Chapter 14b Seed Plants PDF

Summary

This document discusses seed plants, focusing specifically on gymnosperms. It covers their characteristics such as naked seeds, separate gametes, wind pollination and tracheids. The document also details the life cycle of a conifer and the evolution of seed plants.

Full Transcript

14.3 Seed Plants: Gymnosperms 333

implemented landscape.

FIGURE 14.18 This campus garden was designed by students in the horticulture and landscaping department of the college. (credit:
Myriam Feldman)

14.3 Seed Plants: Gymnosperms
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Discuss the type of seeds produced by gymnosperms, as well as other characteristics of gymnosperms
List the four groups of modern-day gymnosperms and provide examples of each

The first plants to colonize land were most likely closely related to modern-day mosses (bryophytes) and are
thought to have appeared about 500 million years ago. They were followed by liverworts (also bryophytes) and
primitive vascular plants, the pterophytes, from which modern ferns are derived. The life cycle of bryophytes and
pterophytes is characterized by the alternation of generations. The completion of the life cycle requires water, as the
male gametes must swim to the female gametes. The male gametophyte releases sperm, which must
swim—propelled by their flagella—to reach and fertilize the female gamete or egg. After fertilization, the zygote
matures and grows into a sporophyte, which in turn will form sporangia, or "spore vessels,” in which mother cells
undergo meiosis and produce haploid spores. The release of spores in a suitable environment will lead to
germination and a new generation of gametophytes.

The Evolution of Seed Plants
In seed plants, the evolutionary trend led to a dominant sporophyte generation, in which the larger and more
ecologically significant generation for a species is the diploid plant. At the same time, the trend led to a reduction in
the size of the gametophyte, from a conspicuous structure to a microscopic cluster of cells enclosed in the tissues of
the sporophyte. Lower vascular plants, such as club mosses and ferns, are mostly homosporous (produce only one
type of spore). In contrast, all seed plants, or spermatophytes, are heterosporous, forming two types of spores:
megaspores (female) and microspores (male). Megaspores develop into female gametophytes that produce eggs,
and microspores mature into male gametophytes that generate sperm. Because gametophyte maturation depends
on water and nutrient supply from the dominant sporophyte tissue, they are not free-living, as are the gametophytes
of seedless vascular plants. Heterosporous seedless plants are seen as the evolutionary forerunners of seed plants.

Seeds and pollen—two adaptations to drought—distinguish seed plants from other (seedless) vascular plants. Both
adaptations were critical to the colonization of land. Fossils place the earliest distinct seed plants at about 350
million years ago. The earliest reliable record of gymnosperms dates their appearance to the Carboniferous period
(359–299 million years ago). Gymnosperms were preceded by the progymnosperms (“first naked seed plants”).
This was a transitional group of plants that superficially resembled conifers (“cone bearers”) because they produced
wood from the secondary growth of the vascular tissues; however, they still reproduced like ferns, releasing spores
to the environment. In the Mesozoic era (251–65.5 million years ago), gymnosperms dominated the landscape.
Angiosperms took over by the middle of the Cretaceous period (145.5–65.5 million years ago) in the late Mesozoic
era, and have since become the most abundant plant group in most terrestrial biomes.
334 14 Diversity of Plants

The two innovative structures of pollen and seed allowed seed plants to break their dependence on water for
reproduction and development of the embryo, and to conquer dry land. The pollen grains carry the male gametes of
the plant. The small haploid (1n) cells are encased in a protective coat that prevents desiccation (drying out) and
mechanical damage. Pollen can travel far from the sporophyte that bore it, spreading the plant’s genes and avoiding
competition with other plants. The seed offers the embryo protection, nourishment and a mechanism to maintain
dormancy for tens or even thousands of years, allowing it to survive in a harsh environment and ensuring
germination when growth conditions are optimal. Seeds allow plants to disperse the next generation through both
space and time. With such evolutionary advantages, seed plants have become the most successful and familiar
group of plants.

Gymnosperms
Gymnosperms (“naked seed”) are a diverse group of seed plants and are paraphyletic. Paraphyletic groups do not
include descendants of a single common ancestor. Gymnosperm characteristics include naked seeds, separate
female and male gametes, pollination by wind, and tracheids, which transport water and solutes in the vascular
system.

Life Cycle of a Conifer
Pine trees are conifers and carry both male and female sporophylls on the same plant. Like all gymnosperms, pines
are heterosporous and produce male microspores and female megaspores. In the male cones, or staminate cones,
the microsporocytes give rise to microspores by meiosis. The microspores then develop into pollen grains. Each
pollen grain contains two cells: one generative cell that will divide into two sperm, and a second cell that will
become the pollen tube cell. In the spring, pine trees release large amounts of yellow pollen, which is carried by the
wind. Some gametophytes will land on a female cone. The pollen tube grows from the pollen grain slowly, and the
generative cell in the pollen grain divides into two sperm cells by mitosis. One of the sperm cells will finally unite its
haploid nucleus with the haploid nucleus of an egg cell in the process of fertilization.

Female cones, or ovulate cones, contain two ovules per scale. One megasporocyte undergoes meiosis in each
ovule. Only a single surviving haploid cell will develop into a female multicellular gametophyte that encloses an egg.
On fertilization, the zygote will give rise to the embryo, which is enclosed in a seed coat of tissue from the parent
plant. Fertilization and seed development is a long process in pine trees—it may take up to two years after
pollination. The seed that is formed contains three generations of tissues: the seed coat that originates from the
parent plant tissue, the female gametophyte that will provide nutrients, and the embryo itself. Figure 14.19
illustrates the life cycle of a conifer.

Access for free at openstax.org
 14.3 Seed Plants: Gymnosperms 335

VISUAL CONNECTION

FIGURE 14.19 This image shows the lifecycle of a conifer.

At what stage does the diploid zygote form?

a. when the female cone begins to bud from the tree
b. when the sperm nucleus and the egg nucleus fuse
c. when the seeds drop from the tree
d. when the pollen tube begins to grow

LINK TO LEARNING
Watch this video (http://openstax.org/l/gymnosperm) to see the process of seed production in gymnosperms.

Diversity of Gymnosperms
Modern gymnosperms are classified into four major divisions and comprise about 1,000 described species.
Coniferophyta, Cycadophyta, and Ginkgophyta are similar in their production of secondary cambium (cells that
generate the vascular system of the trunk or stem) and their pattern of seed development, but are not closely
related phylogenetically to each other. Gnetophyta are considered the closest group to angiosperms because they
produce true xylem tissue that contains both tracheids and vessel elements.

Conifers
Conifers are the dominant phylum of gymnosperms, with the most variety of species. Most are tall trees that usually
bear scale-like or needle-like leaves. The thin shape of the needles and their waxy cuticle limits water loss through
transpiration. Snow slides easily off needle-shaped leaves, keeping the load light and decreasing breaking of
branches. These adaptations to cold and dry weather explain the predominance of conifers at high altitudes and in
cold climates. Conifers include familiar evergreen trees, such as pines, spruces, firs, cedars, sequoias, and yews
(Figure 14.20). A few species are deciduous and lose their leaves all at once in fall. The European larch and the
tamarack are examples of deciduous conifers. Many coniferous trees are harvested for paper pulp and timber. The
wood of conifers is more primitive than the wood of angiosperms; it contains tracheids, but no vessel elements, and
336 14 Diversity of Plants

is referred to as “soft wood.”

FIGURE 14.20 Conifers are the dominant form of vegetation in cold or arid environments and at high altitudes. Shown here are the (a)
evergreen spruce, (b) sequoia, (c) juniper, and (d) a deciduous gymnosperm: the tamarack Larix laricina. Notice the yellow leaves of the
tamarack. (credit b: modification of work by Alan Levine; credit c: modification of work by Wendy McCormac; credit d: modification of work
by Micky Zlimen)

Cycads
Cycads thrive in mild climates and are often mistaken for palms because of the shape of their large, compound
leaves. They bear large cones, and unusually for gymnosperms, may be pollinated by beetles, rather than wind. They
dominated the landscape during the age of dinosaurs in the Mesozoic era (251–65.5 million years ago). Only a
hundred or so cycad species persisted to modern times. They face possible extinction, and several species are
protected through international conventions. Because of their attractive shape, they are often used as ornamental
plants in gardens (Figure 14.21).

FIGURE 14.21 This Encephalartos ferox cycad exhibits large cones. (credit: Wendy Cutler)

Access for free at openstax.org
 14.3 Seed Plants: Gymnosperms 337

Gingkophytes
The single surviving species of ginkgophyte is the Ginkgo biloba (Figure 14.22). Its fan-shaped leaves, unique
among seed plants because they feature a dichotomous venation pattern, turn yellow in autumn and fall from the
plant. For centuries, Buddhist monks cultivated Ginkgo biloba, ensuring its preservation. It is planted in public
spaces because it is unusually resistant to pollution. Male and female organs are found on separate plants. Usually,
only male trees are planted by gardeners because the seeds produced by the female plant have an off-putting smell
of rancid butter.

FIGURE 14.22 This plate from the 1870 book Flora Japonica, Sectio Prima (Tafelband) depicts the leaves and fruit of Gingko biloba, as
drawn by Philipp Franz von Siebold and Joseph Gerhard Zuccarini.

Gnetophytes
Gnetophytes are the closest relatives to modern angiosperms, and include three dissimilar genera of plants. Like
angiosperms, they have broad leaves. Gnetum species are mostly vines in tropical and subtropical zones. The single
species of Welwitschia is an unusual, low-growing plant found in the deserts of Namibia and Angola. It may live for
up to 2000 years. The genus Ephedra is represented in North America in dry areas of the southwestern United
States and Mexico (Figure 14.23). Ephedra’s small, scale-like leaves are the source of the compound ephedrine,
which is used in medicine as a potent decongestant. Because ephedrine is similar to amphetamines, both in
chemical structure and neurological effects, its use is restricted to prescription drugs. Like angiosperms, but unlike
other gymnosperms, all gnetophytes possess vessel elements in their xylem.
338 14 Diversity of Plants

FIGURE 14.23 Ephedra viridis, known by the common name Mormon tea, grows in the western United States. (credit: US National Park
Service, USDA-NRCS PLANTS Database)

LINK TO LEARNING
Watch this BBC video (http://openstax.org/l/welwitschia) describing the amazing strangeness of Welwitschia.

14.4 Seed Plants: Angiosperms
LEARNING OBJECTIVES
By the end of this section, you will be able to:
Describe the main parts of a flower and their purpose
Detail the life cycle of an angiosperm
Discuss the two main groups into which flower plants are divided, as well as explain how basal
angiosperms differ from others

From their humble and still obscure beginning during the early Jurassic period (202–145.5 MYA), the angiosperms,
or flowering plants, have successfully evolved to dominate most terrestrial ecosystems. Angiosperms include a
staggering number of genera and species; with more than 260,000 species, the division is second only to insects in
terms of diversification (Figure 14.24).

FIGURE 14.24 These flowers grow in a botanical garden border in Bellevue, WA. Flowering plants dominate terrestrial landscapes. The
vivid colors of flowers are an adaptation to pollination by insects and birds. (credit: Myriam Feldman)

Angiosperm success is a result of two novel structures that ensure reproductive success: flowers and fruit. Flowers
allowed plants to form cooperative evolutionary relationships with animals, in particular insects, to disperse their

Access for free at openstax.org
 14.4 Seed Plants: Angiosperms 339

pollen to female gametophytes in a highly targeted way. Fruit protect the developing embryo and serve as an agent
of dispersal. Different structures on fruit reflect the dispersal strategies that help with the spreading of seeds.

Flowers
Flowers are modified leaves or sporophylls organized around a central stalk. Although they vary greatly in
appearance, all flowers contain the same structures: sepals, petals, pistils, and stamens. A whorl of sepals (the
calyx) is located at the base of the peduncle, or stem, and encloses the floral bud before it opens. Sepals are usually
photosynthetic organs, although there are some exceptions. For example, the corolla in lilies and tulips consists of
three sepals and three petals that look virtually identical—this led botanists to coin the word tepal. Petals
(collectively the corolla) are located inside the whorl of sepals and usually display vivid colors to attract pollinators.
Flowers pollinated by wind are usually small and dull. The sexual organs are located at the center of the flower.

As illustrated in Figure 14.25, the stigma, style, and ovary constitute the female organ, the carpel or pistil, which is
also referred to as the gynoecium. A gynoecium may contain one or more carpels within a single flower. The
megaspores and the female gametophytes are produced and protected by the thick tissues of the carpel. A long,
thin structure called a style leads from the sticky stigma, where pollen is deposited, to the ovary enclosed in the
carpel. The ovary houses one or more ovules that will each develop into a seed upon fertilization. The male
reproductive organs, the androecium or stamens, surround the central carpel. Stamens are composed of a thin stalk
called a filament and a sac-like structure, the anther, in which microspores are produced by meiosis and develop
into pollen grains. The filament supports the anther.

FIGURE 14.25 This image depicts the structure of a perfect and complete flower. Perfect flowers carry both male and female floral organs.
(credit: modification of work by Mariana Ruiz Villareal)

Fruit
The seed forms in an ovary, which enlarges as the seeds grow. As the seed develops, the walls of the ovary also
thicken and form the fruit. In botany, a fruit is a fertilized and fully grown, ripened ovary. Many foods commonly
called vegetables are actually fruit. Eggplants, zucchini, string beans, and bell peppers are all technically fruit
because they contain seeds and are derived from the thick ovary tissue. Acorns and winged maple keys, whose
scientific name is a samara, are also fruit.

Mature fruit can be described as fleshy or dry. Fleshy fruit include the familiar berries, peaches, apples, grapes, and
340 14 Diversity of Plants

tomatoes. Rice, wheat, and nuts are examples of dry fruit. Another distinction is that not all fruits are derived from
the ovary. Some fruits are derived from separate ovaries in a single flower, such as the raspberry. Other fruits, such
as the pineapple, form from clusters of flowers. Additionally, some fruits, like watermelon and orange, have rinds.
Regardless of how they are formed, fruits are an agent of dispersal. The variety of shapes and characteristics reflect
the mode of dispersal. The light, dry fruits of trees and dandelions are carried by the wind. Floating coconuts are
transported by water. Some fruits are colored, perfumed, sweet, and nutritious to attract herbivores, which eat the
fruit and disperse the tough undigested seeds in their feces. Other fruits have burs and hooks that cling to fur and
hitch rides on animals.

The Life Cycle of an Angiosperm
The adult, or sporophyte, phase is the main phase in an angiosperm’s life cycle. Like gymnosperms, angiosperms are
heterosporous. They produce microspores, which develop into pollen grains (the male gametophytes), and
megaspores, which form an ovule containing the female gametophytes. Inside the anthers’ microsporangia (Figure
14.26), male microsporocytes divide by meiosis, generating haploid microspores that undergo mitosis and give rise
to pollen grains. Each pollen grain contains two cells: one generative cell that will divide into two sperm, and a
second cell that will become the pollen tube cell.

Access for free at openstax.org
 14.4 Seed Plants: Angiosperms 341

VISUAL CONNECTION

FIGURE 14.26 This diagram shows the lifecycle of an angiosperm. Anthers and ovaries are structures that shelter the actual gametophytes:
the pollen grain and embryo sac. Double fertilization is a process unique to angiosperms. (credit: modification of work by Mariana Ruiz
Villareal)

If a flower lacked a megasporangium, what type of gamete would it not be able to form? If it lacked a
microsporangium, what type of gamete would not form?

In the ovules, the female gametophyte is produced when a megasporocyte undergoes meiosis to produce four
haploid megaspores. One of these is larger than the others and undergoes mitosis to form the female gametophyte
or embryo sac. Three mitotic divisions produce eight nuclei in seven cells. The egg and two cells move to one end of
the embryo sac (gametophyte) and three cells move to the other end. Two of the nuclei remain in a single cell and
fuse to form a 2n nucleus; this cell moves to the center of the embryo sac.

When a pollen grain reaches the stigma, a pollen tube extends from the grain, grows down the style, and enters
342 14 Diversity of Plants

through an opening in the integuments of the ovule. The two sperm cells are deposited in the embryo sac.

What occurs next is called a double fertilization event (Figure 14.27) and is unique to angiosperms. One sperm and
the egg combine, forming a diploid zygote—the future embryo. The other sperm fuses with the diploid nucleus in the
center of the embryo sac, forming a triploid cell that will develop into the endosperm: a tissue that serves as a food
reserve. The zygote develops into an embryo with a radicle, or small root, and one or two leaf-like organs called
cotyledons. Seed food reserves are stored outside the embryo, and the cotyledons serve as conduits to transmit the
broken-down food reserves to the developing embryo. The seed consists of a toughened layer of integuments
forming the coat, the endosperm with food reserves and, at the center, the well-protected embryo.

FIGURE 14.27 Double fertilization occurs only in angiosperms. (credit: modification of work by Mariana Ruiz Villareal)

Most flowers carry both stamens and carpels; however, a few species self-pollinate. These are known as “perfect”
flowers because they contain both types of sex organs (Figure 14.25. Biochemical and anatomical barriers to self-
pollination promote cross-pollination. Self-pollination is a severe form of inbreeding, and can increase the number
of genetic defects in offspring.

A plant may have perfect flowers, and thus have multiple sexes in each flower; or, it may have imperfect flowers of
both kinds on one plant (Figure 14.28). In each case, such species are called monoecious plants, meaning “one
house.” Some botanists refer to plants with perfect flowers simply as hermaphroditic. (Note: hermaphrodite is a
scientific term for bodies containing two types of sex organs in plants and non-human animals.) Some plants are
dioecious, meaning “two houses,” and have male and female flowers (“imperfect flowers”) on different plants. In
these species, cross-pollination occurs all the time.

FIGURE 14.28 Monoecious plants have both male and female reproductive structures on the same flower or plant. In dioecious plants,
males and females reproductive structures are on separate plants. (credit a: modification of work by Liz West; credit c: modification of work
by Scott Zona)

Access for free at openstax.org
 14.4 Seed Plants: Angiosperms 343

Diversity of Angiosperms
Angiosperms are classified in a single division, the Anthophyta. Modern angiosperms appear to be a monophyletic
group, which means that they originate from a single ancestor. Flowering plants are divided into two major groups,
according to the structure of the cotyledons, the pollen grains, and other features: monocots, which include grasses
and lilies, and eudicots or dicots, a polyphyletic group. Basal angiosperms are a group of plants that are believed to
have branched off before the separation into monocots and eudicots because they exhibit traits from both groups.
They are categorized separately in many classification schemes, and correspond to a grouping known as the
Magnoliidae. The Magnoliidae group is comprised of magnolia trees, laurels, water lilies, and the pepper family.

Basal Angiosperms
The Magnoliidae are represented by the magnolias: tall trees that bear large, fragrant flowers with many parts, and
are considered archaic (Figure 14.29d). Laurel trees produce fragrant leaves and small inconspicuous flowers. The
Laurales are small trees and shrubs that grow mostly in warmer climates. Familiar plants in this group include the
bay laurel, cinnamon, spice bush (Figure 14.29a), and the avocado tree. The Nymphaeales are comprised of the
water lilies, lotus (Figure 14.29c), and similar plants. All species of the Nymphaeales thrive in freshwater biomes,
and have leaves that float on the water surface or grow underwater. Water lilies are particularly prized by gardeners,
and have graced ponds and pools since antiquity. The Piperales are a group of herbs, shrubs, and small trees that
grow in tropical climates. They have small flowers without petals that are tightly arranged in long spikes. Many
species are the source of prized fragrances or spices; for example, the berries of Piper nigrum (Figure 14.29b) are
the familiar black pepper that is used to flavor many dishes.

FIGURE 14.29 The (a) southern spicebush belongs to the Laurales, the same family as cinnamon and bay laurel. The fruit of (b) the Piper
nigrum plant is black pepper, the main product that was traded along spice routes. Notice the small, unobtrusive clustered flowers. (c)
Lotus flowers, Nelumbo nucifera, have been cultivated since antiquity for their ornamental value; the root of the lotus flower is eaten as a
vegetable. The (d) red berries of a magnolia tree, characteristic of the final stage, are just starting to appear. (credit a: modification of work
by Cory Zanker; credit b: modification of work by Franz Eugen Köhler; credit c: modification of work by "berduchwal"/Flickr; credit d:
modification of work by "Coastside2"/Wikimedia Commons)

Monocots
Plants in the monocot group have a single cotyledon in the seedling, and also share other anatomical features. Veins
344 14 Diversity of Plants

run parallel to the length of the leaves, and flower parts are arranged in a three- or six-fold symmetry. The pollen
from the first angiosperms was monosulcate (containing a single furrow or pore through the outer layer). This
feature is still seen in the modern monocots. True woody tissue is rarely found in monocots, and the vascular tissue
of the stem is not arranged in any particular pattern. The root system is mostly adventitious (unusually positioned)
with no major taproot. The monocots include familiar plants such as the true lilies (not to be confused with the
water lilies), orchids, grasses, and palms. Many important crops, such as rice and other cereals (Figure 14.30a),
corn, sugar cane, and tropical fruit, including bananas and pineapple, belong to the monocots.

FIGURE 14.30 The major crops in the world are flowering plants. One staple food, (a) rice, is a monocot, as are other cereals, while (b)
beans are eudicots. Some popular flowers, such as this (c) lily are monocots; while others, such as this (d) daisy are eudicots. (credit a:
modification of work by David Nance; credit b: modification of work by USDA, ARS; credit c: modification of work by “longhorndave”/Flickr;
credit d: modification of work by “Cellulaer”/NinjaPhoto)

Eudicots
Eudicots, or true dicots, are characterized by the presence of two cotyledons. Veins form a network in leaves. Flower
parts come in four, five, or many whorls. Vascular tissue forms a ring in the stem. (In monocots, vascular tissue is
scattered in the stem.) Eudicots can be herbaceous (like dandelions or violets), or produce woody tissues. Most
eudicots produce pollen that is trisulcate or triporate, with three furrows or pores. The root system is usually
anchored by one main root developed from the embryonic radicle. Eudicots comprise two-thirds of all flowering
plants. Many species seem to exhibit characteristics that belong to either group; therefore, the classification of a
plant as a monocot or a eudicot is not always clearly evident (Table 14.1).

Comparison of Structural Characteristics of Monocots and Eudicots

Characteristic Monocot Eudicot

Cotyledon One Two

Veins in leaves Parallel Network ( branched)

Vascular tissue Scattered Arranged in ring pattern

Roots Network of adventitious roots Tap root with many lateral roots
TABLE 14.1

Access for free at openstax.org
 14.4 Seed Plants: Angiosperms 345

Characteristic Monocot Eudicot

Pollen Monosulcate Trisulcate

Flower parts Three or multiple of three Four, five, multiple of four or five and whorls

TABLE 14.1

LINK TO LEARNING
Explore this website (http://openstax.org/l/pollinators) for more information on pollinators.

The Role of Seed Plants
Without seed plants, life as we know it would not be possible. Plants play a key role in the maintenance of terrestrial
ecosystems through the stabilization of soils, cycling of carbon, and climate moderation. Large tropical forests
release oxygen and act as carbon dioxide “sinks.” Seed plants provide shelter to many life forms, as well as food for
herbivores, thereby indirectly feeding carnivores. Plant secondary metabolites are used for medicinal purposes and
industrial production. Virtually all animal life is dependent on plants for survival.

Animals and Plants: Herbivory
Coevolution of flowering plants and insects is a hypothesis that has received much attention and support, especially
because both angiosperms and insects diversified at about the same time in the middle Mesozoic. Many authors
have attributed the diversity of plants and insects to both pollination and herbivory, or the consumption of plants by
insects and other animals. Herbivory is believed to have been as much a driving force as pollination. Coevolution of
herbivores and plant defenses is easily and commonly observed in nature. Unlike animals, most plants cannot
outrun predators or use mimicry to hide from hungry animals (although mimicry has been used to entice
pollinators). A sort of arms race exists between plants and herbivores. To “combat” herbivores, some plant
seeds—such as acorn and unripened persimmon—are high in alkaloids and therefore unsavory to some animals.
Other plants are protected by bark, although some animals developed specialized mouth pieces to tear and chew
vegetal material. Spines and thorns deter most animals, except for mammals with thick fur, and some birds have
specialized beaks to get past such defenses.

Herbivory has been exploited by seed plants for their own benefit. The dispersal of fruits by herbivorous animals is a
striking example of mutualistic relationships. The plant offers to the herbivore a nutritious source of food in return
for spreading the plant’s genetic material to a wider area.

Animals and Plants: Pollination
More than 80 percent of angiosperms depend on animals for pollination (technically the transfer of pollen from the
anther to the stigma). Consequently, plants have developed many adaptations to attract pollinators. With over
200,000 different plants dependent on animal pollination, the plant needs to advertise to its pollinators with some
specificity. The specificity of specialized plant structures that target animals can be very surprising. It is possible, for
example, to determine the general type of pollinators favored by a plant by observing the flower’s physical
characteristics. Many bird or insect-pollinated flowers secrete nectar, which is a sugary liquid. They also produce
both fertile pollen, for reproduction, and sterile pollen rich in nutrients for birds and insects. Many butterflies and
bees can detect ultraviolet light, and flowers that attract these pollinators usually display a pattern of ultraviolet
reflectance that helps them quickly locate the flower's center. In this manner, pollinating insects collect nectar while
at the same time are dusted with pollen. Large, red flowers with little smell and a long funnel shape are preferred by
hummingbirds, who have good color perception, a poor sense of smell, and need a strong perch. White flowers that
open at night attract moths. Other animals—such as bats, lemurs, and lizards—can also act as pollinating agents.
Any disruption to these interactions, such as the disappearance of bees, for example as a consequence of colony
collapse disorders, can lead to disaster for agricultural industries that depend heavily on pollinated crops.

The Importance of Seed Plants in Human Life
Seed plants are the foundation of human diets across the world. Many societies eat almost exclusively vegetarian
346 14 Diversity of Plants

fare and depend solely on seed plants for their nutritional needs. A few crops (rice, wheat, and potatoes) dominate
the agricultural landscape. Many crops were developed during the agricultural revolution, when human societies
made the transition from nomadic hunter–gatherers to horticulture and agriculture. Cereals, rich in carbohydrates,
provide the staple of many human diets. Beans and nuts supply proteins. Fats are derived from crushed seeds, as is
the case for peanut and rapeseed (canola) oils, or fruits

The medicinal properties of plants have been known to human societies since ancient times. There are references to
the use of plants’ curative properties in Egyptian, Babylonian, and Chinese writings from 5,000 years ago. Many
modern synthetic therapeutic drugs are derived or synthesized from plant secondary metabolites. Very often, the
raw form of the plant or plant-based substance may be unusable even if it demonstrates helpful properties. For
example, chaulmoogra oil was somewhat effective for treating leprosy, but it was difficult to apply and painful for
patients. In 1915, Alice Ball (at only 23 years old), created a method for extracting the active ester compounds from
the oil so that it could be absorbed by the body, creating a much more effective treatment without the negative side
effects. The "Ball Technique" remained the preferred method until synthetic medicines replaced it decades later. It
is important to note that the same plant extract can be a therapeutic remedy at low concentrations, become an
addictive drug at higher doses, and can potentially kill at high concentrations. Table 14.2 presents a few drugs, their
plants of origin, and their medicinal applications.

Plant Origin of Medicinal Compounds and Medical Applications

Plant Compound Application

Deadly nightshade (
Atropine Dilate eye pupils for eye exams
Atropa belladonna )

Foxglove ( Digitalis
Digitalis Heart disease, stimulates heart beat
purpurea )

Yam ( Dioscorea
Steroids Steroid hormones: contraceptive pill and cortisone
spp.)

Ephedra ( Ephedra
Ephedrine Decongestant and bronchiole dilator
spp.)

Pacific yew ( Taxus
Taxol Cancer chemotherapy; inhibits mitosis
brevifolia )

Opium poppy (
Analgesic (reduces pain without loss of consciousness) and narcotic
Papaver Opioids
(reduces pain with drowsiness and loss of consciousness) in higher doses
somniferum )

Quinine tree (
Quinine Antipyretic (lowers body temperature) and antimalarial
Cinchona spp.)

Salicylic
Willow ( Salix spp.) acid Analgesic and antipyretic
(aspirin)

TABLE 14.2

Access for free at openstax.org