logging in or signing up Chapter38 Octavio Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 1732 Category: Entertainment License: All Rights Reserved Like it (2) Dislike it (0) Added: August 14, 2007 This Presentation is Public Favorites: 1 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Chapter 38 Plant Reproduction and Development: Chapter 38 Plant Reproduction and Development Flowers: Flowers Sexual organs of Angiosperms. Develop from compressed shoots with four whorls of modified leaves. Flower Whorls: Flower Whorls 1. Sepals 2. Petals 3. Stamens 4. Carpels Sepals: Sepals Whorl of sterile leaf-like structures. May be brightly colored. Function Protect other flower parts. Attract pollinators. Petals: Petals Whorl of sterile flower parts. Often brightly colored. Function Attract pollinators. Stamens: Stamens Male reproductive flower structure. Function Produce pollen (sperm). Stamen Structure: Stamen Structure Anther - pollen producing sac. Filament - stalk. Carpel: Carpel Female reproductive flower structure. Also called pistil. Function Produce embryo sac (eggs). Carpel Structure: Carpel Structure Stigma – receives the pollen. Style – stalk. Ovary – contains the ovules. Ovule: Ovule A rudimentary seed before fertilization. Flowers: Flowers Are highly variable in form, shape, and color. Not all flowers contain the same combination of whorls. Flower Variations: Flower Variations Complete Flowers - have all four whorls. Incomplete Flowers – less than all four whorls. Flower Variations: Flower Variations Perfect Flowers - have stamens and carpels. Imperfect Flowers - have stamens or carpels. Staminate Flower Carpellate Flower Monoecious Plants: Monoecious Plants Staminate and pistillate flowers are on the same plant. Ex: corn Tassel – staminate flowers Ears – carpellate flowers Dioecious Plants: Dioecious Plants Have staminate or pistillate flowers, but not both. Ex: Holly, Ginkgo Comment - 'Seedless' plants may be a staminate plant. Ex: male Ginkgo Pollen Development: Pollen Development Pollen is the male gametophyte. Starts with a 2N cell called a microsporocyte. Microsporocyte: Microsporocyte Undergoes meiosis and produces 4 Microspores (1N). Each Microspore undergoes mitosis and produces a pollen grain, which is the male gametophyte. Mature Pollen Grain: Mature Pollen Grain Special cell wall. Tube Nucleus (cell). Generative Nucleus (cell) which will divide and produce two sperm nuclei. Slide19: Embryo Sac Development: Embryo Sac Development The Embryo Sac is the female gametophyte. Starts with a megasporocyte (2N). Megasporocyte: Megasporocyte Undergoes meiosis and produces 4 Megaspores (1N). Three of the megaspores abort, leaving only one to develop into the embryo sac. Megaspore: Megaspore Undergoes three rounds of mitosis to produce a 'sac' with 8 nuclei. The nuclei may wall off or may remain as part of a large cell. Embryo Sac: Embryo Sac 3 Antipodal cells. 2 Polar nuclei (1 cell) 2 Synergid cells 1 Egg cell Slide24: Pollination: Pollination The transfer of pollen from a stamen to the stigma. Pollen Vectors: Pollen Vectors Bees Flies Butterflies Moths Birds Beetles Bats Wind Comment: Comment The flower is usually highly adapted to the pollen vector. Ex: Colors Rewards Scents Shape Movie – bat pollination Fertilization: Fertilization The union of egg and sperm to produce a zygote (2N). Movie Angiosperms: Angiosperms Have double fertilization. 1. Egg + sperm zygote 2. Polar nuclei + sperm Endosperm Endosperm: Endosperm Is Triploid (3N) tissue that will be used as a nutrition source for the embryo. After Fertilization: After Fertilization Zygote Embryo Ovule Seed Ovary Fruit Movie – Seed Development: Movie – Seed Development Embryo Development: Embryo Development Root/shoot polarity set with 1st cell division. Mature embryo has all three primary tissues, apical meristems etc. Endosperm: Endosperm Monocots - large tissue. Dicots - transfer the energy over to the embryo's two cotyledons. Seed Coat: Seed Coat Formed from the integuments of the ovule. Hard layer to protect the seed. Fruit: Fruit A mature ovary. Sometimes includes other plant parts. Ex: apple Movie – Fruit Development: Movie – Fruit Development Fruit Functions: Fruit Functions Protect the seeds. Aid in seed dispersal. Fruit Types: Fruit Types Fleshy: soft ovary walls. Dry: hard ovary walls. Fruit Types: Fruit Types Simple Fruit: from a single ovary. Ex: Peach, Cherry Aggregate Fruit: from a flower with multiple carpels. Ex: Raspberry Multiple Fruit: develops from several flowers into one structure. Ex: Pineapple Slide41: Seeds: Seeds Contain a miniature plant. Main dispersal mechanism for plants. Embryo is often 'dormant' when the seed is mature. Seed Dormancy: Seed Dormancy When a seed is not actively growing. Used to increase the chances that the plant will develop when conditions are favorable. Seed Dormancy: Seed Dormancy Usually controlled by plant hormones. May require changes in temperature, moisture, etc. before growth will continue. Imbibition: Imbibition The absorption of water by a seed. First step in seedling growth. Causes 'swelling' which ruptures the seed coat. Starts metabolism to resume growth. Germination: Germination The continuation of growth of the plant within a seed. Root usually emerges first. Shoot tip must break through the soil surface. Role of Light: Role of Light Light is the usual clue that the shoot has broken above ground. Light causes many growth changes in the shoot Ex. Leaves to expand Stem elongation rate decreases Asexual Reproduction: Asexual Reproduction Offspring produced by mitosis. Also called 'cloning'. Normal Method: Normal Method Fragmentation of the plant body so that new plants are formed. Ex: Cuttings Grafting Offshoots High-Tech Methods: High-Tech Methods Tissue Culture. Protoplasts (naked cells) Tissue Culture: Tissue Culture Clumps of cells grow into embryoids which can be used to regenerate whole plants. Often used in genetic engineering of plants. Slide52: Protoplast Fusion. A 'naked' plant cell (no cell wall). Used to create new hybrids Plants: Plants Frequently use both sexual and asexual reproduction depending on the environment. Asexual - stable Sexual - unstable Plant Development: Plant Development Growth: increase in size Development: changes in body form and structure. Plant Problems: Plant Problems Determining the direction of cell growth because of the cell wall. Control Mechanism: Control Mechanism Cytoskeleton: determines the direction of cell expansion. Cellulose Microfibrils: are arranged in parallel strips as guided by microtubules in the cell membrane. Slide57: Cell Expansion: Cell Expansion Increase in cell size is usually caused by turgor pressure. Direction of cell increase is at right angles to the cellulose mircofibrils. Slide59: Cell Differentiation: Cell Differentiation Depends on the control of gene expression. (review previous chapters on this topic) Positional Information: Positional Information Gradients of chemicals that provide clues of position of cells to each other. Ex: why some cells develop into shoots and others into roots. Important in plants as cells don’t migrate. Pattern Formation: Pattern Formation The development of specific structures in specific locations. Important in plants since cells don’t usually migrate. Juvenile Mature Organ-Identity Genes: Organ-Identity Genes Genes for normal organ development. Used in positional information to determine which organ the cells should develop into. Example: Example The combination of three genes that give rise to the flower parts. A sepals A + B petals B + C stamens C carpels Mutations: Mutations Cause other floral parts to form in the flowers. (review Chapter 21). Summary: Summary Know the general structures of flowers. Know the general life cycle of flowers. Review the items on plant development. You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
Chapter38 Octavio Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINT Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 1732 Category: Entertainment License: All Rights Reserved Like it (2) Dislike it (0) Added: August 14, 2007 This Presentation is Public Favorites: 1 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript Chapter 38 Plant Reproduction and Development: Chapter 38 Plant Reproduction and Development Flowers: Flowers Sexual organs of Angiosperms. Develop from compressed shoots with four whorls of modified leaves. Flower Whorls: Flower Whorls 1. Sepals 2. Petals 3. Stamens 4. Carpels Sepals: Sepals Whorl of sterile leaf-like structures. May be brightly colored. Function Protect other flower parts. Attract pollinators. Petals: Petals Whorl of sterile flower parts. Often brightly colored. Function Attract pollinators. Stamens: Stamens Male reproductive flower structure. Function Produce pollen (sperm). Stamen Structure: Stamen Structure Anther - pollen producing sac. Filament - stalk. Carpel: Carpel Female reproductive flower structure. Also called pistil. Function Produce embryo sac (eggs). Carpel Structure: Carpel Structure Stigma – receives the pollen. Style – stalk. Ovary – contains the ovules. Ovule: Ovule A rudimentary seed before fertilization. Flowers: Flowers Are highly variable in form, shape, and color. Not all flowers contain the same combination of whorls. Flower Variations: Flower Variations Complete Flowers - have all four whorls. Incomplete Flowers – less than all four whorls. Flower Variations: Flower Variations Perfect Flowers - have stamens and carpels. Imperfect Flowers - have stamens or carpels. Staminate Flower Carpellate Flower Monoecious Plants: Monoecious Plants Staminate and pistillate flowers are on the same plant. Ex: corn Tassel – staminate flowers Ears – carpellate flowers Dioecious Plants: Dioecious Plants Have staminate or pistillate flowers, but not both. Ex: Holly, Ginkgo Comment - 'Seedless' plants may be a staminate plant. Ex: male Ginkgo Pollen Development: Pollen Development Pollen is the male gametophyte. Starts with a 2N cell called a microsporocyte. Microsporocyte: Microsporocyte Undergoes meiosis and produces 4 Microspores (1N). Each Microspore undergoes mitosis and produces a pollen grain, which is the male gametophyte. Mature Pollen Grain: Mature Pollen Grain Special cell wall. Tube Nucleus (cell). Generative Nucleus (cell) which will divide and produce two sperm nuclei. Slide19: Embryo Sac Development: Embryo Sac Development The Embryo Sac is the female gametophyte. Starts with a megasporocyte (2N). Megasporocyte: Megasporocyte Undergoes meiosis and produces 4 Megaspores (1N). Three of the megaspores abort, leaving only one to develop into the embryo sac. Megaspore: Megaspore Undergoes three rounds of mitosis to produce a 'sac' with 8 nuclei. The nuclei may wall off or may remain as part of a large cell. Embryo Sac: Embryo Sac 3 Antipodal cells. 2 Polar nuclei (1 cell) 2 Synergid cells 1 Egg cell Slide24: Pollination: Pollination The transfer of pollen from a stamen to the stigma. Pollen Vectors: Pollen Vectors Bees Flies Butterflies Moths Birds Beetles Bats Wind Comment: Comment The flower is usually highly adapted to the pollen vector. Ex: Colors Rewards Scents Shape Movie – bat pollination Fertilization: Fertilization The union of egg and sperm to produce a zygote (2N). Movie Angiosperms: Angiosperms Have double fertilization. 1. Egg + sperm zygote 2. Polar nuclei + sperm Endosperm Endosperm: Endosperm Is Triploid (3N) tissue that will be used as a nutrition source for the embryo. After Fertilization: After Fertilization Zygote Embryo Ovule Seed Ovary Fruit Movie – Seed Development: Movie – Seed Development Embryo Development: Embryo Development Root/shoot polarity set with 1st cell division. Mature embryo has all three primary tissues, apical meristems etc. Endosperm: Endosperm Monocots - large tissue. Dicots - transfer the energy over to the embryo's two cotyledons. Seed Coat: Seed Coat Formed from the integuments of the ovule. Hard layer to protect the seed. Fruit: Fruit A mature ovary. Sometimes includes other plant parts. Ex: apple Movie – Fruit Development: Movie – Fruit Development Fruit Functions: Fruit Functions Protect the seeds. Aid in seed dispersal. Fruit Types: Fruit Types Fleshy: soft ovary walls. Dry: hard ovary walls. Fruit Types: Fruit Types Simple Fruit: from a single ovary. Ex: Peach, Cherry Aggregate Fruit: from a flower with multiple carpels. Ex: Raspberry Multiple Fruit: develops from several flowers into one structure. Ex: Pineapple Slide41: Seeds: Seeds Contain a miniature plant. Main dispersal mechanism for plants. Embryo is often 'dormant' when the seed is mature. Seed Dormancy: Seed Dormancy When a seed is not actively growing. Used to increase the chances that the plant will develop when conditions are favorable. Seed Dormancy: Seed Dormancy Usually controlled by plant hormones. May require changes in temperature, moisture, etc. before growth will continue. Imbibition: Imbibition The absorption of water by a seed. First step in seedling growth. Causes 'swelling' which ruptures the seed coat. Starts metabolism to resume growth. Germination: Germination The continuation of growth of the plant within a seed. Root usually emerges first. Shoot tip must break through the soil surface. Role of Light: Role of Light Light is the usual clue that the shoot has broken above ground. Light causes many growth changes in the shoot Ex. Leaves to expand Stem elongation rate decreases Asexual Reproduction: Asexual Reproduction Offspring produced by mitosis. Also called 'cloning'. Normal Method: Normal Method Fragmentation of the plant body so that new plants are formed. Ex: Cuttings Grafting Offshoots High-Tech Methods: High-Tech Methods Tissue Culture. Protoplasts (naked cells) Tissue Culture: Tissue Culture Clumps of cells grow into embryoids which can be used to regenerate whole plants. Often used in genetic engineering of plants. Slide52: Protoplast Fusion. A 'naked' plant cell (no cell wall). Used to create new hybrids Plants: Plants Frequently use both sexual and asexual reproduction depending on the environment. Asexual - stable Sexual - unstable Plant Development: Plant Development Growth: increase in size Development: changes in body form and structure. Plant Problems: Plant Problems Determining the direction of cell growth because of the cell wall. Control Mechanism: Control Mechanism Cytoskeleton: determines the direction of cell expansion. Cellulose Microfibrils: are arranged in parallel strips as guided by microtubules in the cell membrane. Slide57: Cell Expansion: Cell Expansion Increase in cell size is usually caused by turgor pressure. Direction of cell increase is at right angles to the cellulose mircofibrils. Slide59: Cell Differentiation: Cell Differentiation Depends on the control of gene expression. (review previous chapters on this topic) Positional Information: Positional Information Gradients of chemicals that provide clues of position of cells to each other. Ex: why some cells develop into shoots and others into roots. Important in plants as cells don’t migrate. Pattern Formation: Pattern Formation The development of specific structures in specific locations. Important in plants since cells don’t usually migrate. Juvenile Mature Organ-Identity Genes: Organ-Identity Genes Genes for normal organ development. Used in positional information to determine which organ the cells should develop into. Example: Example The combination of three genes that give rise to the flower parts. A sepals A + B petals B + C stamens C carpels Mutations: Mutations Cause other floral parts to form in the flowers. (review Chapter 21). Summary: Summary Know the general structures of flowers. Know the general life cycle of flowers. Review the items on plant development.