Flower

V

Evolution of Flowers

Flowering plants are thought to have evolved around 135 million years ago from cone-bearing gymnosperms. Scientists had long proposed that the first flower most likely resembled today’s magnolias or water lilies, two types of flowers that lack some of the specialized structures found in most modern flowers. But in the late 1990s scientists compared the genetic material deoxyribonucleic acid (DNA) of different plants to determine their evolutionary relationships. From these studies, scientists identified a small, cream-colored flower from the genus Amborella as the only living relative to the first flowering plant. This rare plant is found only on the South Pacific island of New Caledonia.

The evolution of flowers dramatically changed the face of earth. On a planet where algae, ferns, and cycads tinged the earth with a monochromatic green hue, flowers emerged to paint the earth with vivid shades of red, pink, orange, yellow, blue, violet, and white. Flowering plants spread rapidly, in part because their fruits so effectively disperse seeds. Today, flowering plants occupy virtually all areas of the planet, with about 240,000 species known.

Many flowers and pollinators coevolved—that is, they influenced each other’s traits during the process of evolution. For example, any population of flowers displays a range of color, fragrance, size, and shape—hereditary traits that can be passed from one generation to the next. Certain traits or combinations of traits appeal more to pollinators, so pollinators are more likely to visit these attractive plants. The appealing plants have a greater chance of being pollinated than others and, thus, are likely to produce more seeds. The seeds develop into plants that display the inherited appealing traits. Similarly, in a population of pollinators, there are variations in hereditary traits, such as wing size and shape, length and shape of tongue, ability to detect fragrance, and so on. For example, pollinators whose bodies are small enough to reach inside certain flowers gather pollen and nectar more efficiently than larger-sized members of their species. These efficient, well-fed pollinators have more energy for reproduction. Their offspring inherit the traits that enable them to forage successfully in flowers, and from generation to generation, these traits are preserved. The pollinator preference seen today for certain flower colors, fragrances, and shapes often represents hundreds of thousands of years of coevolution.

Coevolution often results in exquisite adaptations between flower and pollinator. These adaptations can minimize competition for nectar and pollen among pollinators and also can minimize competition among flowers for pollinators. Comet orchids, for example, have narrow flowers almost a foot and a half long. These flowers are pollinated only by a species of hawk moth that has a narrow tongue just the length of the flowers. The flower shape prevents other pollinators from consuming the nectar, guarantees the moths a meal, and ensures the likelihood of pollination and fertilization.

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Most flowers and pollinators, however, are not as precisely matched to each other, but adaptation still plays a significant role in their interactions. For example, hummingbirds are particularly attracted to the color red. Hummingbird-pollinated flowers typically are red, and they often are narrow, an adaptation that suits the long tongues of hummingbirds. Bats are large pollinators that require relatively more energy than other pollinators. They visit big flowers like those of saguaro cactus, which supply plenty of nectar or pollen. Bats avoid little flowers that do not offer enough reward.

Other examples of coevolution are seen in the bromeliads and orchids that grow in dark forests. These plants often have bright red, purple, or white sepals or petals, which make them visible to pollinators. Night-flying pollinators, such as moths and bats, detect white flowers most easily, and flowers that bloom at sunset, such as yucca, datura, and cereus, usually are white.

The often delightful and varied fragrances of flowers also reveal the hand of coevolution. In some cases, insects detect fragrance before color. They follow faint aromas to flowers that are too far away to be seen, recognizing petal shape and color only when they are very close to the flower. Some night-blooming flowers emit sweet fragrances that attract night-flying moths. At the other extreme, carrion flowers, flowers pollinated by flies, give off the odor of rotting meat to attract their pollinators.

Flowers and their pollinators also coevolved to influence each other’s life cycles. Among species that flower in response to a dark period, some measure the critical night length so accurately that all species of the region flower in the same week or two. This enables related plants to interbreed, and provides pollinators with enough pollen and nectar to live on so that they too can reproduce. The process of coevolution also has resulted in synchronization of floral and insect life cycles. Sometimes flowering occurs the week that insect pollinators hatch or emerge from dormancy, or bird pollinators return from winter migration, so that they feed on and pollinate the flowers. Flowering also is timed so that fruits and seeds are produced when animals are present to feed on the fruits and disperse the seeds.

VI

Flowers and Extinction

Like the amphibians, reptiles, insects, birds, and mammals that are experiencing alarming extinction rates, a number of wildflower species also are endangered. The greatest threat lies in the furious pace at which land is cleared for new houses, industries, and shopping malls to accommodate rapid population growth. Such clearings are making the meadow, forest, and wetland homes of wildflowers ever more scarce. Among the flowers so endangered is the rosy periwinkle of Madagascar, a plant whose compounds have greatly reduced the death rates from childhood leukemia and Hodgkin’s disease. Flowering plants, many with other medicinal properties, also are threatened by global warming from increased combustion of fossil fuels; increased ultraviolet light from ozone layer breakdown; and acid rain from industrial emissions. Flowering plants native to a certain region also may be threatened by introduced species. Yellow toadflax, for example, a garden plant brought to the United States and Canada from Europe, has become a notorious weed, spreading to many habitats and preventing the growth of native species. In some cases, unusual wildflowers such as orchids are placed at risk when they are collected extensively to be sold.

Many of the threats that endanger flowering plants also place their pollinators at risk. When a species of flower or pollinator is threatened, the coevolution of pollinators and flowers may prove to be disadvantageous. If a flower species dies out, its pollinators will lack food and may also die out, and the predators that depend on the pollinators also become threatened. In cases where pollinators are adapted to only one or a few types of flowers, the loss of those plants can disrupt an entire ecosystem. Likewise, if pollinators are damaged by ecological changes, plants that depend on them will not be pollinated, seeds will not be formed, and new generations of plants cannot grow. The fruits that these flowers produce may become scarce, affecting the food supply of humans and other animals that depend on them.

Worldwide, more than 300 species of flowering plants are endangered, or at immediate risk of extinction. Another two dozen or so are considered threatened, or likely to become extinct in the near future. Of these species, fewer than 50 were the focus of preservation plans in the late 1990s. Various regional, national, and international organizations have marshaled their resources in response to the critical need for protecting flowering plants and their habitats. In the United States, native plant societies work to conserve regional plants in every state. The United States Fish and Wildlife Endangered Species Program protects habitats for threatened and endangered species throughout the United States, as do the Canadian Wildlife Service in Canada, the Ministry for Social Development in Mexico, and similar agencies in other countries. At the international level, the International Plant Conservation Programme at Cambridge, England, collects information and provides education worldwide on plant species at risk, and the United Nations Environmental Programme supports a variety of efforts that address the worldwide crisis of endangered species.

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