Chapter 38 Angiosperm Reproduction and Biotechnology
Lecture Outline
Overview: To Seed or Not to Seed
·
Sexual
reproduction is not the sole means by which flowering plants reproduce.
·
Many
species can also reproduce asexually, creating offspring that are genetically
identical to them.
·
The
propagation of flowering plants by sexual and asexual reproduction forms the
basis of agriculture.
·
For
10,000 years, plant breeders have altered the traits of a few hundred
angiosperm species by artificial selection, transforming them into today’s
crops.
Concept 38.1 Pollination enables gametes to come
together within a flower
Sporophyte and gametophyte generations
alternate in the life cycles of plants.
·
The
life cycles of angiosperms and other plants are characterized by an alternation of generations, in which
haploid (n) and diploid (2n) generations take turns producing each
other.
°
The
diploid plant, the sporophyte,
produces haploid spores by meiosis.
°
These
spores divide by mitosis, giving rise to multicellular male and female haploid
plants—the gametophytes.
°
The
gametophytes produce gametes—sperm and eggs.
°
Fertilization
results in diploid zygotes, which divide by mitosis to form new sporophytes.
·
In
angiosperms, the sporophyte is the dominant generation, the conspicuous plant
we see.
°
Over
the course of seed plant evolution, gametophytes became reduced in size and
dependent on their sporophyte parents.
§
Angiosperm
gametophytes are the most reduced of all plants, consisting of only a few
cells.
·
In
angiosperms, the sporophyte produces a unique reproductive structure, the
flower.
°
Male
and female gametophytes develop within the anthers and ovules, respectively, of
a sporophyte flower.
°
Pollination
by wind, water, or animals brings a male gametophyte (pollen grain) to a female
gametophyte contained in an ovule embedded in the ovary of a flower.
Ovules develop into seeds,
while the ovary itself develops into the fruit around the seed.
Flowers are specialized shoots bearing the
reproductive organs of the angiosperm sporophyte.
·
Flowers,
the reproductive shoots of the angiosperm sporophyte, are typically composed of
four whorls of highly modified leaves called floral organs, which are separated
by very short internodes.
°
Unlike
the indeterminate growth of vegetative shoots, flowers are determinate shoots
in that they cease growing once the flower and fruit are formed.
·
The
four kinds of floral organs are the sepals,
petals, stamens, and carpels.
°
Their
site of attachment to the stem is the receptacle.
·
Sepals
and petals are sterile.
°
Sepals,
which enclose and protect the floral bud before it opens, are usually green and
more leaflike in appearance than the other floral organs.
°
In
many angiosperms, the petals are brightly colored and advertise the flower to
insects and other pollinators.
·
Stamens
and carpels are the male and female reproductive organs, respectively.
°
A
stamen consists of a stalk (the filament) and a terminal anther containing chambers called pollen sacs.
§
The
pollen sacs produce pollen.
°
A
carpel has an ovary at the base and
a slender neck, the style.
§
At the
top of the style is a sticky structure called the stigma that serves as a landing platform for pollen.
§
Within
the ovary are one or more ovules.
§
Some
flowers have a single carpel.
§
In
others, several carpels are fused into a single structure, producing an ovary
with two or more chambers, each containing one or more ovules.
·
The
anthers and the ovules bear sporangia, where spores are produced by meiosis and
where gametophytes later develop.
°
The
male gametophytes are sperm-producing structures called pollen grains, which form within the pollen sacs of anthers.
°
The
female gametophytes are egg-producing structures called embryo sacs, which form within the ovules in ovaries.
·
Pollination
is the transfer of pollen from an anther to a stigma.
°
It
begins the process by which the male and female gametophytes are brought
together so their gametes can unite.
°
Pollination
occurs when pollen released from anthers is carried by wind, water, or animals
to land on a stigma.
°
Each
pollen grain produces a pollen tube, which grows down into the ovary via the
style and discharges sperm into the embryo sac, fertilizing the egg.
°
The
zygote gives rise to an embryo.
°
The
ovule develops into a seed, and the entire ovary develops into a fruit
containing one or more seeds.
°
Fruits
carried by wind, water, or animals disperse seeds away from the source plant
where the seed germinates.
·
Numerous
floral variations have evolved during the 130 million years of angiosperm
history.
·
Plant
biologists distinguish between complete
flowers, those having all four organs, and incomplete flowers, those lacking one or more of the four floral
parts.
·
A bisexual flower is equipped with both
stamens and carpels.
°
All
complete and many incomplete flowers are bisexual.
·
A unisexual flower is missing either
stamens (therefore, a carpellate flower) or carpels (therefore, a staminate
flower).
·
A monoecious plant has staminate and
carpellate flowers at separate locations on the same individual plant.
°
For
example, maize and other corn varieties have ears derived from clusters of
carpellate flowers, while the tassels consist of staminate flowers.
·
A dioecious species has staminate flowers
and carpellate flowers on separate plants.
°
For
example, date palms have carpellate individuals that produce dates and
staminate individuals that produce pollen.
·
In
addition to these differences based on the presence of floral organs, flowers
vary in size, shape, and color.
°
Much
of this diversity represents adaptations of flowers to different animal
pollinators.
°
The
presence of animals in the environment has been a key factor in angiosperm
evolution.
Male and female gametophytes develop within
anthers and ovaries, respectively; pollination brings them together.
·
The
male gametophyte begins its development within the sporangia (pollen sacs) of
the anther.
°
Within
the sporangia are microsporocytes, each of which will form four haploid microspores through meiosis.
°
Each
microspore can give rise to a haploid male gametophyte.
·
A
microspore divides once by mitosis and produces a generative cell and a tube
cell.
°
The
generative cell will eventually form sperm.
°
During
maturation of the male gametophyte, the generative cell passes into the tube
cell.
°
The
tube cell, enclosing the generative cell, produces the pollen tube, which
delivers sperm to the egg.
°
This
is a pollen grain, an immature male gametophyte.
§
This
two-celled structure is encased in a thick, ornate, distinctive, and resistant
wall.
·
A
pollen grain becomes a mature gametophyte when the generative cell divides by
mitosis to form two sperm cells.
°
In
most species, this occurs after the pollen grain lands on the stigma of the
carpel and the pollen tube begins to form.
·
The
pollen tube grows through the long style of the carpel and into the ovary,
where it releases the sperm cells in the vicinity of the embryo sac.
·
Ovules,
each containing a single sporangium, form within the chambers of the ovary.
°
One
cell in the sporangium of each ovule, the megasporocyte, grows and then goes
through meiosis, producing four haploid megaspores.
°
In
many angiosperms, only one megaspore survives.
·
This
megaspore divides by mitosis three times without cytokinesis, forming in one
cell with eight haploid nuclei.
°
Membranes
partition this mass into a multicellular female gametophyte—the embryo sac.
·
Three
cells sit at one end of the embryo sac: two synergid cells flanking the egg
cell.
°
The
synergids function in the attraction and guidance of the pollen tube.
·
At the
other end of the egg sac are three antipodal cells of unknown function.
·
The
other two nuclei, the polar nuclei, share the cytoplasm of the large central
cell of the embryo sac.
·
The
ovule now consists of the embryo sac and the surrounding integuments, layers of
protective tissue from the sporophyte that will eventually develop into the
seed coat.
·
Pollination,
which brings male and female gametophytes together, is the first step in the
chain of events that leads to fertilization.
°
Some
plants, such as grasses and many trees, release large quantities of pollen on
the wind to compensate for the randomness of this dispersal mechanism.
§
At
certain times of the year, the air is loaded with pollen, as anyone plagued by
pollen allergies can attest.
°
Some
aquatic plants rely on water to disperse pollen.
°
Most angiosperms
interact with insects or other animals that transfer pollen directly between
flowers.
Plants have various mechanisms that prevent
self-fertilization.
·
Some
flowers self-fertilize or “self,” but most angiosperms have mechanisms that
make this difficult or impossible.
·
The
various barriers that prevent self-fertilization contribute to genetic variety
by ensuring that sperm and eggs come from different parents.
·
Dioecious
plants cannot self-fertilize because they are unisexual.
·
In
plants with bisexual flowers, a variety of mechanisms may prevent
self-fertilization.
°
For
example, in some species stamens and carpels mature at different times.
°
Alternatively,
they may be arranged in such a way that it is mechanically unlikely that an
animal pollinator could transfer pollen from the anthers to the stigma of the
same flower.
°
The
most common anti-selfing mechanism is self-incompatibility,
the ability of a plant to reject its own pollen and that of closely related
individuals.
°
If a
pollen grain from an anther happens to land on a stigma of a flower on the same
plant, a biochemical block prevents the pollen from completing its development
and fertilizing an egg.
·
The
self-incompatibility systems in plant are analogous to the immune response of
animals.
°
Both
are based on the ability of organisms to distinguish “self” from “nonself.”
°
The
key difference is that the animal immune system rejects nonself, but
self-incompatibility in plants is a rejection of self.
·
Recognition
of “self” pollen is based on genes for self-incompatibility, called S-genes, with dozens of different
alleles in a population.
°
If a
pollen grain and the carpel’s stigma have matching alleles at the S-locus, then the pollen grain fails to
initiate or complete the formation of a pollen tube.
°
Because
the pollen grain is haploid, it will be recognized as “self” if its one S-allele matches either of the two S-alleles of the diploid stigma.
·
Although
self-incompatibility genes are all referred to as S-loci, such genes have evolved independently in various plant
families.
°
As a
consequence, self-recognition blocks pollen tube growth by different molecular
mechanisms.
·
In
some cases, the block occurs in the pollen grain itself, called gametophytic
self-incompatibility.
°
In
some species, self-recognition leads to enzymatic destruction of RNA within the
rudimentary pollen tube.
°
RNases
are present in the style of the carpel, and they can enter the pollen tube and
attack its RNA only if the pollen is of a “self” type.
·
In
other cases, the block is a response by the cells of the carpel’s stigma,
called sporophytic self-incompatibility.
°
In
some species, self-recognition activates a signal transduction pathway in
epidermal cells that prevents germination of the pollen grain.
°
Germination
may be prevented when cells of the stigma take up additional water, preventing
the stigma from hydrating the relatively dry pollen.
·
Basic
research on self-incompatibility may lead to agricultural applications.
°
Many
agricultural plants are self-compatible.
°
Plant
breeders sometimes hybridize different varieties of a crop plant to combine the
best traits of the varieties and counter the loss of vigor that can result from
excessive inbreeding.
°
To
maximize hybrid seed production, breeders currently prevent self-fertilization
by laboriously removing anthers from the parent plants that provide the seeds
or by developing male sterile plants.
°
Eventually,
it may be possible to impose self-incompatibility on species that are normally
self-compatible.
Concept 38.2
After fertilization, ovules develop into seeds and ovaries into fruits
Double fertilization gives rise to the zygote
and endosperm.
·
After
landing on a receptive stigma, the pollen grain absorbs moisture and
germinates, producing a pollen tube that extends down the style toward the
ovary.
°
The
nucleus of the generative cell divides by mitosis to produce two sperm, the
male gametes.
°
The
germinated pollen grain contains the mature male gametophyte.
°
Directed
by a chemical attractant, possibly calcium, the tip of the pollen tube enters
the ovary, probes through the micropyle (a gap in the integuments of the
ovule), and discharges two sperm within the embryo sac.
·
Both
sperm fuse with nuclei in the embryo sac.
°
One
sperm fertilizes the egg to form the zygote.
°
The
other sperm combines with the two polar nuclei to form a triploid nucleus in
the central cell.
°
This
large cell will give rise to the endosperm,
a food-storing tissue of the seed.
·
The
union of two sperm cells with different nuclei of the embryo sac is termed double fertilization.
°
Double
fertilization ensures that the endosperm will develop only in ovules where the
egg has been fertilized.
°
This
prevents angiosperms from squandering nutrients.
·
Normally
nonreproductive tissues surrounding the embryo have prevented researchers from
visualizing fertilization in plants, but recently, scientists have been able to
isolate sperm cells and eggs and observe fertilization in vitro.
°
The
first cellular event after gamete fusion is an increase in cytoplasmic Ca2+
levels, which also occurs during animal gamete fusion.
°
In
another similarity to animals, plants establish a block to polyspermy, the
fertilization of an egg by more than one sperm cell.
§
In
plants, this may be through deposition of cell wall material that mechanically
impedes sperm.
§
In
maize, this barrier is established within 45 seconds after the initial sperm
fusion with the egg.
The ovule develops into a seed containing an
embryo and a supply of nutrients.
·
After
double fertilization, the ovule develops into a seed, and the ovary develops
into a fruit enclosing the seed(s).
°
As the
embryo develops, the seed stockpiles proteins, oils, and starch.
°
Initially,
these nutrients are stored in the endosperm.
°
Later
in seed development in many species, the storage function is taken over by the
swelling storage leaves (cotyledons) of the embryo itself.
·
Endosperm
development usually precedes embryo development.
°
After
double fertilization, the triploid nucleus of the ovule’s central cell divides,
forming a multinucleate “supercell” having a milky consistency.
°
It
becomes multicellular when cytokinesis partitions the cytoplasm between nuclei.
°
Cell
walls form, and the endosperm becomes solid.
§
Coconut
“milk” is an example of liquid endosperm and coconut “meat” is an example of
solid endosperm.
·
The
endosperm is rich in nutrients, which it provides to the developing embryo.
°
In
most monocots and some dicots, the endosperm also stores nutrients that can be
used by the seedling after germination.
°
In
many dicots, the food reserves of the endosperm are completely exported to the
cotyledons before the seed completes its development, and consequently the
mature seed lacks endosperm.
·
The
first mitotic division of the zygote is transverse, splitting the fertilized
egg into a basal cell and a terminal cell.
°
The
terminal cell gives rise to most of the embryo.
°
The
basal cell continues to divide transversely, producing a thread of cells, the
suspensor, which anchors the embryo to its parent.
°
The
suspensor functions in the transfer of nutrients to the embryo from the parent.
·
The
terminal cell divides several times and forms a spherical proembryo attached to
the suspensor.
°
Cotyledons
begin to form as bumps on the proembryo.
§
A
eudicot, with its two cotyledons, is heart-shaped at this stage.
§
Only
one cotyledon develops in monocots.
·
After
the cotyledons appear, the embryo elongates.
°
Cradled
between cotyledons is the embryonic shoot apex with the apical meristem of the
embryonic shoot.
°
At the
opposite end of the embryo axis is the apex of the embryonic root, also with a
meristem.
·
After
the seed germinates, the apical meristems at the tips of the shoot and root
sustain primary growth as long as the plant lives.
·
During
the last stages of maturation, a seed dehydrates until its water content is
only about 5–15% of its weight.
°
The
embryo stops growing and becomes dormant until the seed germinates.
°
The
embryo and its food supply are enclosed by a protective seed coat formed by the integuments of the ovule.
·
In the
seed of a common bean, the embryo consists of an elongate structure, the
embryonic axis, attached to fleshy cotyledons.
°
Below
the point at which the fleshy cotyledons are attached, the embryonic axis is
called the hypocotyl; above it is
the epicotyl.
§
At the
tip of the epicotyl is the plumule, consisting of the shoot tip with a pair of
miniature leaves.
°
The
hypocotyl terminates in the radicle,
or embryonic root.
·
While
the cotyledons of the common bean supply food to the developing embryo, the
seeds of some dicots, such as castor beans, retain their food supply in the
endosperm and have cotyledons that are very thin.
°
The
cotyledons will absorb nutrients from the endosperm and transfer them to the
embryo when the seed germinates.
·
The
embryo of a monocot has a single cotyledon.
°
Members
of the grass family, including maize and wheat, have a specialized cotyledon
called a scutellum.
°
The
scutellum is very thin, with a large surface area pressed against the
endosperm, from which the scutellum absorbs nutrients during germination.
·
The
embryo of a grass seed is enclosed by two sheathes, a coleorhiza, which covers the young root, and a coleoptile, which covers the young shoot.
The ovary develops into a fruit adapted for
seed dispersal.
·
As the
seeds are developing from ovules, the ovary of the flower is developing into a fruit, which protects the enclosed
seeds and aids in their dispersal by wind or animals.
°
Fertilization
triggers hormonal changes that cause the ovary to begin its transformation into
a fruit.
°
If a
flower has not been pollinated, fruit usually does not develop, and the entire
flower withers and falls away.
·
The
wall of the ovary becomes the pericarp,
the thickened wall of the fruit, while other parts of the flower wither and are
shed.
°
In
some angiosperms, other floral parts contribute to the fruit.
°
In
apples, the fleshy part of the fruit is derived mainly from the swollen
receptacle, while the core of the apple fruit develops from the ovary.
·
Fruits
are classified into several types, depending on their developmental origin.
°
A
typical fruit is derived from a single carpel or several fused carpels and is
called a simple fruit.
§
Some
simpler fruits are fleshy, like a peach, while others are dry, like a pea pod.
°
An aggregate fruit results from a single
flower that has more than one carpel, each forming a small fruit.
§
The
fruitlets are clustered together on a single receptacle, like a raspberry.
°
A multiple fruit develops from an
inflorescence, a group of flowers tightly clustered together.
§
When
the walls of the ovaries thicken, they fuse together and form one fruit, as in
a pineapple.
·
The
fruit usually ripens about the same time as its seeds are completing their
development.
°
For a
dry fruit such as a soybean pod, ripening is a little more than senescence of
the fruit tissues, which allows the fruit to open and release the seeds.
°
The
ripening of fleshy fruits is more elaborate, its steps controlled by the
complex interactions of hormones.
§
Ripening
results in an edible fruit that serves as an enticement to the animals that
help spread the seeds.
§
The
“pulp” of the fruit becomes softer as a result of enzymes digesting components
of the cell walls.
§
Color
changes from green to red, orange, or yellow.
§
The
fruit becomes sweeter as organic acids or starch molecules are converted to
sugar.
Evolutionary adaptations of seed germination
contribute to seedling survival.
·
As a
seed matures, it dehydrates and enters a dormancy
phase, a condition of extremely low metabolic rate and a suspension of growth
and development.
·
Conditions
required to break dormancy and resume growth and development vary between
species.
°
Some
seeds germinate as soon as they are in a suitable environment.
°
Others
remain dormant until some specific environmental cue causes them to break
dormancy.
·
Seed
dormancy increases the chances that germination will occur at a time and place
most advantageous to the seedling.
°
For
example, seeds of many desert plants germinate only after a substantial
rainfall, ensuring enough water to complete development.
°
Where
natural fires are common, many seeds require intense heat to break dormancy,
allowing them to take advantage of new opportunities and open space.
°
Where
winters are harsh, seeds may require extended exposure to cold.
°
Small
seeds such as lettuce require light for germination and break dormancy only if
they are buried near the surface.
°
Other
seeds require a chemical attack or physical abrasion as they pass through an
animal’s digestive tract before they can germinate.
·
The
length of time that a dormant seed remains viable and capable of germinating
varies from a few days to decades or longer.
°
It
depends on the species and on environmental conditions.
°
Most
seeds are durable enough to last for a year or two until conditions are
favorable for germination.
°
Thus,
the soil has a pool of nongerminated seeds that may have accumulated for
several years.
°
This
is one reason vegetation reappears so rapidly after a fire, drought, flood, or
some other environmental disruption.
·
Germination
of seeds depends on imbibition, the uptake of water due to the low water
potential of the dry seed.
°
This
causes the expanding seed to rupture its seed coat and triggers metabolic
changes in the embryo that enable it to resume growth.
°
Enzymes
begin digesting the storage materials of endosperm or cotyledons, and the
nutrients are transferred to the growing regions of the embryo.
·
The
first organ to emerge from the germinating seed is the radicle, the embryonic
root.
°
Next,
the shoot tip must break through the soil surface.
°
In
garden beans and many other dicots, a hook forms in the hypocotyl, and growth
pushes it aboveground.
°
Stimulated
by light, the hypocotyl straightens, raising the cotyledons and epicotyl.
·
As it
rises into the air, the epicotyl spreads its first foliage leaves (true
leaves).
°
These
foliage leaves expand, become green, and begin making food by photosynthesis.
°
After
the cotyledons have transferred all their nutrients to the developing plant,
they shrivel and fall off the seedling.
·
Corn
and other grasses, which are monocots, use a different method for breaking
ground when they germinate.
°
The
coleoptile, the sheath enclosing and protecting the embryonic shoot, pushes
upward through the soil and into the air.
°
The
shoot tip then grows straight up through the tunnel provided by the tubular
coleoptile.
·
The
tough seed gives rise to a fragile seedling that will be exposed to predators,
parasites, wind, and other hazards.
°
Because
only a small fraction of seedlings endure long enough to become parents, plants
must produce enormous numbers of seeds to compensate for low individual
survival.
°
This
provides ample genetic variation for natural selection to screen.
°
However,
flowering and fruiting in sexual reproduction is an expensive way of plant
propagation in terms of the resources consumed.
Concept 38.3 Many flowering plants
clone themselves by asexual reproduction
·
Many
plants clone themselves by asexual
reproduction.
·
Many
plants are capable of both sexual and asexual reproduction, and each offers
advantages in certain situations.
°
When
reproducing asexually, a plant passes on all of its genes to its offspring.
°
When
reproducing sexually, it passes on only half of its genes.
·
If a
plant is superbly suited to a stable environment, asexual reproduction has
advantages.
°
A
plant can clone many copies of itself rapidly.
°
If the
environmental conditions remain stable, the clones will be well suited to the
environment.
°
The
offspring are not as frail as the seedlings produced by sexual reproduction in
seed plants.
§
They
are usually mature vegetative fragments of the parent plant.
·
In
unstable environments, where evolving pathogens and other variables affect
survival and reproductive success, sexual reproduction can be advantageous
because it generates variation in offspring.
°
In
contrast, the genotypic uniformity of asexually produced plants puts them at
great risk of local extinction if there is a catastrophic environmental change,
such as a new strain of disease.
°
Seeds
produced by sexual reproduction can disperse to new locations and wait for
favorable growing conditions.
°
Seed
dormancy allows growth to be suspended until hostile environmental conditions
are reversed.
·
Asexual
reproduction is an extension of the capacity of plants for indeterminate
growth.
°
Meristematic
tissues with dividing undifferentiated cells can sustain or renew growth
indefinitely.
°
Parenchyma
cells throughout the plant can divide and differentiate into various types of
specialized cells.
°
Detached
fragments of some plants can develop into whole offspring.
·
In fragmentation, a parent plant separates
into parts that re-form into whole plants.
·
A
variation of this occurs in some dicots, in which the root system of a single
parent gives rise to many adventitious shoots that become separate root
systems, forming a clone.
°
A ring
of creosote bushes in the Mojave Desert of California is believed to be at
least 12,000 years old.
·
A
different method of asexual reproduction, called apomixis, is found in dandelions and some other plants.
°
These
produce seed without their flowers being fertilized.
°
A
diploid cell in the ovule gives rise to the embryo, and the ovules mature into
seeds.
§
These
seeds are dispersed by the wind.
§
This
combines asexual reproduction and seed dispersal.
Vegetative propagation of plants is common in
agriculture.
·
Various
methods have been developed for the asexual propagation of crop plants,
orchards, and ornamental plants.
°
These
can be reproduced asexually from plant fragments called cuttings.
°
These
are typically pieces of shoots or stems.
·
At the
cut end, a mass of dividing, undifferentiated cells called the callus forms, and then adventitious
roots develop from the callus.
°
If the
shoot fragment includes a node, then adventitious roots form without a callus
stage.
°
Some
plants, including African violets, can be propagated from single leaves.
·
In
others, specialized storage stems can be cut into several pieces and develop
into clones.
°
For
example, a piece of a potato including a vegetative bud or “eye” can regenerate
a whole plant.
·
A twig
or bud from one plant can be grafted onto a plant of a closely related species
or a different variety of the same species.
°
This
makes it possible to combine the best properties of different species or
varieties into a single plant.
°
The
plant that provides the root system is called the stock, and the twig grafted onto the stock is the scion.
§
For
example, scions of French vines, which produce superior grapes, are grafted
onto roots of American varieties, which are more resistant to certain soil
pathogens.
§
The
quality of the fruit is not influenced by the genetic makeup of the stock.
·
In
some cases of grafting, however, the stock can alter the characteristic of the
shoot system that develops from the scion.
°
For
example, dwarf fruit trees are made by grafting normal twigs onto dwarf stock
varieties that retard the vegetative growth of the shoot system.
§
Because
the seeds are produced by the scion part of the plant, they give rise to plants
of the scion species if planted.
·
Plant
biotechnologists have adopted in vitro
methods to create and clone novel plant varieties.
°
Whole
plants are cultured from small explants (small tissue pieces) or even single
parenchyma cells on an artificial medium containing nutrients and hormones.
°
The
cultured cells divide and form an undifferentiated callus.
°
Through
manipulations of the hormonal balance, the callus that forms can be induced to
develop shoots and roots with fully differentiated cells.
·
Once
roots and shoots have developed, the test-tube plantlets can be transferred to
soil, where they continue their growth.
°
This
test-tube cloning can be used to clone a single plant into thousands of copies
by subdividing calluses as they grow.
°
This
technique is used to propagate orchids and to clone pine trees that deposit
wood at an unusually fast rate.
·
Plant
tissue culture facilitates genetic engineering of plants.
°
Most
techniques for the introduction of foreign genes into plants start with small
pieces of plant material or single plant cells.
°
Transgenic plants are genetically modified (GM)
plants that have been genetically engineered to express a gene from another
species.
°
Test-tube
culture makes it possible to regenerate a GM plant from a single cell into
which foreign DNA has been incorporated.
·
Another
approach combines protoplast fusion
with tissue culture methods to invent new plant varieties that can be cloned.
°
Protoplasts
are plant cells that have had their cell walls removed enzymatically by
cellulases and pectinases.
°
It is
possible in some cases to fuse two protoplasts from different plant species
that would otherwise be incompatible.
°
The
hybrids can regenerate the cell wall, be cultured, and produce a hybrid
plantlet.
·
One
success of this technique has been the development of a hybrid between a potato
and a wild relative called black nightshade.
°
The
nightshade is resistant to an herbicide that is commonly used to kill weeds.
°
The
hybrids are also resistant, enabling a farmer to “weed” a potato field with an
herbicide without killing the potato plants.
Concept 38.4 Plant biotechnology is transforming
agriculture
·
Plant
biotechnology has two meanings.
°
One is
innovation in the use of plants, or of substances obtained from plants, to make
products of use to humans.
§
This began
in prehistory.
°
In a
more specific sense, biotechnology refers to the use of genetically modified
(GM) organisms in agriculture and industry.
°
Over
the past two decades, the terms genetic
engineering and biotechnology
have become synonymous in the media.
Neolithic humans created new plant varieties
by artificial selection.
·
Humans
have intervened in the reproduction and genetic makeup of plants for thousands
of years.
°
Neolithic
(late Stone Age) humans domesticated virtually all of our crop species over a
relatively short period about 10,000 years ago.
§
Even
for these plants, genetic modifications began long before humans started
altering crops by artificial selection.
§
For
example, the wheat groups that we harvest are the result of natural
hybridizations between different species of grasses.
·
Selective
breeding by humans has created plants that could not survive or reproduce in
the wild.
°
For
example, maize cannot spread its seeds naturally.
°
Humans
selected for a larger central axis (“the cob”), permanent attachment of the
maize kernels to the cob, and a permanent protection by tough, overlapping leaf
sheathes (“the husk”).
·
Maize
is a staple in many developing countries.
°
However,
because most varieties are a relatively poor source of protein, a diet of maize
must be supplemented with other protein sources such as beans.
°
Forty
years ago, a mutant maize known as opaque-2
was discovered with increased levels of tryptophan and lysine, two essential
amino acids.
°
This
maize is more nutritious, and swine fed with opaque-2 maize gain weight three times faster than those fed with
normal maize.
°
However,
the beneficial trait was closely associated with several undesirable ones.
°
It
took nearly 20 years for plant breeders, using conventional breeding methods of
hybridization and artificial selection, to create maize varieties that had
higher nutritional value without the undesirable traits.
°
If
modern methods of genetic engineering had been available, the desirable
varieties could have been developed in only a few years.
·
Unlike
traditional plant breeders, modern plant biotechnologists, using the techniques
of genetic engineering, are not limited to transferring genes between closely
related species or varieties of the same species.
°
Genes
can be transferred between distantly related plant species to create transgenic
plants.
·
Whatever
the social and demographic causes of human starvation around the world,
increasing food production seems like a humane objective.
°
Because
land and water are the most limiting resources for food production, the best
option is to increase yields on available land.
°
Based
on conservative estimates of population growth, the world’s farmers will have
to produce 40% more grain per hectare to feed the human population in 2020.
°
Plant
biotechnology can help make these plant yields possible.
·
The
commercial adoption by farmers of transgenic crops has been one of the most
rapid cases of technology transfer in the history of agriculture.
°
These
crops include cotton, maize, and potatoes that contain genes from a bacterium Bacillus thuringiensis.
§
These
“transgenes” encode for a protein (Bt
toxin) that effectively controls several insect pests.
§
This
has reduced the need for application of chemical insecticides.
§
Bt toxin is produced in the plant as a harmless protoxin that
becomes toxic when activated by alkaline conditions in the guts of insects.
§
In the
acid guts of vertebrates, the protoxin is destroyed without becoming active.
·
Considerable
progress has been made in the development of transgenic plants of cotton,
maize, soybeans, sugar beat, and wheat that are tolerant of a number of
herbicides.
·
Researchers
have also engineered transgenic plants with enhanced resistance to disease.
°
Transgenic
papaya resistant to ringspot virus was introduced to
·
“Golden
rice,” a transgenic variety with a few daffodil genes that increase quantities
of vitamin A, is under development.
°
It is
hoped that this rice will prevent blindness in those whose diet is chronically
deficient in vitamin A.
Plant biotechnology has incited much public
debate.
·
Many
people, including some scientists, are concerned about the unknown risks
associated with the release of GM organisms into the environment.
°
Much
of the animosity regarding GM organisms is political, economic, or ethical in
nature, but there are also biological concerns about GM crops.
°
The
most fundamental debate centers on the extent to which GM organisms are an
unknown risk that could potentially cause harm to human health or to the
environment.
·
One
specific concern is that genetic engineering could potentially transfer
allergens, molecules to which some humans are allergic, from a gene source to a
plant used for food.
°
Biotechnologists
are engaged in removing genes that code allergenic proteins from soybeans and
other crops.
°
So far
there is no credible evidence that any GM plants specifically designed for
human consumption have had any adverse effect on human health.
°
Some
GM foods are potentially healthier than non-GM foods.
§
Bt
maize contains 90% less of a carcinogen produced by a fungus that infects
insect-damaged maize.
§
Since Bt maize suffers less insect damage, it
contains less of the fungal carcinogen.
°
GM-organism
opponents lobby for clear labeling of all foods made wholly or in part from
products of GM organisms and for strict regulations against mixing GM foods
with non-GM foods at any stage of food preparation.
°
Biotechnology
advocates argue that similar demands were not raised when “transgenic” crops
were produced by traditional plant-breeding techniques.
·
There
are concerns that growing GM crops might have unforeseen effects on nontarget
organisms.
°
One
study suggested that the caterpillars of monarch butterflies responded
adversely and even died after consuming milkweed leaves heavily dusted with
pollen from transgenic maize that produced Bt
toxin.
§
Bt
toxin is normally toxic to pests closely related to monarch butterflies.
°
This
study has since been discredited.
°
When
the original researchers shook the male maize inflorescences onto the milkweed
leaves in the laboratory, other floral parts rained onto the leaves.
°
It was
those floral parts, not the pollen, that contained Bt toxin in high concentrations.
°
These
floral parts would not be blown by wind to neighboring milkweed plants under
normal field conditions.
°
The
alternative to transgenic maize, spraying chemical insecticides, is more
harmful to monarch populations.
·
Probably
the most serious concern that some scientists raise is the possibility that
introduced genes may escape from a transgenic crop into related weeds through
crop-to-weed hybridization.
°
This
spontaneous hybridization may lead to a “superweed,” which may have a selective
advantage and be difficult to control.
°
Some
crops do hybridize with weedy relatives, and crop-to-weed transgene escape is a
possibility.
°
Its
likelihood depends on the ability of the crop and weed to hybridize and on how
the transgenes affect the overall fitness of the hybrids.
°
Strategies
to minimize risk include planting a border of unrelated plants with which the
transgenic plants could not hybridize.
°
Another
possibility is breeding male sterility in transgenic plants.
°
Alternatively,
the transgenes can be engineered into chloroplasts, which are inherited
maternally only.
·
“Terminator
technology” may offer another approach to the problem of transgene escape.
°
Plants
that are genetically modified to undergo the terminator process grow normally
until the last stages of seed maturation.
°
At
this point, a gene expressing a “terminator” protein toxic to plants but
harmless to animals is activated in the new seeds.
°
The
seeds are inviable.
°
Terminator
proteins are only produced if the original seeds are pretreated with a specific
chemical.
·
There
is the potential for seed companies to control supplies of viable seeds.
°
Seeds
sold to farmers would be pretreated with the chemical that activates the
terminator process.
°
Some
argue that poor farmers in developing countries will not be able to produce
their own seed, because the plants they grow would produce inviable seeds.
·
The
continuing debate about GM organisms in agriculture exemplifies the
relationship of science and technology to society.
°
Technological
advances almost always involve some risk that unintended outcomes could occur.
°
In the
case of plant biotechnology, zero risk is unrealistic and probably
unattainable.
°
Scientists
and the public need to assess the possible benefits of transgenic products
versus the risks that society is willing to take on a case-by-case basis.
°
These
discussions and decisions should be based on sound scientific information and
testing rather than on reflexive fear or blind optimism.