Chapter 22 Lecture- Plants

22–1 Introduction to Plants

What Is a Plant? Plants are multicellular eukaryotes that have cell walls made of cellulose. Plants develop from multicellular embryos and carry out photosynthesis using the green pigments chlorophyll a and b.

What Is a Plant? Plants include trees, shrubs, and grasses, as well as other organisms, such as mosses and ferns. Most plants are autotrophs, although a few are parasites or saprobes that live on decaying materials.

The Plant Life Cycle Plant life cycles have two alternating phases, a diploid (2N) phase and a haploid (N) phase, known as alternation of generations.

The Plant Life Cycle During the two phases of the life cycle, mitosis and meiosis alternate to produce the two types of reproductive cells—gametes and spores. The diploid (2N) phase is called the sporophyte, or spore-producing plant. The haploid (N) phase is called the gametophyte, or gamete-producing plant.

The Plant Life Cycle Plant spores are haploid (N) reproductive cells formed in the sporophyte by meiosis. The spores can grow into new organisms called gametophytes. A gamete is a reproductive cell produced by mitosis, and it can fuse with another gamete to produce the sporophyte.

What Plants Need to Survive In order to survive, plants need: sunlight water and minerals gas exchange transport of water and nutrients throughout the plant body

What Plants Need to Survive Sunlight Plants use energy from sunlight to carry out photosynthesis. Photosynthetic organs such as leaves are broad and flat to maximize light absorption.

What Plants Need to Survive Water and Minerals All cells require a constant supply of water. Water is used up quickly when the sun is shining. As a result, plants have structures that limit water loss.

What Plants Need to Survive As they absorb water, plants also absorb minerals. Minerals are nutrients in the soil needed for plant growth.

What Plants Need to Survive Gas Exchange Plants require oxygen to support cellular respiration as well as carbon dioxide to carry out photosynthesis. They must exchange these gases with the atmosphere without losing excessive amounts of water through evaporation.

What Plants Need to Survive Movement of Water and Nutrients Plants take up water and minerals through their roots, but they make food in their leaves. Most plants have specialized tissues that carry water and nutrients from the soil and distribute products of photosynthesis throughout the plant body. Simpler plants carry out these functions by diffusion.

Early Plants Early Plants When plants first appeared, life on Earth changed. As plants colonized the land, they changed the environment so other organisms could develop. New ecosystems arose, and organic matter began to form soil.

Early Plants The first plants evolved from an organism similar to the multicellular green algae living today.

Early Plants Multicellular green algae have the size, color, and appearance of plants. They have reproductive cycles similar to those of plants. Green algae also have cell walls and photosynthetic pigments that are identical to those of plants.

Early Plants The First Plants DNA sequences confirm that plants are closely related to certain groups of green algae , suggesting that the ancestors of the first plants were indeed algae.

Early Plants The oldest known plant fossils, about 450 million years old, are similar to today’s mosses. They had a simple structure and grew close to the ground.

Early Plants Fossils suggest that the first plants needed water to complete their life cycles. The demands of life on land favored the evolution of plants that were: more resistant to the drying rays of the sun. more capable of conserving water. more capable of reproducing without water.

Early Plants From these plants, several major groups of plants evolved. One group developed into the mosses and their relatives. Another group gave rise to all other plants. All plants have evolved different adaptations for a variety of terrestrial environments.

Overview of the Plant Kingdom Overview of the Plant Kingdom Plants are divided into four groups based on these features: water-conducting tissues seeds flowers Plants are also classified by other features, including reproductive structures and body plan.

in the Plant Kingdom Evolutionary Relationships Flowering plants Cone-bearing plants Ferns and their relatives Mosses and their relatives Flowers; Seeds enclosed in fruit Water-conducting (vascular) tissue Seeds Green algae ancestor

Overview of the Plant Kingdom Today, scientists can classify plants more precisely by comparing the DNA sequences of various species.

Mosses and their relatives are called bryophytes, or nonvascular plants. They do not have vascular tissues, or specialized tissues that conduct water and nutrients. Bryophytes

Bryophytes have life cycles that depend on water for reproduction. Bryophytes draw up water by osmosis only a few centimeters above the ground.

During one stage of their life cycle, bryophytes produce sperm that swim through water to reach eggs of other individuals. Therefore, bryophytes must live where there is rainfall or dew for part of the year. Bryophytes

Bryophytes are low-growing plants found in moist, shaded areas.

The three groups of bryophytes are: mosses liverworts hornworts

The most common bryophytes are mosses. Mosses: are adapted to life in wet habitats and nutrient-poor soils. can tolerate low temperatures. are clumps of gametophytes growing together.

The Structure of a Moss Stalk Capsule Sporophyte Gametophyte Stemlike structure Leaflike structure Rhizoid

Each moss plant has a shoot that looks like a stem with leaves. These are not true stems or leaves, because they do not contain vascular tissue.

Groups of Bryophytes When mosses reproduce, they produce thin stalks, each containing a capsule. This is the sporophyte stage.

The “leaves” of mosses are one cell thick, so they lose water quickly if the surrounding air is dry.

Life Cycle of Bryophytes Bryophytes reproduce and develop by alternation of generations. For bryophytes, the gametophyte is the dominant stage of the life cycle and is the stage that carries out most of the plant's photosynthesis.

Life Cycle of Bryophytes Life Cycle of a Moss The life cycle of a moss illustrates how bryophytes reproduce and develop.

Gametophyte (N) Mature sporophyte (2N) Gametophyte (N)

22–3 Seedless Vascular Plants

420 million years ago, mosslike plants on land were joined by taller plants. Evidence shows that these plants had vascular tissue, which is specialized to conduct water and nutrients throughout the plant. Evolution of Vascular Tissue

Evolution of Vascular Tissue The first vascular plants contained tracheids which are cells specialized to conduct water. Tracheids make up xylem, a transport subsystem that carries water from the roots to every part of a plant.

Tracheids are hollow with thick cell walls that resist pressure. They connect end to end to allow water to move efficiently.

Evolution of Vascular Tissue Vascular plants have a second transport subsystem composed of vascular tissue called phloem. Phloem transports solutions of nutrients and carbohydrates produced by photosynthesis.

Evolution of Vascular Tissue Both xylem and phloem can move fluids through the plant body, even against the force of gravity.

Evolution of Vascular Tissue Together xylem and phloem move water, nutrients, and other materials throughout the plant. Xylem and lignin (a substance that makes cell walls rigid) enable some plants to grow upright and tall.

Ferns and Their Relatives Seedless vascular plants include: club mosses horsetails ferns

Ferns and Their Relatives The most numerous phylum is the ferns. Ferns and their relatives have true roots, leaves, and stems.

Life Cycle of Ferns Roots are underground organs that absorb water and minerals. Leaves are photosynthetic organs that contain one or more bundles of vascular tissue. Tissue is gathered into veins made of xylem and phloem. Stems are supporting structures that connect roots and leaves, carrying water and nutrients between them.

Ferns and Their Relatives Club Mosses Ancient club mosses grew into trees and produced forests. Fossilized remains of these exist today as huge beds of coal. Today, club mosses are small plants that live in moist woodlands.

Ferns and Their Relatives Horsetails The only living genus of Arthrophyta is Equisetum. Equisetum has true leaves, stems, and roots. Equisetum is called horsetail, or scouring rush.

Ferns and Their Relatives Ferns Ferns probably evolved 350 million years ago, when club moss forests covered Earth. Ferns thrive in wet areas with little light.

Life Cycle of Ferns Ferns have vascular tissues, strong roots, underground stems called rhizomes, and leaves called fronds.

Life Cycle of Ferns Ferns and other vascular plants have a life cycle in which the diploid sporophyte is the dominant stage.

Life Cycle of Ferns Fern sporophytes develop haploid spores on the underside of their fronds in structures called sporangia. Sporangia are grouped into clusters called sori.

The Underside of a Fern Frond Sorus Sporangia

Life Cycle of Ferns Young gametophyte (N) Mature gametophyte (N) Egg Archegonium Sperm Antheridium Spores (N) Sporangium (2N) Frond Mature sporophyte (2N) Gametophyte (N) Sporophyte embryo (2N) Developing sporophyte (2N)

Life Cycle of Ferns When the spores germinate, they develop into haploid gametophytes. The gametophyte first grows a set of rootlike rhizoids. It then flattens into a mature gametophyte. The gametophyte grows independently of the sporophyte.

Life Cycle of Ferns The antheridia and archegonia are found on the underside of the gametophyte. In ferns, fertilization requires water, which allows the sperm to swim to the eggs.

Life Cycle of Ferns Spores (N) Antheridium Sperm Archegonium Egg Mature gametophyte (N) Young gametophyte (N)

Life Cycle of Ferns The diploid zygote formed by fertilization, develops into a new sporophyte. As the sporophyte grows, the gametophyte withers away. Fern sporophytes often live for many years. In some species, fronds die in the fall, but rhizomes live through the winter and produce new leaves in the spring.

Frond Mature sporophyte (2N) Gametophyte (N) Sporophyte embryo (2N) Developing sporophyte (2N) Sporangium (2N)

Seed plants are the most dominant group of photosynthetic organisms on land.

Seed plants are divided into two groups: Gymnosperms bear seeds directly on the surfaces of cones. Angiosperms, or flowering plants, bear seeds within a layer of tissue that protects the seed.

Gymnosperms include conifers, cycads, & ginkgoes. Angiosperms include grasses, flowering trees and shrubs, and all species of flowers.

Reproduction Free From Water Seed plants have a life cycle that alternates between a gametophyte stage and a sporophyte stage. Seed plants do not need water for fertilization of gametes. Seed plants can live just about anywhere.

Reproduction Free From Water Adaptations that allow seed plants to reproduce without water include: flowers or cones the transfer of sperm by pollination the protection of embryos in seeds

Cones and Flowers Gametophytes grow within sporophytes called cones, which are the seed-bearing structures of gymnosperms, and flowers, which are the seed-bearing structures of angiosperms. Gametophyte generations live inside these structures.

Pollen The male gametophyte is contained in a tiny structure called a pollen grain. Sperm do not need water to fertilize eggs; instead the pollen grain is carried to the female reproductive structure by wind, insects, or small animals. This transfer of pollen is called pollination.

Seeds A seed is an embryo of a plant that is encased in a protective covering and surrounded by a food supply. An embryo is an organism in its early stage of development. The seed coat surrounds and protects the embryo and keeps contents of the seed from drying out.

Reproduction Free From Water Seeds may have special tissues or structures that aid in their dispersal to other habitats. Some seed coats stick to the fur or feathers of animals. Other seeds are within tissues eaten and dispersed by animals.

Reproduction Free From Water After fertilization, the zygote grows into a plant—the embryo. The embryo can stop growing while it is within the seed, and it can remain this way for a long time. When it grows, it uses nutrients from the stored food supply. Seeds can survive extreme cold or heat, or even drought.

Evolution of Seed Plants Evolution of Seed Plants The fossil record indicates that ancestors of seed plants evolved adaptations enabling them to survive where most mosses and ferns could not. The most important of these adaptations was the seed itself. A seed can survive dry conditions and extreme temperatures.

22–5 Angiosperms—Flowering Plants

The majority of living plant species are flowering plants, or angiosperms. Flowers and Fruits

Flowers and Fruits Angiosperms develop unique reproductive organs known as flowers.

Flowers are an evolutionary advantage because they attract animals, which then transport pollen from flower to flower. Flowers contain ovaries, which surround and protect the seeds. After pollination, the ovary develops into a fruit. A fruit is a wall of tissue that surrounds a seed. A fruit protects the seed and aids in its dispersal.

Chapter 22 Lecture- Plants

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Chapter 22 Lecture- Plants