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Download Overview of Plant Evolution
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An overview of Plant Evolution Key Moments in the life of Kingdom Plantae How did we get from here to there? Key “Moments” in Plant Evolution • • • • • The Transition to Land Development of Vascular Systems Evolution of Heterospory Evolution of the Seed Diversification of the Angiosperms 1. The transition to Land - ca. 475 mya The Heat, dessication, damage by UV rays The risks: Harsh environment… rewards: Great opportunity… Plentiful CO2, sunlight, few competitors or herbivores. The importance: paved the way for other organisms Food for herbivores; First soils! Ancestors of the Plantae The Plantae evolved from green algae, most likely a group called the charophytes. Evidence: Plants and green algae contain chlorophyll b. Chloroplasts of both have a similar structure in which thylakoid membranes are stacked as grana. Cell wall structure of both is very similar (about 2226% cellulose) DNA sequence data supports close relationship between these groups. Challenges of living on land Water Algae is a supportive medium, air is not. are surrounded by a medium that contains water and minerals and can take in their requirements across the whole body. Challenges of living on land To survive on land a plant must: Avoid drying out. Be able to hold itself up. Determine how to get chemical resources (water, minerals, oxygen, and CO2) separated into air and soil. Exploiting these different media requires specialized tissues. Solve the problem of reproducing outside water. Some Adaptations (Solutions) 1. Have body parts extending into both air and soil 2. Develop a vascular system to transport resources within the plant 3. Have a protective layer – cuticle (waxy outer layer) to keep from drying out 4. Specialized structures for reproduction including spores and seeds that do not dry out. Transition to land It is believed that ancestral charophytes lived in shallow water that sometimes dried out (as do modern charophytes). Selection would have favored adaptations in these charophytes to resist drying out such as waxy cuticles and protecting developing embryos within layers of tissue. These preadaptations facilitated the transition onto land. Reproduction on land Moving onto land required the development of new forms of reproduction. Algae shed their gametes into the water, but on land gametes must be protected against desiccation. Reproduction on land Plants produce gametes within gametangia (protective layers of tissue that prevent gametes from drying out). Egg is fertilized within female gametangium (called the archegonium) and embryo develops for some time inside archegonium. Embryophytes Retention of the developing embryo by plants is a fundamental difference from algae. Because this difference is so basic, plants are sometimes described as embryophytes. Transition to land The ancestor of modern plants once established on land had enormous opportunities. No competition for sunlight or minerals and no herbivores. Selection rapidly led to a massive diversification of plants. 2. Rise of Vascular plants The first land plants lacked vascular tissue (as is true of most mosses today) so they could not transport water, sugars or minerals around the plant. Lack of vascular tissue also, of course, limited the size of plants. 2. Rise of Vascular plants Once the first plants moved onto land, selection quickly led to the development of specialized roots and shoots. Roots and shoots required the development of a vascular system to move water and other essentials around the plant and by about 400mya early vascular plants had begun to diversify. Large ferns and other seedless plants came to dominate the land in the Carboniferous Period. 3. Transition from homospory to heterospory Homospory means spores are the same size and heterospory that microspores (male) and megaspores (female) differ in size. Microspores develop into male gametophytes and megaspores into female gametophytes. 3. Transition from homospory to heterospory Mosses and most ferns are homosporous. Conifers and flowering plants are heterosporous. Homosporous plants produce spores that develop into bisexual gametophytes that produce both sperm and eggs. For successful fertilization, homosporous plants need water in the form of rainfall when gametes are mature. 3. Transition from homospory to heterospory Some homosporous plants evolved heterospory. With heterospory in which the female gametophyte is enclosed and protected and there is no need for water to ensure fertilization. Heterospory led to the evolution of seeds. 4. Evolution of the seed In mosses the life cycle is dominated by the gametophyte generation. In ferns the sporophyte generation is dominant and the gametophyte is reduced, but still visible to the naked eye. In seed plants the gametophyte generation is so reduced that in most cases it is microscopic Alternation of Generations Sequoia Slide # 16 Gymnosperms-Conifers 1. Most common gymnosperms are Conifers 2. Conifers have leaves called needles or scales have a reduced surface area and thick waxy coat on the needle to reduce water loss and prevents freezing. Pine Juniper Conifer Reproduction 1. Male cones produce pollen and the female cone produces eggs and seeds. 2. Pollen is inefficiently transferred by the wind. 3. Once mature, the scales on the female cone dry out and open scattering the seeds by the wind. Pollen Cone Pollen Seed Cone 4. Evolution of the seed The reduction of size of the female gametophyte has meant that it can be enclosed and protected within sporophyte tissue (the ovule). The female gametophyte is not dispersed and is protected from drying out and other hazards. 4. Evolution of the seed The male gametophyte is what is dispersed in seed plants. It is also protected by sporophyte tissue, the pollen grain. Pollen lands on the ovule, grows a pollen tube to carry sperm nucleus to egg nucleus and eventually fertilizes egg produced by the female gametophyte. Embryo (sporophyte 2n) then develops. Angiosperms- “enclosed seeds” 1. 2. 3. 4. These are flowering plants the encourage direct and efficient pollen transfer (smell, color and offering nectar) Pollinators are flying insects, birds, and bats that transfer pollen from flower to flower. Flowers contain ovaries, which is where eggs/seeds are produced. A fruit is the pollinated ovary containing mature seeds. Advantages of seeds Provides protection and nourishment for developing embryo. Dispersal: seeds can be dispersed more widely than spores by enclosing them in a bribe (fruit) and having animals move them. Dormancy: the developing embryo is protected and can wait a long time to germinate when conditions are good. Fruit can aid in dispersal of seed to reduce competition with parent plant. 1. Winged fruit – glides to new location (maple fruit) 2. Floating fruit – can float to new locations (coconut) 3. Fleshy fruit - sweet bright colored fruit have seeds that survive the digestive system of animals that eat the fruit (apple) 4. Spiny fruit- Velcro like projections attach to the fur of animals (cockleburs) Maple seeds: Winged fruit Burdock: Spiny fruit Seeds vs spores Seeds are better than spores because spores have a short lifetime. Spores are thinner walled and more vulnerable to pathogens and damage. Angiosperm diversification The angiosperms have been enormously successful. There are now about 235,000 species in comparison to just over 700 gymnosperms. Flowers and fruit The key to the success of the Angiosperms has been that they have evolved flowers and fruit. Fruit protects the seeds and aids in their dispersal. The fruit is a bribe. Animals eat the fruit and spread the seeds. Flowers and pollination A major advantage of flowers is that they have allowed angiosperms to use other organisms to move their pollen about. Bees, bats, birds and others all transport pollen. They are attracted to flowers by the nectar and pollen [bribes] provided by the plant and when they visit multiple flowers they move pollen from one to the next