Evolution and Plant Diversity
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Transcript Evolution and Plant Diversity
EVOLUTION AND PLANT DIVERSITY
Chapter 29
Evolution of Green Algae
Plants share many characteristics
with many protists
Multicellular,
eukaryotic,
and photoautotrophs
Cell walls of cellulose
Chloroplasts with chlorophylls a
and b
Charophytes are only algae that
share 4 distinctive traits with
land plants
Identified
lineage as closest
relatives to land plants
Charophytes Traits
Rosette-shaped cellulose-synthesizing complexes
Peroxisome enzymes
Similar structure in land plants with and charophyceans
Formation of a phragmoplast
Help minimize loss of organic products from photorespiration
Flagellated sperm structure
Proteins in the PM that synthesize cellulose in cell wall
Microtubules that form between daughter nuclei to create
new cell wall in dividing cells
Doesn’t imply land plants are descendents
Land Move Adaptations
Charophyte algae inhabit shallow waters
Dessication is a problem
Natural selection chose individuals that could survive
Sporopollenin is a polymer layer to prevent spores
from drying out during dispersal
Allowed 1st land plants to survive terrestrially
Needed to overcome challenges
Brighter sunlight, more CO2, and mineral rich
Scarce water and little structural support
4 adaptations specific to land plants
Not unique to (convergent evolution) and not all plants have
Alternation of Generations
Each generation gives rise to the
other
Gametophyte generation
From
1n spore by mitosis
Produce gametes by mitosis
Gametes combine in syngamy to
form 2n zygote
Sporophyte generation
From
2n zygote by mitosis
Produces spores by meiosis
Generations can look different
Plants
we see usually sporophyte
Other Derived Traits
* Apical meristems
Localized regions of
cell division at tips of
shoots and roots
* Walled spores
produced in sporangia.
Multicelled organs where
sporocytes (2n) produce
spores via meiosis.
* Multicellular gametangia
Archegonia: female, pearshape with non-motile egg
Antheridia: male, release
sperm to environment
Additional Characteristics
Epidermis covered by a cuticle to protect leaves
from desiccation
Early plants without true roots and leaves benefited
from mycorrhizal associations with fungi
Review:
2 types are?
Secondary compound production to prevent against
herbivores, parasites, and UV radiation
Human
E.g
source of spices and medicines
tannin in red wines from grape skin, stem, and seed;
responsible to dry, pucker taste/sensation of good reds
Diversification of Plants
Nonvascular: unclear
monophylogeny
No vascular tissue, true
roots, stems, or leaves
Small, grow low, moist
environments
Vascular: exist in
smaller clades (phyla)
Seedless are
paraphyletic
Seeds are embryos with
nutrients in a protective
shell
Gymno: naked seeds
Angio: flowering plants
Nonvascular Plants
Phylum Hepatophyta (liverworts)
Marchantia
has ‘thalloid’ shape gametophyte
Gametangia
Plagiochilla
appear as mini trees from which sporophytes hang
has ‘leafy’ looking gametophytes
Phylum Anthocerophyta (hormworts)
Long,
tapered sporophyte with an open sporangium
Gametophyte grows horizontally, 1st to colonize open area
Phylum Bryophyta (mosses)
Mainly
see gametophyte stage, carpet-like
Sporophytes visible and tall, green when young, tan to
release spores
Nonvascular Plants Life Cycle
Gametophyte is dominant
stages
Protonemata produce
‘buds’
Develop into gametophores
with rhizoids = anchors
Antheridia or archegonia
Can be bi- (not mosses)
Sporophyte results
Dependent on parent
Develop foot, stalk (seta),
and capsule (sporangium)
Importance of Mosses
Colonize bare, sandy soil and help retain nitrogen
Moist environments and extreme ones
Mountaintops,
tundra, and deserts
Survive despite loss of water and rehydrate when
conditions improve
Sphagnum forms deposits of dead organic material
= peat
Good
fuel
for water absorbing and gardening; dried as
Evolution of Seedless Vascular Plants
Sperm is flagellated like
nonvascular plants so must
move through films of water
to fertilize egg
Common in moist environments
Branched sporophytes not
dependent on gametophytes
for nutrition
Branching allowed for
multiple sporangia
Ancestors lacked roots, but
shared other traits
Seedless Vascular Plant Life Cycle
Compare with nonvascular life cycle
Sporophyte generation is larger and more complex
In ferns is what is seen
Gametophytes grow on or in soil
Gametophytes reduced as evolution to seed plants
Vascular Transport Tissue
Xylem conducts most water
and minerals
Usess tracheids (tubeshaped cells) to move root to
tip
Cell walls strengthened with
lignin, a polymer
Phloem distributes sugars,
amino acids, and other
organics through cells
arranged as tubes
Evolutionary adaptations
Taller
Cover other plants
(dominance)
Evolution of trees
Roots and Leaves Appear
Roots absorb from the soil and provide support
Resemble
stem tissue
Leaves increase SA and serve as photosynthetic
organs
Stomata
to regulate gas and water exchange
Microphylls: small, spine-like leaves, single vascular
tissue
Phylum
lycophyta only
Megaphylls:
More
highly branched vascular tissue
photosynthetic
Stems move water and minerals to leaves and
organics from leaves to roots
Sporophylls
Modified leaves
that bear
sporangia
Vary in structure
between phyla
of vascular
plants
Most seedless
vascular plants
are
homosporous
Phylum Lycophytes
Club mosses, spike
mosses, and quillworts
Sporophylls clustered
together as cone-like
structures called strobili
Club mosses all
homosporous while
others are heterosporous
Club moss spores are
rich in oil
Photographers ignited
them to create light
Previously represented as 3 separated phyla
All homosporous
Ferns
Sporophytes produce fronds that grow as fiddlehead uncoils
Gametophytes die after sporophyte detaches
Horsetails
Separate fertile (cone-bearing) and vegetative stems
Stems have joints with small leaves emerging from them
Stem is main photosynthetic organ
Whisk ferns
Sporophytes have branched stems, but no roots
3 fused sporangia on stems