The Living World

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Transcript The Living World

The Living World
Fourth Edition
GEORGE B. JOHNSON
18
Evolution of Plants
PowerPoint® Lectures prepared by Johnny El-Rady
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18.1 Adapting to Terrestrial Living
~ 288,700 species of plants are now in existence
These are terrestrial
However, green algae, the likely ancestors of plants,
are aquatic and not well adapted to living on land
Three challenges had to be overcome
1. Mineral absorption
2. Water conservation
3. Reproduction on land
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Mineral Absorption
Plants require relatively large amounts of six
inorganic minerals
Nitrogen, potassium, calcium, phosphorus,
magnesium, sulfur
Plants absorb these materials through their roots
The first plants developed symbiotic associations
with fungi
These mycorrhizae enabled plants to extract
minerals from rocky soil
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Water Conservation
To avoid drying
out, plants have a
watertight outer
covering, termed
the cuticle
Stomata
(singular, stoma)
are pores in the
cuticle that allow
gas and vapor
exchange
Fig. 18.2
Regulate opening
and closing of the
stoma
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Reproduction on Land
Spores developed
as a means to
protect gametes
from drying out on
land
In a plant life cycle,
there is alternation
of generations
Diploid with
haploid
Fig. 18.3 Generalized plant life cycle
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The diploid generation is called the sporophyte
The haploid generation is called the gametophyte
As plants evolved, the sporophyte tissue dominated
Fig. 18.4 Two types of gametophytes
Pine
Moss
Primitive plant
Mostly
gametophyte
Vascular plant
Gametophyte
barely visible
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18.2 Plant Evolution
Four key evolutionary innovations serve to trace the
evolution of the plant kingdom
1. Alternation of generations
Plants developed a more dominant diploid
phase of the life cycle
2. Vascular tissue
Transports water and nutrients throughout the
plant body
Thus plants were able to grow larger and in
drier conditions
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18.2 Plant Evolution
Four key evolutionary innovations serve to trace the
evolution of the plant kingdom
3. Seeds
Protected the embryo, thus allowing plants to
dominate their terrestrial environments
4. Flowers and fruits
Flowers protected the egg and improved the
odds of its fertilization
Fruits surrounded the seeds and aided in their
dispersal
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Fig. 18.5 The evolution of plants
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18.3 Nonvascular Plants
Only two phyla of living plants lack a vascular system
The simplest of
all living plants
Liverworts (Phylum Hepaticophyta)
Hornworts (Phylum Anthocerophyta)
Mosses (Phylum Bryophyta) were the first plants to
evolve strands of specialized conduction cells
The conducting cells do not have specialized wall
thickenings
Thus, a primitive vascular system, at the most
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Fig. 18.6 The life cycle of a moss
Hair-cup moss, Polytrichum
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18.4 The Evolution of Vascular Tissue
The first vascular plant appeared approximately
430 million years ago (mya)
Early plants became
successful colonizers
of land through the
development of
vascular tissue
Efficient water- and
food-conducting
systems
Fig. 18.8 The vascular system of a leaf
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Early vascular plants exhibited primary growth
Growth by cell division at the tips of the stem and
roots
About 380 mya, vascular plants developed a new
pattern of growth, secondary growth
New cells are produced in regions around the
plant’s periphery
Thus, plants could become thick-trunked and
taller
Note
The product of plant secondary growth is wood
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18.5 Seedless Vascular Plants
Two phyla of modern-day vascular plants lack seeds
Ferns (Phylum Pterophyta)
Club mosses (Phylum Lycophyta)
Both have free-swimming sperm that require free
water for fertilization
By far, the largest group are ferns
~ 12,000 living species
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The Life of a Fern
Ferns have both gametophyte and sporophyte
individuals, each independent and self-sufficient
Gametophyte
Produces eggs and sperm
These unite to form the zygote, which develops into
the sporophyte
Sporophyte
Bears and releases haploid spores
These germinate to form gametophytes
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Fig. 18.10 Fern
life cycle
Frond = Vertical leaves
Rhizome = Horizontal stem
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18.6 Evolution of Seed Plants
Seeds are embryo covers that protect the embryonic
plant at its most vulnerable stage
Seed plants produce two kinds of gametophytes
Male gametophytes
Called pollen grains
Arise from microspores
Female gametophytes
Contains the egg
Develops from a megaspore
produced within an ovule
Pollination is the transfer of pollen by insects, winds
Thus, there is no need for free water for fertilization
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All seed plants are derived from a single common
ancestor
There are five living phyla
Four are gymnosperms
Ovules not completely
enclosed by sporophyte
at time of pollination
Fifth is angiosperms
Ovules completely
enclosed by a vessel of
sporophyte tissue, the
carpel, at time of pollination
Cycad
Fig. 18.11
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A seed has three parts
1. A sporophyte plant embryo
2. A source of food for the embryo called endosperm
3. A drought-resistant protective cover
Fig. 18.12
Used for food storage
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Seeds have greatly improved the adaptations of
plants to living on land
1. Dispersal
Facilitate migration dispersal
2. Dormancy
Postpone development until conditions are favorable
3. Germination
Permit embryonic development to be synchronized
with habitat
4. Nourishment
Offer an energy source of young plants
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18.7 Gymnosperms
Gymnosperms are nonflowering seed plants
They include four phyla
Conifers (Coniferophyta)
Cycads (Cycadophyta)
Gnetophytes (Gnetophyta)
Ginkgo (Ginkgophyta)
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Conifers
The most common (and familiar) of the
gymnosperms
Include
Pine, spruce, cedar,
redwood and fir trees
Conifers are trees that
produce their seeds in
cones
Seeds (ovules) develop
on scales within cones
and are exposed at the
Fig. 18.14
time of pollination
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Cycads
Fig. 18.15a
Have short stems and
palmlike leaves
The predominant land plant
in the Jurassic Period
Acts like a plant
standing on its head!
Welwitschia
mirabilis
Gnetophytes
The most closely related to
angiosperms
Only three types of plants;
all unusual
Have flagellated sperm
Fig. 18.15b
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Ginkgo
Only one living species exists
The maidenhair tree, Ginkgo biloba
Resistant to air
pollution
Reproductive
structures found on
different trees
Have flagellated
sperm
Fig. 18.15c
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The Life of a Gymnosperm
Conifer trees form two kinds of cones
Large seed cones: contain the female gametophyte
Small pollen cones: contain pollen grains
Pollen grains are carried by wind to the seed
cones
Fertilization yields a zygote
The zygote matures into a seed
Seeds are dispersed into new habitats
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Fig. 18.16 Life cycle of a conifer
Dominant form of
the life cycle
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18.8 Rise of the Angiosperms
Angiosperms comprise 90% of all living plants
> 300,000 species
Virtually all our food is derived, directly or indirectly
from them
In gymnosperm reproduction, pollen grains are
carried passively by the wind
Angiosperms have evolved a more direct way of
transferring pollen
Induce animals to carry it for them
How?
Flowers!
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18.8 Rise of the Angiosperms
Flowers are the reproductive organs of angiosperms
A flower employs bright colors to attract insects and
nectar, to induce the insects to enter the flower
There they are coated with pollen grains, which
they carry with them to other flowers
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A flower consists of four concentric circles, or whorls,
connected to a base called the recepatcle
Outermost whorl (Sepals)
Protects flower from physical damage
Second whorl (Petals)
Attracts pollinators
Third whorl (Stamens)
Produces pollen grains in the anther
Innermost whorl (Carpel)
Produces eggs in the ovary
Rising from the ovary, is a slender stalk, the style, with a
sticky tip, the stigma
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Fig. 18.17 An
angiosperm flower
Petals
Fused
carpel
Stamens
Geranium
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18.9 Why Are There
Different Kinds of Flowers?
Different insect pollinators are attracted to specific
types of flowers
The most numerous insect pollinators are bees
Bees are first attracted by the odor of nectar
They then focus on the flower’s color and shape
Bee-pollinated flowers are usually yellow or
blue
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Fig. 18.18 How a bee sees a flower
Ludwigia peruviana
Normal light
Light emphasizing
UV reflection
Bee covered
in pollen
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Other pollinators include
Moths
Attracted to scented, white or pale-colored flowers
Flies
Pollen on
beak
Attracted to foulsmelling brown flowers
Hummingbirds
Attracted to red flowers
These are not
typically visited by
insect pollinators
Fig. 18.19
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18.10 Improving Seeds:
Double Fertilization
Within their seeds, angiosperms produce a special,
highly nutritious tissue called the endosperm
The male gametophyte contains two sperm
One fertilizes the egg to form the diploid (2n) zygote
The other fuses with two polar nuclei to form the
triploid (3n) endosperm
This process is called double fertilization
It is only found in angiosperms and gnetophytes
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Fig. 18.20 Life cycle of an angiosperm
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Angiosperms are divided into two groups
Dicotyledons
or dicots
Embryos have two
cotyledons
Evolved earlier
Fig. 18.21a
Monocotyledons
or monocots
Embryos have a
single cotyledon
Evolved later
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Angiosperms are divided into two groups
Dicotyledons
or dicots
Have leaves with
netlike veins
Have flower parts
in fours and fives
Monocotyledons
or monocots
Have leaves with
parallel veins
Have flower parts
in threes
Fig. 18.21b & c
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18.11 Improving Seed Dispersal:
Fruits
A fruit is a mature ripened ovary containing fertilized
seeds
Fruits aid in the dispersal of seeds to new habitats
By animals
By water
By wind
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Fig. 18.22 Different ways of dispersing fruit
Maples
Berries
Coconuts
By animals
By water
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By wind