Introduction It has been said that an oak is an acorn s way of making more acorns. In a Darwinian view of life, the fitness of an organism is measured only by its ability to replace itself with healthy, fertile offspring. 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 themselves.
Items referring to physiological processes are limited to photosynthesis, cellular respiration, transpiration, growth, and reproduction.
This is how plants d sexual reproduction. Gametophytes produce gametes, egg and sperm. Fusion of egg and sperm during fertilization form a diploid zygote, the beginning of a Sporophyte. Fig. 29.6
Wrap your mind around this When a plant has babies, they look very different. An oak tree, for instance, has pollen grains and embryo sacs for babies. Pollen grains and embryo sacs have oak trees for babies. Confusing?
Fig. 38.1
Know these structures and tissues for the EOC Roots Stems Leaves Flowers Fruits Cones Seeds
And these Meristem Cambium Ground tissue Dermal tissue Vascular tissue Xylem Phloem
And these Stomata Guard cells Stamen: anther, filament, sperm Pistil: style, stigma, ovary, egg Sepal, petals Let s watch it all here and then see details as time permits. Or see more detail here. Let s watch some Private Life of Plants, if time.
2. 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. So a basic leaf does photosynthesis, but these have a different function. What kind of evolution is this?
The four kinds of floral organs are the sepals, petals, stamens, and carpals. Their site of attachment to the stem is the receptacle. Fig. 38.2
The stamens and carpels of flowers contain sporangia, within which the spores and then gametophytes 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.
3. Male and female gametophytes develop within anthers and ovaries, respectively: Pollination brings them together The male gametophyte begins its develop within the sporangia (pollen sacs) of the anther. The female gametophyte begins to develop within the ovules of the ovary
The development of angiosperm gametophytes involves meiosis and mitosis. Fig. 38.4
The male gametophyte begins its development within the sporangia (pollen sacs) of the anther. Within the sporangia are microsporocytes, each of which will from four haploid microspores through meiosis. Each microspore can eventually 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. The tube cell, enclosing the generative cell, produces the pollen tube, which delivers sperm to the egg. This two-celled structure is encased in a thick, ornate, distinctive, and resistant wall. This is a pollen grain, an immature male gametophyte. Fig. 38.5
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.
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, resulting in one cell with eight haploid nuclei. Membranes partition this mass into a multicellular female gametophyte - the egg sac.
At one end of the egg sac, two synergid cells flank the egg cell, or female gametophyte. 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 (from the sporophyte).
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. Most angiosperms interact with insects or other animals that transfer pollen directly between flowers.
5. 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 generative cells divides by mitosis to produce two sperm, the 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 foodstoring tissue of the seed.
Fig. 38.9
The union of two sperm cells with different nuclei of the embryo sac is termed double fertilization. Double fertilization is also present in a few gymnosperms, probably via independent evolution. Double fertilization ensures that the endosperm will develop only in ovules where the egg has been fertilized. This prevents angiosperms from squandering nutrients in eggs that lack an embryo.
6. 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, but 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 and 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.
7. 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. Pollination 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.
By selectively breeding plants, humans have capitalized on the production of edible fruits. The apples, oranges, and other fruits in grocery stores are exaggerated versions of much smaller natural varieties of fleshy fruits. The staple foods for humans are the dry, wind-dispersed fruits of grasses, which are harvested while still on the parent plant. The cereal grains of wheat, rice, maize, and other grasses are easily mistaken for seeds, but each is actually a fruit with a dry pericarp that adheres tightly to the seed coat of the single seed within.
Know these structures and tissues for the EOC Roots Stems Leaves Flowers Fruits Cones Seeds
And these Stomata Guard cells Stamen: anther, filament, sperm Pistil: style, stigma, ovary, egg Sepal, petals Let s watch it all here and then see details as time permits. Or see more detail here. Let s watch some Private Life of Plants, if time.