific Photosynthetic
Reactions
• T.W. Engelmann
– Between 1883 and 1885
– Demonstrated which colors of light are used
in photosynthesis
– Found that red and blue light were trapped by
algal photosynthetic organelles
Specific Photosynthetic
Reactions
• J. Reinke
– Studied effect of changing the intensity of light on
photosynthesis
– Observed rate of photosynthesis increased
proportionally to increase in light intensity at low-tomoderate light intensities
– At greater light intensities, rate of photosynthesis was
not affected by changing light intensities
– Indicated reaction was already proceeding at
maximum rate
Specific Photosynthetic
Reactions
• F.F. Blackman
– 1905
– Reasoned photosynthesis could be divided
into two general parts
• Photochemical reactions (light reactions)
• Temperature-sensitive reactions (previously called
dark reactions)
Specific Photosynthetic
Reactions
• Photochemical reactions
– Light reactions
– Insensitive to temperature changes
• Temperature-sensitive reactions
– Previously called dark reactions
– Enzymatic reactions
– Do not depend directly on light
– Chloroplast proteins, thioredoxins, regulate
activities of some dark reactions
Chloroplast Research
• Robin Hill
– 1932
– Demonstrated chloroplasts isolated from cell
could still trap light energy and liberate
oxygen
• Daniel Amon
– 1954
– Proved isolated chloroplasts could convert
light energy to chemical energy and use this
energy to reduce CO2
Chloroplast Structure
• Double-membrane envelope
• Two types of internal membranes
– Grana (singular, granum)
– Stroma lamella – interconnect grana
• Stroma
– Made up of grana and stroma lamella
Division of Labor in Chloroplasts
• Research has shown that
– Intact chloroplasts carry out complete process
of photosynthesis
– Broken plastids
• Carry out only part of photosynthetic reactions
• Will liberate oxygen
Division of Labor in Chloroplasts
• Division of labor
– Green thylakoids
•
•
•
•
Capture light
Liberate O2 from H2O
Form ATP from ADP and phosphate
Reduce NADP+ to NADPH
– Colorless stroma
• Contain water-soluble enzymes
• Captures CO2
• Uses energy from ATP and NADPH in sugar synthesis
Characteristics of Light
• Two models describing nature of light
– Interpret light as electromagnetic waves
– Light acts as if it were composed of discrete
packets of energy called photons
Characteristics of Light
• Light is small portion of electromagnetic energy
spectrum that comes from sun
• Longest waves
– Cannot see
– Infrared and radio waves
– Longer than visible red wavelength
• Shortest waves
– Cannot see
– Ultraviolet waves, X-rays, gamma rays
– Shorter than violet
Characteristics of Light
• White light (visible light)
– Separate into component colors to form
visible spectrum
– Visible wavelengths range from
• Red (640 – 740 nm)
• Violet (400 – 425 nm)
Photons
• Packet of energy making up light
• Contains amount of energy inversely
proportional to wavelength of light
characteristic for that photon
– Blue light has more energy per photon than
does red light
Photons
• Only one photon is absorbed by one
pigment molecule at a time
• Energy of photon is absorbed by an
electron of pigment molecule
– Gives electron more energy
Absorption of Light Energy by
Plant Pigments
• Spectrophotometer
– Instrument used to measure amount of specific
wavelength of light absorbed by a pigment
– Absorption spectrum
• Graph of data obtained
• Chlorophyll
– Reflects green light
– Absorbs blue and red wavelengths
• Wavelengths used in photosynthesis
Absorption of Light Energy by
Plant Pigments
• Chlorophyll
– Two major types of chlorophyll in vascular
plants
• Chlorophylls a and b
• In solution absorb much of red, blue, indigo, and
violet light
• In thin green leaf
– Absorption spectrum similar to but not identical to that of
chlorophyll in solution
Absorption of Light Energy by
Chlorophyll
• Chlorophyll molecule absorbs or traps
photon
• Energy of photon causes electron from
one of chlorophyll’s atoms to move to
higher energy state
• Unstable condition
• Electron moves back to original energy
level
Absorption of Light Energy by
Chlorophyll
• Absorbed energy transferred to adjacent pigment
molecule
– Process called resonance
• Energy eventually transferred to chlorophyll a reception
center
– Series of steps drives electrons from water to reduce NADP+
– Formation of NADPH represents conversion of light energy to
chemical energy
– NADPH reduces CO2 in enzymatic reactions leading to sugar
formation
Two Photosystems
• Robert Emerson
– 1950s
– Made observations that led to realization that
there are two light reactions and two pigment
systems
• Photosystem I
• Photosystem II
Two Photosystems
Pigments
Photosystem I
Photosystem II
Chlorophyll a and b
Chlorophyll a and
b, carotene
Reaction
Center
Description
P700
Greater proportion of
chlorophyll a than b in
*light-harvesting
complex, sensitive to
longer wavelength light
P680
Equal amounts of
chlorophyll a and b,
*light-harvesting complex
sensitive to shorter
wavelength light
* light-harvesting complex – functional pigment units that act as light traps
Adenosine Triphosphate
Synthesis
• Photophosporylation
– Light-driven production of ATP in chloroplasts
• Two types
– Cyclic photophosphorylation
– Noncyclic photophosphorylation
Adenosine Triphosphate
Synthesis
• Cyclic Photophosphorylation
– Electrons flow from light-excited chlorophyll
molecules to electron acceptors and cyclically
back to chlorophyll
– No O2 liberated
– No NADP+ is reduced
– Produces H+ gradient that leads to energy
conservation in ATP production
– Only photosystem I involved
Adenosine Triphosphate
Synthesis
• Noncyclic photophosphorylation
– Electrons from excited chlorophyll molecules
are trapped in NADP+ to form NADPH
– Electrons do not cycle back to chlorophyll
– Photosystems I and II are involved
– ATP and NADPH are formed
• Energy drives CO2 reduction reactions of
photosynthesis
Enzymes of Light-Independent
Reactions
• All enzymes participating directly in
photosynthesis occur in chloroplasts
– Many are water-soluble
– Many found in stroma
• Ribulose biphosphate
carboxylase/oxygenase (rubisco)
– Catalyzes first step in carbon cycle of
photosynthesis
Enzymes of Light-Independent
Reactions
rubisco
Carbon dioxide + ribulose biphosphate

2 phosphoglyceric acid
*(RuBP)
•RuBP  5-C sugar present in plastid stroma, spontaneous reaction
Photosynthetic Carbon
Reduction Cycle
• Methods used to isolate carbon
compounds formed during enzymatic
reactions
– Used radioactive carbon (14C) in CO2 to trace
each intermediate product
– Two-dimensional paper chromatography
Photosynthetic Carbon
Reduction Cycle
• Melvin Calvin
– 1950s
– Used radioactive C (14C) in CO2 to trace
intermediate products of carbon reduction
cycle
– Nobel Prize
C3 Pathway
• First product PGA contains 3 Cs
• Calvin cycle (in honor of discoverer, Melvin
Calvin)
• Key points
– CO2 enters cycle and combines with RuBP produced
in stroma
• 2 molecules of PGA are produced
– Energy stored in NADPH and ATP transferred into
stored energy in phosphoglyceraldehyde (PGAL)
C3 Pathway
– PGAL may be enzymatically converted to 3-C
sugar phosphate, dihydroxyacetone
phosphate
– Two molecules of dihydroxyacetone
phosphate combine to form a sugar
phosphate, fructose 1,6 - biphosphate
C3 Pathway
– Some fructose 1,6 – biphosphate transformed
into other carbohydrates, including starch
(reactions not part of C3 cycle)
– RuBP is regenerated
• Free to accept more CO2
Photorespiration
• Differs from aerobic respiration
– Yields no energized energy carriers
– Does not occur in the dark
• Involves interaction with chloroplasts,
peroxisomes, mitochondria
Photorespiration
High rates of
photorespiration (particularly
on hot, bright days)
Produce less sugar
during hot, bright
days of summer,
under milder
conditions are more
efficient because
they expend less
energy to capture
CO2
Show little or no
photorespiration
Produce 2 or 3 times
more sugar than C3
plants during hot,
bright days of
summer
C3 Plants
C4 Plants
Environmental Stress and
Photorespiration
• Succulents
– Developed methods of storing and conserving
water
•
•
•
•
Highly developed parenchyma tissue
Large vacuoles
Reduced intercellular spaces
Absorb and store water when moisture is available
Environmental Stress and
Photorespiration
• Succulents
– Stoma closed during the day and open at
night
• Advantage
– Reduces water loss during day
• Disadvantage
– Reduces CO2 uptake in daylight when photosynthesis
can occur
– Exhibit type of carbon metabolism called
crassulacean acid metabolism (CAM)
Major Features of CAM
– Stomata open at night
– Leaves rapidly absorb CO2
– Enzyme phosphoenolpyruvate (PEP) carboxylase
initiates fixation of CO2
– Malate, 4-C compound is usually produced
– Total amount of organic acids rapidly increases in
leaf-cell vacuoles at night
– Leaf acidity rapidly decreases during following day
• Organic acids are decarboxylated and CO2 released into leaf
mesophyll
Major Features of CAM
– Stomata closed during the day
• Prevents or greatly reduces CO2 absorption and
water loss
• C3 cycle of photosynthesis usually takes place and
converts the internally released CO2 into
carbohydrate
C4 Pathway
• Discovered in 1965
– H.P. Kortschak, C.E. Hartt, G.O. Burr
• Extensively studied by M.D. Hatch and
C.R. Slack
• Pathway also known as Hatch-Slack cycle
• Differs from C3 or Calvin cycle
– Ensures an efficient absorption of CO2 and
results in low CO2 compensation point
C4 Pathway
• Compensation point
– Concentration of CO2 remaining in closed
chamber at the point when CO2 produced by
respiration balances or compensates for CO2
absorbed during photosynthesis
– Varies among different plants
C4 Pathway
– Example of compensation point
•
•
•
•
Place bean plant and corn plant in chamber in light
Bean plant will die before corn plant
Corn plant has very low CO2 compensation point
Both plants eventually die of starvation
Factors Affecting Productivity
• Only about 0.3% to 0.5% of light energy
that strikes leaf is stored in photosynthesis
• Yield could be increased by factor of 10
under ideal conditions
Factors Affecting Productivity
• Breed productivity into plants
– Norman Borlaug
– Nobel Prize 1970
– Developed high-yielding wheat strains
• Disadvantages
– Strains require high levels of fertilizer
» Expensive
» Create pollution
– Potential for genetic problems
Factors Affecting Productivity
• Breeding programs or use of recombinant
DNA technology may lead to new C4 and
C3 plants less prone to photorespiration
Environmental Fluctuations Alter
Photosynthesis Rate
• To some extent, environmental factors
under control of plant grower
• Water and mineral content control of soil
most easily controlled
• Control of temperature, light (intensity,
quality, duration), and CO2 require special
equipment
Environmental Factors
• Temperature
– Most plants function best between
temperatures of 10C and 25C
– Above 25C
• Continuous decrease in photosynthesis rate as
temperature increases
– Under low light intensity, increase in
temperature beyond certain minimum does
not produce increase in photosynthesis
Environmental Factors
• Light
– Light intensity and wavelength affect
photosynthesis rate
• Intensity to which chloroplasts are exposed affects
photosynthesis more than intensity of light falling
on leaf surface
• Structural adaptations that diminish light intensity
that reaches chloroplasts
– Surface hairs, thick cuticle, thick epidermis
Environmental Factors
• Light
– Sunflecks
• Brief exposure to light received by plants on forest
floor when breezes move upper canopy
• Contribute to majority of light used by understory
vines, shrubs, and herbs
– Plants adapt to quality of light to survive
• Plants growing in deep water have developed
accessory pigments to absorb blue-green
wavelengths and use it in photosynthesis
Environmental Factors
• Carbon dioxide
– Not possible to deplete atmospheric carbon dioxide
– Continual increase in carbon dioxide contributes to
threat of global warming
– Atmospheric carbon dioxide around leaves limits rate
of photosynthesis in C3 plants
– Experimentally determined an artificial increase in
carbon dioxide (up to 0.6%) may increase rate of
photosynthesis for limited period
• Level injurious to some plants after 10 to 15 days of
exposure
Environmental Factors
• Water
– Rate of photosynthesis may be changed by
small differences in water content of
chlorophyll-bearing cells
– Drought reduces rate of photosynthesis in
some plants
Environmental Factors
• Mineral nutrients
– Poor soils can result in plants with poorly
developed photosynthetic capacities
• Can increase yields by effective fertilizer programs
Absorption and Transport
Chapter 11
Transport and Life
• Plants have same general needs as
animals for transporting substances from
one organ to another
• Plants need supply of water
– Maintain structures
– Photosynthesis
– Growth
– Die if dehydrated
Transport and Life
• Replacement water comes from soil
through roots
• Need transport system to get water from
soil into roots and up to leaves
• Growth requires mineral nutrients
– Must have system to transport minerals to
meristematic regions
Transport and Life
• Carbohydrates produced in
photosynthesis provide energy and C
skeleton for synthesis of other organic
molecules
– Energy needed in all plant parts but especially
in meristematic regions of stems and roots
and in flowers, seeds, and fruits
• Must have system for transporting
carbohydrates from photosynthetic organs
to living cells in plant
Water
•
•
•
•
Most abundant compound in living cell
Solvent
Moves solutes from place to place
Substrate or reactant for many
biochemical reactions
• Provides strength and structure to
herbaceous organs
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Five major forces
– Diffusion
– Osmosis
– Capillary forces
– Hydrostatic pressure
– Gravity
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Diffusion
– Flow of molecules from regions of higher to
lower concentrations
– Major force for directing flow of water in gas
phase
– Liquid water and solute molecules also diffuse
• Example: place drop of dye in glass of water
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Osmosis
– Diffusion of water across selectively
permeable membrane from a dilute solution
(less solute, more water) to a more
concentrated solution (more solute, less
water)
– Osmotic pump
• Device that uses osmosis to power the flow of
water out of a chamber
• Works by pressure generated through osmosis
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Hydrostatic pressure
– In cells, called turgor pressure
– Opposes flow of water into cells
– Importance of turgor
• Stiffens cells and tissues
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Capillary forces
– Water molecules are cohesive
• Stick to each other
– Water molecules are adhesive
• Stick to hydrophilic molecules
• Example: carbohydrates
– Cohesion and adhesion can generate tension
that pulls water into small spaces
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Capillary forces
– Forces pulling water into tube
– Produce a tension in water like a stretched
rubber band
– Maximum tension that can develop in capillary
tube depends on cross-sectional area of bore
• Smallest bores produce greatest tensions
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Water pulled into soil and held there by
capillary forces
– Strength of forces depends on amount of
water present
• Dry soil – stronger tension
Factors Affecting Flow of Water
in Air, Cells, and Soil
• Gravity
– Takes force to move water upward
– Significant factor in tall trees
Water Potential
• Takes into account all the forces that move water
• Combines them to determine when and where water will
move through a plant
• Water always tends to flow from a region of high water
potential to a region of low water potential
– If water potential of soil around root is less than water potential of
root cells, water will flow out of root into the soil
Water Potential
• Can calculate water potential from
physical measurements
– Useful to agriculturists who estimate water
needs
Transpiration
• Flow of water through plant is usually
powered by loss of water from leaves
• Transpiration pulls water up the plant
– Major event is diffusion of water vapor from
humid air inside leaf to drier air outside the
leaf
– Loss of water from leaf generates force that
pulls water into leaf from vascular system,
from roots, and from soil into roots
Diffusion of Water Vapor Through
Stomata
• Intercellular air spaces in leaves close to
equilibrium with solution in cellulose fibrils
of cell walls
• Bulk of air outside leaves generally dry
• Strong tendency for diffusion of water
vapor out of leaf
• Water vapor diffuses out of stomata
– Route by which most water is lost from plant
Diffusion of Water Vapor Through
Stomata
• Anatomical leaf features that slow diffusion
rate
– Dense layer of trichomes on leaf surface
– Stomatal crypts (sunken stomata)
• Depressions in leaf surface into which stomata
open
• Warm air holds more water than cool air
– Plants lose water faster when temperature is
high
Flow of Water Into Leaves
• Water vapor evaporates from surrounding
cell walls when water vapor is lost from
intercellular spaces of leaf
– Partially dries cell walls
– Produces capillary forces that attract water
from adjacent area in leaf
• Some replacement water comes from inside leaf
cells across plasma membrane
– Too much water lost, plant wilts
Flow of Water Into Leaves
• In well-watered plant, water from cell walls
and from inside cell replaced by water
from xylem
Flow of Water Through Xylem
• Removal of one water molecule out of
central space of tracheid
• Results in hydrostatic tension on rest of
water in tracheids and vessels
• If water continues to flow from leaf
tracheid into leaf cell walls
– Constant stream of water flowing from xylem
– Powered by tension gradient
Flow of Water Through Xylem
• Tracheids
– Fairly high resistance to water flow
– Require fairly steep tension gradient to
maintain adequate flow
– Air bubble in one tracheid has no effect on
overall flow
Flow of Water Through Xylem
• Vessels
– Lower resistance to water flow
– More easily inactivated by air bubbles
• Few vessels
• Bubble in vessel may block substantial amount of
water flow
Flow of Water Through Xylem
• Conifers
– Only tracheids, no vessels
– Advantage in dry, cold climates
• Conditions most likely to produce air bubbles in
xylem
Symplastic and Apoplastic Flow
Through Roots
• Pathway
– Loss of water through xylem decreases water
potential in xylem of growing primary root
– Pulls water from apoplast of stele of root
– Water from apoplast of stele is replaced by
water flowing into stele from root cortex
– Water from soil moves into root cortex
Symplastic and Apoplastic Flow
Through Roots
• Because no cuticle over epidermis of
primary root
– Water can flow between cells of epidermis
directly into apoplast of cortex and to
endodermis
• Water cannot cross endodermis because
of Casparian strip
Symplastic and Apoplastic Flow
Through Roots
• To go further into root
– Water must enter symplast by crossing
plasma membrane of endodermal cell
– Can also cross plasma membrane of cells at
root hairs or in cortex
– Can flow from cell to cell through symplast via
plasmodesmata
• Cross endodermis in symplast
• Enters apoplast
• Flows into xylem
Symplastic and Apoplastic Flow
Through Roots
• Water must pass through at least two
plasma membranes to reach root xylem
from soil
Flow Through Soil
• Can be considerable resistance to flow of
water through soil
– Capillary spaces are small
– Distances may be long
• Limits rate at which water can reach
leaves
Flow Through Soil
• Temporary wilt
– Occurs when water does not move quickly
enough to replace water lost from leaves
– Plant recovers if water loss is stopped
• Permanent wilt
– Occurs when osmotic forces pulling water into
cells are not as great as the attractive forces
holding water to soil particles
– Plant does not recover
Control of Water Flow
• Transpiration
– Slow at night
– Increases after sun comes up
– Peaks middle of day
– Decreases to night level over afternoon
• Rate of transpiration directly related to
intensity of light on leaves
Control of Water Flow
• Other environmental factors affecting rate
– Temperature
– Relative humidity of bulk air
– Wind speed
Stomata
• Primary sensing organs are guard cells
– Illumination
• Concentration of solutes in vacuoles of guard cells
increases
• Starch in chloroplasts of guard cells converted to
malic acid
Stomata
• Proton pump in guard cell plasma membrane
activated
– Moves H+ across plasma membrane
– K+ and Cl- ions flow through different channels into cells
• Accumulation of malate, K+, Cl- increase osmotic
effect drawing water into guard cells
• Extra water volume in guard cells expands walls
increasing turgor pressure
Stomata
• Guard cells bend away from each other opening
stoma between them
– Specialized cell walls of guard cells
» Cellulose microfibrils wrapped around long axis of
cells (radial micellation)
» Heavier, less extensible wall adjacent to stoma
• Darkness reverses process
Mineral Uptake and Transport
• Plants synthesize organic growth
compounds
– Do not need to take them in
• Need to take in elements that are
substrates or catalysts for synthetic
reactions
Mineral Uptake and Transport
• Plant cells take up mineral elements only
when elements are in solution
– Dissolution of crystals in rock and soil
particles
– Decomposition of organic matter in soil
Roles of Mineral Elements in Plants
Element
Primary Roles
Potassium (K)
Osmotic solute, activation of some enzymes
Nitrogen (N)
Structure of amino acids and nucleic acid bases
Phosphorus (P)
Structure of phospholipids, nucleic acids, adenosine triphosphate
Sulfur (S)
Structure of some amino acids
Calcium (Ca)
Structure of cell walls, transmission of developmental signals
Magnesium (Mg)
Structure of chlorophyll, activation of some enzymes
Iron (Fe)
Structure of heme in respiratory, photosynthetic enzymes
Manganese (Mn)
Activation of photosynthetic enzyme
Chloride (Cl)
Activation of photosynthetic enzyme, osmotic solute
Boron (B), cobalt
(Co), copper (Cu),
zinc (Zn)
Activation of some enzymes
C. HOPKiNS CaFe – Mighty good (mnemonic for remembering elements)
Soil Types
• Soil
– Part of Earth’s crust that has been changed
by contact with biotic and abiotic parts of
environment
– 1-3 m in thickness
– Made up of
• Physically and chemically modified mineral matter
• Organic matter in various stages of decomposition
Soil Types
• Soils differ in
– Depth
– Texture
– Chemistry
– Sequence of layers
Soil Types
• Soil type
– Basic soil classification unit
• Soil types grouped into
– Soil series
– Families
– Orders
• 11 soil orders
• Distribution of specific types of plants often
correlated with presence of particular soil types
Soil Formation
• Dissolving elements from rock
– Begins with acidic rain
– Rain dissolves crystals in rock
– Rate of dissolving depends on crystal surface
area in contact with water
– Freezing and thawing of water in cracks of
rocks
• Breaks off pieces of rock
• Forms new fissures
Soil Formation
• Starts soil formation process
• Water and wind erosion pulverize rock
particles
• Lichens and small plants start to grow
– Rhizoids and roots enlarge fissures in rocks
Soil Formation
• Best soils
– Do not have greatest concentration of
minerals in soil solution
– High ion concentration increases osmotic
effect of soil and limits movement of water into
plant
– High concentration of some ions
• Toxic to plants
• Al3+, Na+
Soil Formation
• Best to have lower concentration of
nutrients with source that releases ions
into solution as they are taken up by plants
Nitrogen Fixation
• Nitrogen
– Needed in large amounts by plants
– Plants cannot use atmospheric nitrogen (N2)
• Must be converted to NH4+ or NO3- through process of
nitrogen fixation
• Nitrogen fixation
– Catalyzed by enzymes in bacteria
• Bacteria free living in soil
• Bacteria in association with roots of plants (legumes)
– Rhizobium
Nitrogen Fixation
•
–
–
•
–
–
•
–
–
NH4+  NO3Nitrification
NO3- very soluble and easily leached from soil
NO3-  NH4+
occurs in plants
Nitrate reduction
NO3-  N2
Denitrification
Carried out by certain soil bacteria
Minerals Accumulated by Root
Cells
• All plant cells require mineral source
– Especially meristematic regions
• Minerals in solution
– Passive transport in stream of water pulled
through plant by transpiration
– Active processes contributing to uptake and
transport
• Require input of energy from ATP or NADPH
Maintenance of Mineral Supply
• Three processes replenish mineral supply
– Bulk flow of water in response to transpiration
– Diffusion
– Growth
• As root grows, comes in contact with new soil
region and new supply of ions
Uptake of Minerals Into Root Cells
• Ion transported across plasma membrane
into root cell
• Enter epidermis
– Moves along symplast
– Travels as far as endodermis through
apoplastic pathway
Uptake of Minerals Into Root Cells
– Reaches endodermis
• Crosses plasma membrane
– Allows plant to exclude toxic ions
– Concentrate needed nutrients in low concentration in soil
solution
– Requires ATP energy
Mycorrhizae
• Association of filamentous fungi with roots
of some plants
• Plants with mycorrhizae often grow better
than plants with mycorrhizae
Mycorrhizae
• Mutualistic relationship
– Mycorrhizal fungi have high-affinity system for
taking up phosphate
– Fungus provides phosphate for uptake into
plant roots
– Plant roots provide carbon and nutrients to
fungus
Ion Transport From Root to Shoot
• Ions secreted into apoplast
– Enter xylem
• Takes ions to wherever stomata are open and
transpiration is occurring
– Transported to shoot
• Taken up into shoot cells
• Greater concentration of ions accumulate and
solvent water evaporates
Ion Transport From Root to Shoot
• Example of ion accumulation
– Dead tips of older leaves of slow-growing
house plants
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•
•
•
Sign ions have accumulated to toxic level
Water this type of plant infrequently but thoroughly
Allow excess water to drain through pot
Fertilize infrequently
Root Pressure
• Root pressure is result of osmotic pump
• Accumulation of ions in stele has osmotic
effect
• Soil saturated with water
– Water tends to enter root and stele
– Builds up root pressure in xylem
– Forces xylem sap up into shoot
Root Pressure
• Hydathode
– Specialized opening in leaves of some
grasses and small herbs
• Guttation
– Water forced out of hydathodes by root
pressure
Phloem Transport
• Translocation – transport of carbohydrates in
plant
• Carbohydrates
– Product of photosynthesis
– Source of carbon for synthesis of all other organic
compounds
– Can be stored temporarily in chloroplast of mature
leaf cells
– May be exported from leaf in form of sucrose or other
sugars
Phloem Transport
• Carbohydrate pathway through phloem
traced using radioactive CO2
– Rate of transport is faster than diffusion or
transport from individual cell to cell
– Not as fast as the rate at which water is pulled
through xylem
• Phloem transport can change direction
Phloem Transport
• Current idea of transport
– Sucrose flows through sieve tubes as one
component in bulk flow of solution
– Flow directed by gradient of hydrostatic
pressure
– Powered by osmotic pump
Phloem Transport
• Phloem
– Dynamic osmotic pump
– Source of solute at one end and sink at the
other
– Sucrose is main osmotically active solute in
phloem
– Sucrose pumped from photosynthetically
active parenchyma cells into sieve tubes of
minor veins
• Exact pathway unknown
Phloem Transport
– Accumulation of sucrose in sieve tube pulls
water into sieve tube from apoplast by
osmosis
• Increases hydrostatic pressure inside sieve tube at
source
• Pressure starts flow of solution that will travel to
any attached sieve tube in which pressure is less
Phloem Transport
– Loss of concentration prevented by
• Continual pumping of sucrose at source
• Removal of sucrose at the sink