Plants (p. 662) 32.1 32.2 Adapting to Terrestrial Living (p. 662; Figs. 32.1, 32.2, 32.3) A. Plants are multicellular, terrestrial autotrophs that occur almost exclusively on land and derive energy through photosynthesis. B. The green algae gave rise to the diversity of land plants, which have now evolved into nearly 300,000 different species. C. Three major challenges had to be overcome for living on land: organisms had to absorb minerals, conserve water, and develop a new mode of reproduction suitable for land. D. Absorbing Minerals 1. Many of the early plants had symbiotic fungi, such as the present-day mycorrhizae, to aid in the uptake of minerals and nutrients from rocky shores devoid of soil. E. Conserving Water 1. A waxy cuticle evolved to help retard water loss. 2. Gases could be exchanged with the atmosphere through tiny openings called stomata that could also be closed to further reduce water loss. F. Reproducing on Land 1. The development of spores was an evolutionary trend that protected reproductive cells from drying. 2. Transferring gametes from one plant to the next during sexual reproduction posed a problem that has been answered by the development of spores in many plant lines. 3. Haploid spores are produced by sporophytes, the diploid generation that alternates with the haploid gamete-producing gametophyte generation. 4. This alternation of generations solved many problems for plants reproducing sexually on land. Plant Evolution (p. 664; Fig. 32.4; Table 32.1) A. As plants evolved greater specializations on land, below-ground root systems developed, along with vascular tissue to connect above- and below-ground portions of plants. B. Four key innovations highlight the evolutionary trends in plants: an alternation of generations, vascular tissue, seeds, and flowers and fruits. Seedless Plants (p. 666) 32.3 32.4 Nonvascular Plants (p. 666; Fig. 32.5) A. Liverworts and Hornworts 1. The liverworts and hornworts are two groups of primitive plants that completely lack any kind of vascular system. 2. These small plants can only survive in moist habitats. B. Primitive Conducting Systems: Mosses 1. Mosses, a third type of fairly primitive plant, managed to evolve a simple, soft-sided tube capable of conducting water over short distances. 2. In the liverworts, hornworts, and mosses, the main plant body is the gametophyte, with the sporophyte being borne on the gametophyte. The Evolution of Vascular Tissue (p. 667; Figs. 32.6, 32.7) A. Vascular plants have specialized cells that can conduct materials and fluids. B. Seven phyla of plants have such vascular tissue. C. The fossil record indicates that vascular plants have been around for 430 million years. D. Vascular tissue consists of strands of specialized cells the form a network throughout the plant. E. Two types of vascular tissue can be found in vascular plants. 1. Xylem conducts water and minerals from the roots upward to the rest of the plant 2. Phloem conducts carbohydrates throughout the plant. F. How vascular plants grow has changed somewhat over the course of evolution. 1. Primitive vascular plants exhibited primary growth only, which involves cell division at the tips of the stem and roots. 2. 32.5 Around 380 million years ago, vascular plants developed secondary growth, the ability to grow in width, in addition to primary growth. 3. Secondary growth produces wood. Seedless Vascular Plants (p. 668; Figs. 32.8, 32.9) A. Two phyla of modern vascular plants lack seeds and rely on the presence of water to enable sperm to swim to their destination for fertilization. B. Ferns are among the most abundant of the seedless vascular plants, and are especially numerous in the tropics. C. The Life of a Fern 1. Vascular seedless plants have independent gametophyte and sporophyte individuals, but the sporophyte generation is dominant. 2. Spores are produced on the fronds and fall to the earth to develop into gametophytes. 3. On the small heart-shaped gametophytes, gametes are produced, fertilization occurs, and a new sporophyte grows. The Advent of Seeds (p. 670) 32.6 32.7 Evolution of Seed Plants (p. 670; Figs. 32.10, 32.11, 32.12) A. The evolution of seeds has greatly enhanced the ability of plants to survive on land. B. A seed protects the developing embryo when it is most vulnerable to drying out or predation. C. In seed plants, the gametophyte generation is even smaller than in seedless vascular plants, and gametophytes exist entirely within the sporophyte plant. 1. Pollen grains, or male gametophytes, develop from microspores and are transported by various means, depending upon the particular adaptations of a plant. 2. The female gametophyte develops from a megaspore produced within an ovule; the egg is fertilized only after pollination. D. The first seed plants were the gymnosperms with incompletely enclosed ovules. E. Angiosperms evolved later, with their ovules completely enclosed within a vessel called a carpel. F. The Structure of a Seed 1. A seed is made up of a sporophyte embryo surrounded by a hard, protective seed coat. 2. Nourishing endosperm is also housed within the seed coat to provide a food source until germination. 3. Seeds are adapted to life on land because they enable better dispersal, or colonization of new areas or better habitats, and because they protect the embryo during a period of dormancy when the embryo is waiting for better conditions before germination. 4. Seeds are also tuned into the appropriate environmental cues that indicate when moisture and temperature are optimal before germination and growth of the embryo out of the seed. Gymnosperms (p. 672; Figs. 32.13, 32.14) A. Gymnosperms are represented on earth today by four different phyla: conifers, cycads, gnetophytes, and ginkgos. B. We are most familiar with the conifers whose needlelike leaves help resist water loss. C. The Life of a Gymnosperm 1. Conifers form two kinds of cones: seed cones that bear female gametophytes and pollen cones that produce male gametophytes. 2. Conifers rely on the wind to transfer pollen to the seed cone. 3. Once the sperm cell inside the pollen fuses with the egg cell, a new zygote is formed that can eventually develop into a sporophyte. The Evolution of Flowers (p. 674) 32.8 Rise of the Angiosperms (p. 674) A. Angiosperms comprise about 250,000 species or 90% of all living plants. B. Angiosperms evolved special structures, called flowers, to attract and reward animal pollinators, which has led to their success. 32.9 32.10 32.11 C. The Flower 1. Flowers are structured into four concentric whorls. 2. The outermost whorl, made up of sepals, protects the flower while it is still a bud. 3. The second whorl is made up of the colorful petals that attract pollinators. 4. The third whorl is the male portion of the flower, made up of stamens that bear a pollenproducing swollen tip called the anther. 5. The innermost whorl is female in nature, and contains the carpel that houses the ovary and ovule, a long stalk called the style leading to the ovules, and a stigma at the tip that receives pollen. 6. When pollen arrives at the stigma, a pollen tube grows down through the style to reach the ovule. Why Are There Different Kinds of Flowers? (p. 675; Figs. 32.15, 32.16) A. Some flower adaptations that have coevolved to attract and satisfy the needs of the pollinator include unique petal arrangements and colors, patterns of color, odor, and nectar rewards. B. Angiosperms that rely on wind pollination, like grasses, oaks, and birches, do not have large, showy, fragrant flowers. Double Fertilization (p. 676; Figs. 32.17, 32.18) A. Angiosperm seeds have a greatly improved food source for the growing embryo. B. Endosperm is a triploid nutritive source for the growing embryo, and forms as a result of double fertilization. C. One sperm nucleus fertilizes the ovule while another fuses with the polar nuclei to form the triploid endosperm. D. Endosperm divides very rapidly to ensure an adequate food supply for the embryo. E. In some angiosperms, food is stored in swollen, fleshy leaves called cotyledons. 1. Dicots are plants with two cotyledons, like oak and maple trees. 2. Monocots have only one cotyledon and other characteristics different from dicots. 3. Grasses are among the most successful monocots. Fruits (p. 677) A. Fruits are a means of dispersing seeds. B. A fruit is a ripened, fleshy ovary containing the seeds. C. Animals eat fruits and pass the seeds in feces. D. Many specialized types of fruit can be found among the angiosperms.