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Get onto land, plants had to evolve
a way to keep from drying out and
stand upright.
Have to be able to transport
nutrients, water over long short
distances.
Plant structures divided into 2
systems: root system (below
ground), shoot system (above
ground).
Systems rely on one another; roots
require shoots to photosynthesize.
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Water and mineral salts from soil
enter plant through epidermis
(outer layer) of roots, cross root
cortex, pass into stele (where
xylem is), flow up xylem vessels to
shoot system.
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Fig. 36.7
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings
Most absorption of water and
minerals occurs near root tips,
epidermis is permeable to water and
root hairs are located.
Root hairs allow for maximum uptake.
Most plants form partnerships with
symbiotic fungi for absorbing water
and minerals from soil.
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Water and minerals in root cortex
cannot be transported to rest of
plant until they enter xylem in
stele.
Endodermis surrounds stele and is
last checkpoint for absorption into
vascular tissue.
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Some plants have adventitious
roots that arise aboveground from
stems or even from leaves.
Seen in corn - help keep plant
upright.
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1Stems have nodes (leaves attached)
internodes (spaces between nodes)
Where leaves meet stems are axillary
buds - vegetative branch could form.
Terminal bud - growth of young shoot
is concentrated - growth happens
vertically (apical dominance)
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Modified shoots
1Stolons - “runners” of strawberry
plants - grow on surface so parent
plant can asexually reproduce in
large numbers.
2Rhizomes – ginger - horizontal
stems that grow underground.
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Rhizomes
3Tubers – potatoes - swollen ends
of rhizomes specialized for food
storage.
4Bulbs – onions - vertical,
underground shoots consisting
mostly of swollen bases of leaves
that store food.
Tubers
Bulbs
2Leaves consist of a flattened
blade and a petiole (stalk)
Some leaves have evolved other
purposes - spines of cacti for
defense, leaves modified for water
storage, brightly colored leaves
that attract pollinators.
3Flowers – discussed later
Each organ has 3 tissues: dermal,
vascular, and ground.
Dermal tissue - epidermis (covers
and protects)
Epidermis of leaves and most stems
secretes waxy coating, cuticle, that
helps parts of plant retain water.
Land plants - true roots, stems,
leaves.
Xylem carry water, minerals up from
roots - dead at maturity.
Phloem - living tissue - distribute
sugars, amino acids, other organic
products.
http://www.bbc.co.uk/schools/gcsebitesize/img/bixylemphloem.gif
2 types of xylem cells: vessel
elements, tracheids.
Both dead at maturity - help thicken
walls to promote water flow.
1Tracheids - long, thin cells with
tapered ends.
2Vessel elements - wider, shorter,
thinner walled, less tapered than
tracheids.
2 types of phloem cells - companion
cells and sieve tube members.
1Sieve tube members - tubes that
material moves through.
2Companion cells assist sieve tube
members.
Xylem sap flows into veins of leaf
providing them with water.
Plants lose water through
transpiration (water is replaced
through water transport)
Xylem sap must rise against gravity
through pumping system.
Accumulation of minerals in stele
lowers water potential, generating
positive pressure (root pressure) forces fluid up xylem.
Plants rely on osmosis.
Direction of water movement depends
on solute concentration and physical
pressure (water potential)
Water moves from high water
potential to low water potential.
Water potential is measured in MPa,
abbreviated psi.
Pressure to water can reverse
movement of water would normally
move.
Using syringe (negative pressure) can
force water to move upwards.
Combined effects of pressure and
solute concentrations on water
potential: psi = psiP + psis
psiP - pressure potential psis - solute
potential (or osmotic potential).
Flaccid cell, psip = 0.
If placed in solution with lower psi,
water will leave cell - will
plasmolyze, by shrinking and pulling
away from wall.
As cell begins to swell pushes
against wall (turgor pressure)
Placed in pure water - cell will have
lower water potential due to
solutes; water will enter cell.
Become turgid (firm)
Simple diffusion is not efficient
enough.
Water and solutes move through
xylem vessels and sieve tubes by
bulk flow - movement of fluid
driven by pressure.
Tension allows for transport of
materials.
Transpiration forces water to move
up plant in stream (negative
pressure) - allows materials to move
in bulk.
Larger diameter of stem = faster
material can move.
Other items regulate water flow.
1Aquaporins - specific transport
proteins that aid in passive
movement of water.
2Tonoplast (membrane that bounds
vacuole), regulates molecular traffic
between cytosol and contents of vacuole
(cell sap)
3Plasmodesmata (connections between
cells) connect symplast (cytoplasm
stream)
Cell walls of adjacent plant cells apoplast.
Leaf epidermis composed of cells tightly
locked together.
Full of stomata - openings that allow
diffusion of carbon dioxide, water vapor,
and oxygen between leaf and air.
Size of stomata controlled by guard cells open and close opening using turgor
pressure.
Guard cells open during day to allow
CO2 for photosynthesis; close at night
to limit loss of water vapor through
transpiration (evaporation of water
from leaves)
Decreased turgor pressure causes
guard cells to close (need to conserve
water)
Absorption of sunlight drives
transpiration by causing water to
evaporate from mesophyll cells and
by maintaining high humidity in air
spaces in a leaf.
Sunlight drives transport of water.
Root pressure causes guttation
(oozing of water droplets in
morning on tips of grass blades)
Roots accumulate water during
night, transpiration is low, so water
enters leaf at faster rate.
Xylem sap pulled through plant
creating stream of water that cannot
be broken.
Cavitation (formation of water vapor
pockets in xylem vessel) breaks chain.
Occurs when xylem sap freezes in
water.
Cannot be fixed in trees, but stream
can form around it.
When transpiration exceeds delivery of
water by xylem, (soil begins to dry out)
leaves wilt as cells lose turgor pressure.
Guard cells control diameter of stomata
by changing shape, widening or
narrowing gap between the 2 cells.
Potassium helps in regulation of
guard cells.
Their opening is regulated in 3
ways.
1Blue-red wavelengths signal plant
to start photosynthesizing.
2Depletion of CO2.
3Internal clock in plant cues plant to
start photosynthesizing - started at
dawn.
Opening and closing cycle of stomata is
circadian rhythm, cycles that have
intervals of approximately 24 hours.
Plants adapted to arid climates
(xerophytes) have leaf modifications
that reduce rate of transpiration.
Some - smaller, thicker leaves.
Some shed leaves during extremely
dry months.
Some - stomata concentrated on
lower (shady) leaf surface.
Phloem sap
Phloem transports organic products
of photosynthesis throughout plant
via translocation.
Phloem sap - aqueous solution sugar, mostly sucrose - is most
abundant solute.
Xylem - unidirectional movement;
phloem movement variable.
Sieve tubes carry food from sugar
source to sugar sink.
Sugar source - plant organ (especially
mature leaves) where sugar is being
produced by photosynthesis or
breakdown of starch.
Sugar sink - organ (growing roots, shoots,
or fruit) that is net consumer or storer of
sugar.
Storage organ (like a tuber) can be sink in
summer (storing for winter) but source
during in beginning of spring
http://www.pearsoned.ca/school/science11/biology1
1/sugartransport.html
Neither dermal tissue nor vascular
tissue.
In dicot stems, ground tissue
divided into pith, internal to
vascular tissue, and cortex,
external to the vascular tissue.
3 different types of plant cells:
parenchyma, collenchyma, and
sclerenchyma.
1Parenchyma cells have walls that
are thin and flexible; typical plant
cells (sieve-tube members)
2Collenchyma cells - thicker walls
than parenchyma cells.
Used for support in growing plants.
3Sclerenchyma cells function as
supporting elements of plant.
Annual plants complete life cycle in
single year or less.
Biennial plants - two years.
Plants that live many years, including
trees, shrubs, and some grasses, are
perennials.
Growth in plants due to embryonic
(undifferentiated) cells meristems.
Can undergo cell division to produce
new organs through life of plant.
Elongate and differentiate into cell
types depending on tissue of plant.
Apical meristems found at tips of
roots and stems.
Allow for growth in length – only
happens at tips of roots and stems.
Primary growth – lengthwise,
secondary growth - widthwise.
Lateral meristems - secondary
growth.
Root tip protected by root cap to
protect meristem.
Lateral meristems
2 cambiums responsible for secondary
growth.
1Vascular cambium - meristem to
produce secondary xylem and secondary
phloem.
2Cork cambium - meristem for tough,
thick covering for stems and roots replaces epidermis.
As secondary growth continues
over years, layer upon layer of
secondary xylem accumulates,
producing wood - actually dead
cells.
Growth in areas like Maine occur in
cycles through dormancy then
growth which produce growth rings.
Bark - all tissues external to vascular
cambium (secondary phloem, cork
cambium, and cork)
2 types of secondary phloem:
heartwood and sapwood.
Heartwood (hardwood) no longer
conducts water (responsible for
strength in old trees) while sapwood
(softwood) functions in transport of
water and minerals.
4 groups of land plants: bryophytes,
pteridophytes, gymnosperms, and
angiosperms.
Bryophytes - mosses.
Pteridophytes - ferns.
Gymnosperms – pines, conifers.
Angiosperms - flowering plants.
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings
Bryophytes - offspring remain
attached to parent plant.
Non-vascular plants.
Vascular plants - vascular tissues,
cells join into tubes that transport
water, nutrients throughout plant
body.
http://www.science.siu.edu/landplants/Bryophyta/images/Physcomitrium.JPEG
Ferns - seedless plants.
Seed - plant embryo packaged along with
food supply within protective coat.
Early seed plants gave rise to diversity
of present-day gymnosperms, including
conifers.
Modern plants angiosperms.
http://www.rockhillridge.com/images/hayes/Ferns,%20Hayes%20Tract%206%2003-web.jpg
Fern
Plant evolution:
1Origin of bryophytes from algal
ancestors.
2Origin, diversification of vascular
plants.
3Origin of seeds.
4Evolution of flowers.
Plants – multicellular, derive energy and
nutrition through photosynthesis.
Plant cell walls - cellulose.
Different from algae - apical meristems,
alternation of generations, sporangia
that produce walled spores.
http://www.botany.hawaii.edu/faculty/webb/BOT311/bot311-00/PlantCellWalls00/CellWallHemiLab.jpg
Plants need to grow to maximize
absorption.
Done through apical meristems undifferentiated cells that divide
when needed.
Located at tips of roots, shoots.
Multicellular plant embryos develop
from zygotes - stay in tissues of
female parent.
Land plants - embryophytes.
Parent provides nutrients to
embryo.
Alternation of generations -
gametophyte produces haploid
gametes through mitosis that get
fertilized (by other gametes); form
a diploid zygote that will grow into
mature sporophyte.
http://fig.cox.miami.edu/~cmallery/150/mitosis/sf9x7c.jpg
Sporophyte produces haploid
single-celled spores - reproductive
cells - grow into gametophyte by
mitosis.
Size of sporophyte and
gametophyte differ in plant
species.
Bryophytes - gametophyte
dominant generation.
Pteridophytes, gymnosperms, and
angiosperms - sporophyte dominant
generation.
http://www.sbs.auckland.ac.nz/info/schools/nzplants/images/moss/moss_major_parts1.jpg
Spores - covered by sporopollenin –
resistant to outside stress.
Sporangia found on sporophyte produce spores.
Sporopollenin
Female gametangium (gamete
producing organ) – archegonium produces single egg cell in vase shaped organ.
Male gametangia – antheridia produce many sperm cells released to
environment.
Sperm fuses with egg in archegonium.
Female
Fusion of sperm and egg
Land plants have cuticle – protects
from drying out, microbes.
Stomata allow exchange of carbon
dioxide and oxygen between outside
and interior.
Plants also produce secondary
compounds - alkaloids, tannins, and
phenolics such as flavonoids bitter tastes, strong odors, or
toxic effects (protection for plant)
Some used for medicinal purposes.
http://www.naturalproductsmarketplace.com/articles/i461a12.jpg
Origin of land plants
Chloroplasts of land plants most
similar to plastids of green algae.
In both - cellulose comprises 2026% of cell wall.
http://www.rsbs.anu.edu.au/profiles/Brian_Gunning/Web%20PCB/Ch%2010%20Plastids/Topic%2005%20Chloroplasts-Charophyceae/10%2005%2010.jpg
Bryophytes
3 phyla - 1phylum Hepatophyta –
liverworts, 2phylum Anthocerophyta
– hornworts, 3phylum Bryophyta –
mosses.
Gametophytes dominant phase of
life cycle.
Bryophytes anchored by tubular
cells or filaments of cells rhizoids.
No conducting tissues (xylem,
phloem) to distribute water and
organic compounds within
gametophyte – so very small.
http://userwww.sfsu.edu/~biol240/labs/lab_10plantoverview/media/rhizoids.jpg
Most mosses lack cuticle, only 1 cell
thick – quick absorption from
surroundings.
Gametophytes produce gametes in
gametangia.
http://io.uwinnipeg.ca/~simmons/Chap29a98/img016.jpg
Bryophyte Reproduction
Sperm swim toward archegonia,
drawn by chemical attractants.
Zygotes and young sporophytes
retained and nourished by parent
gametophyte.
Moss sporophytes have foot, elongated
stalk (seta), and sporangium (capsule).
Foot gathers nutrients and water from
parent gametophyte via transfer cells.
Stalk conducts materials to capsule.
Capsule – disperse spores.
Common in wetlands, wind dispersal
allows for inhabiting many different
areas.
Some moss form deposits of undecayed
organic material – peat.
Forms peat bogs.
Pteridophytes
Vascular plants have food transport
tissues (phloem) and water
conducting tissues (xylem) with
lignified cells.
1st vascular plants, pteridophytes,
were seedless.
http://www.florelaurentienne.com/flore/Groupes/Pteridophytes/images/Adiantum_pedatum_940528_21_800.jpg
Seedless Vascular Plants
Cooksonia (extinct) - earliest known
vascular plant (400 MYA)
2 modern phyla:
1Phylum Lycophyta – lycophytes.
2Phylum Pterophyta -- ferns, whisk
ferns, and horsetails.
Cooksonia
Lycophytes - small leaves
(microphylls) with single
unbranched vein.
Leaves of other vascular plants,
megaphylls much larger and highlybranched.
Reproduction in
Pteridophytes
Homosporous (one sex) sporophyte
produces a single type of spore.
Heterosporous sporophyte (two sexes)
produces 2 kinds of spores.
Megaspores - females gametophytes.
Microspores - male gametophytes.
Heterosporous
Fig. 29.23
Copyright © 2002 Pearson Education, Inc., publishing as Benjamin Cummings
Modern lycophytes - tropical
species that grow on trees as
epiphytes, using trees as
substrates, not as hosts.
Specialized leaves (sporophylls)
bear sporangia clustered to form
club-shaped cones.
http://www.tcr.gov.nl.ca/nfmuseum/images/osmundaclaytoniana3barrdharbourhilljuly122002.jpg
Phylum Pterophyta – ferns and
relatives.
1Psilophytes - whisk ferns.
2Sphenophytes – horsetails - found in
marshy habitats, along
streams and sandy roadways.
3Ferns - leaves (fronds) may be
divided into many leaflets.
Produce clusters of sporangia (sori)
on back of green leaves
(sporophylls) or on special, nongreen leaves.
Dispersed by wind.
Sporophylls
Sori
Seed plants - vascular plants that
produce seeds.
3 adaptations that seed plants
have:
1Gametophyte more reduced.
2Seed evolved.
3Pollen evolved.
Gametophytes of seed plants
almost invisible.
Gametophytes still exist - plants
can destroy themselves at this
stage if there something wrong
with plant.
Seed - sporophyte embryo packaged
with food supply within protective
coat.
Seed plants - 2 different types of
sporangia – each produces different
spores: megaspores (grows into
female gametophyte) and
microspores.
Gametophytes stay in sporophyte as
it develops.
Ovule contains integuments
(protective covering), megaspore, and
megasporangium.
Female gametophyte develops inside
megaspore; produces 1 + egg cells.
Fertilized egg develops into embryo.
Whole ovule develops into seed
Microspores (pollen) – light, carried
through air.
Pollen will create pollen tube - allow
sperm to travel down into female
gametophyte.
2 groups of seed plants:
gymnosperms and angiosperms.
Gymnosperms
4 phyla of gymnosperms still
around.
1Phylum Ginkgophyta - Ginkgo
biloba.
2Phylum Cycadophyta - cycads -
look like palm trees.
3Phylum Gnetophyta – 3 different
types of plants including ephedra.
Cycad
Ephedra
Phylum Coniferophyta - largest phyla -
includes conifers.
Conifer because of reproductive
structure (cone)
Conifers
Conifers - evergreen - keep leaves all
year long.
Needles help in dry conditions.
Conifers - pines, firs, spruces, larches,
yews, junipers, cedars, cypresses, and
redwoods.
Life cycle of gymnosperms
Conifers - heterosporous (separate male
and female gametophytes)
Produce both pollen cones and ovule
cones.
During pollination, pollen falls on ovule.
Pollen creates pollen tube - digests
through megaspore.
Fertilized megaspore goes through
meiosis to produce 4 haploid cells.
1 cell will turn into female gametophyte;
other 2 or 3 cells (archegonia) will
develop within gametophyte.
Angiosperms
Angiosperms - flowering plants -
produce flowers and fruit.
Phylum Anthophyta divided into two
groups: monocots and dicots.
Most monocots - leaves with parallel
veins, dicots - netlike venation.
Monocots (grasses) usually have
fibrous root systems - look like
mat.
Dicots (flowers) have taproot
system - one large root.
Vascular tissue runs length of stem
in vascular bundles.
Dicots - vascular bundles arranged
in a ring; monocots - scattered.
Angiosperms - long tracheids that help
to transport water and to support plant.
Flower specialized for reproduction.
Most angiosperms rely on pollination
through animals; grasses rely on random
chance.
Flower - specialized shoot - 4 circles of
modified leaves: sepals, petals, stamens,
and carpals.
1Sepals - base of flower - modified
leaves that enclose flower before it
opens.
2Petals lie inside ring of sepals - usually
colorful in animal pollinated plants.
3Stamen – male organ - thin, stalk-like
filament with sac at top (anther)
Anther produces haploid spores that
develop into pollen grains.
4Carpal – female organ - contains three
parts: stigma, style, ovary.
Stigma - sticky top part of flower -
extends beyond flower, catches pollen.
Style connects stigma to ovary at base of
pistil - allows sperm to reach ovules.
Ovary - enlarged area at base of pistil that
contains one or more ovules.
The entire structure is the carpal.
An ovule contains the egg nucleus.
Fruit - mature ovary.
As seeds develop from ovules after
fertilization, wall of ovary thickens to form
fruit.
Fruit helps protect seeds while they disperse.
Some fruits, like dandelion, are modified to
catch wind.
Burrs that stick to animals - fruits.
After fertilization, fruit triggered to
form.
Wall of ovary becomes pericarp
(thickened wall of fruit)
If flower not pollinated, fruit will not
develop.
3 different types of fruits.
1Simple fruits - single ovary, like cherries.
2Aggregate fruit, blackberry - single flower
with several carpals.
3Multiple fruit, pineapple - develops a tightly
clustered group of flowers.
Ovules (develop in ovary) contain female
gametophyte (the embryo sac)
Angiosperm life cycle starts with
mature flower on sporophyte plant, ends
with germinating seed.
Anther produce microspores - form
male gametophytes (pollen).
Ovules produce megaspores - form
female gametophytes (embryo sacs).
Pollen released from anther - carried
to sticky stigma of carpal.
Plants can self-pollinate; crosspollination is better.
Pollen grain begins growing from stigma
toward ovary.
Discharges 2 sperm cells into female
gametophyte.
1 sperm fuses with egg nucleus to form
diploid zygote - develops into embryo.
Embryo has rudimentary root and 1 (in
monocots) or 2 seed leaves (in dicots),
(cotyledons)
Other sperm nucleus fuses with 2 polar bodies to
form endosperm, (triploid or 3n) in monocots.
Dicots - nutrition goes directly to cotyledons.
As ovules develop into seeds, ovary develops into
fruit.
Conditions favorable, germination occurs - seed
coat ruptures and embryo emerges as seedling.
Seedling uses food stored in either
endosperm (monocot) or cotyledon
(dicot) to start growth.
As seed develops, enters dormancy
allows it to survive until conditions
are favorable.
1st organ to emerge from germinating
seed is radicle (embryonic root)
Asexual reproduction
Plants can clone themselves - vegetative
reproduction.
Fragmentation - parent plant separates
into parts that reform whole plants.
Co-evolution
Because certain animals only eat certain
plants, actually have forced evolution of
one another.
Plants have evolved special fragrances,
that forced evolution of specific animals
to pollinate these plants.
Plants and human welfare
All our fruit and vegetable crops are
angiosperms.
Corn, rice, wheat, and other grain are
grass fruits.
Plants for medicinal purposes; more than
25% of our prescriptions come from
plants.
Destroying these plants may mean
destroying possible cures.
Biotechnology
Selective breeding has allowed humans
to spread plants that could not survive
for very long (i.e. maize).
Scientists use transgenic plants,
(genetically engineered to express
foreign gene from another species) to
study genetics.
Hormones
Plants produce hormones that regulate
growth and development.
Hormones - chemical signals produced in
one part of body, transported to other
parts.
Growth towards or away from stimuli
(regulated by hormones) - tropism.
Growth of shoot towards light -
phototropism (positive).
Hormone responsible for growth auxin.
Quic kT ime™ and a
dec ompress or Quick Time™ an d a
d eco mp res sor
are needed to s ee thisar pi
cture.
e n eed
ed to s ee this pic ture .
Auxin produced in large quantities
in apical meristem - growth occurs.
Auxin used on cut stems to promote
root growth.
Auxins used as growth inhibitor for
some plants - used as pesticides.
http://botit.botany.wisc.edu/images/130/Growth_Substances/Auxins/root_formation/
Cytokinins stimulate cytokinesis
(cell division)
Cytokinins produced in actively
growing tissues, particularly roots,
embryos, and fruits.
Both cytokinins and auxins present,
cells divide.
Shoots forming with
addition of cytokinins
http://trilliumresearch.org/images/htr_web_images_research/05_rp_03_30_md.jpg
Cytokinin levels raised, shoot buds
form.
Auxin levels raised, roots form.
Cytokinins also slow down aging
process of some plant organs florists use sprays to keep flowers
fresh.
http://www.gbpetalpusher.com/flowers/flower5-big.jpg
Gibberellins stimulate growth in
leaves and stems - little effect on
root growth.
Stems, gibberellins stimulate cell
elongation and cell division.
Gibberellins applied to dwarf plants
- grow to normal height.
Applied to normal plants - nothing
happens.
Qui ckT ime™ and a
dec ompress or
are needed to s ee this pic ture.
Many plants - both auxin and
gibberellins must be present for
fruit to set.
Seeds have large amount of
gibberellins - signals seed to break
dormancy.
Abscisic acid promotes plant to
become dormant; thought to help
leaves drop in fall.
Sometimes seed will need to have
all abscisic acid removed (through
washing) to break dormancy.
Also helps to withstand drought sends plant into dormancy until the
conditions are favorable again.
Ethylene promotes leaf dropping as
well as fruit ripening.
If fruit producing ethylene placed
with fruits that are not, those
fruits will also ripen in response to
hormone.
By losing leaves during fall, plants
prevent drying out during winter.
Responses to light
Qui ckTime™ and a
decompressor
are needed to see this pi cture.
Plants require light to grow; can
absorb various aspects of spectrum
of light.
Respond differently to different
wavelengths of light.
2 different types of plants, short
day and long day.
Short-day plants - long-night plants
-require minimum length of
uninterrupted darkness.
Long-day plans - short-night plants
- require period of continuous
darkness interrupted by few
minutes of light.
Response to light - photoperiodism.
Typically, red light used to
interrupt nighttime cycle.
Tropisms
Roots - positive gravitropism (grow
in direction of gravity); shoots negative gravitropism (grow against
direction of gravity).
Thigmotropism - response to touch;
in some plants, causes plant to coil
around an object (like tendril).
Qui ckTi me™ and a
decompressor
are needed to see this pictur e.
Some plants cannot grow in
extreme temperatures or salinities;
others thrive in them.
Freezing of cytoplasm can kill plant
because excess ions can
accumulate.
QuickTime™ and a
decompres sor
are needed to see this pic ture.
http://www.learnnc.org/lp/media/collections/cede/resized/cedebwr07.jpg
Marsh grasses are often tolerate of
extreme salinities
Plant defenses
Plants susceptible to many
Quic kTime™ a nd a
d eco mp res so r
ar e n eed ed to see thi s p ictu re.
different bacteria and viral
infections because of place in food
chain.
Eaten by herbivores - need
protection against excess herbivory
– use physical defenses, such as
thorns, and chemical defenses, such
as production of toxic compounds.
http://www.learner.org/jnorth/images/graphics/monarch/PlantDefense01.jpg
Some plants able to secrete
compounds that kill insect eating it.
Most plants resistant to pathogens
automatically because they are able
to detect infection and kill it off
right away.
QuickTime™ and a
decompressor
are needed to see this picture.
http://138.23.152.128/images/leaf.jpg