9.3.2 - Plant Hormones
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Introduction to Plant Hormones
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Today we will be discussing plant hormones, which are essential for regulating growth and development in plants. Can anyone tell me what they think a plant hormone does?
I think they help plants grow!
That's correct! Plant hormones help control various processes like cell division and elongation. They are active at very low concentrations. For example, auxins are known for promoting growth in response to light, a process called phototropism. What's phototropism?
Is it when plants grow towards light?
Yes! To remember this, think of A for Auxins and A for Attraction to light. Great job!
Types of Plant Hormones
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Now, letβs dive deeper into specific types of plant hormones. First up is auxin. What does auxin do?
It helps with cell elongation!
Exactly! Auxins also help maintain apical dominance. This means they inhibit the growth of lateral buds so that energy is focused on growing upwards. What about gibberellins?
They help with flowering and seed germination!
Correct again! Gibberellins stimulate these processes and contribute to elongation as well. An easy way to remember it is that gibberellins make things grow tall like a 'gibbering giant'!
Stress Responses and Aging
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Letβs talk about how some hormones help plants survive stress and manage aging. Who can explain what abscisic acid does?
I think it closes stomata when there's not enough water?
Great memory! Abscisic acid is critical in water stress response. It helps prevent water loss. And how does ethylene affect plants?
Ethylene makes fruits ripen and causes leaves to drop?
Exactly right! Ethylene signals for ripening and leaf abscission or shedding. To help remember, just think of 'E for Ethylene, E for Everything ripening!'
Tropisms linked to Hormones
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Finally, let's look at how hormones relate to tropisms. Can anyone tell me the types of tropisms we discussed?
Phototropism and gravitropism!
Exactly! Phototropism is the response to light and gravitropism is the response to gravity. Auxins are primarily responsible for these responses. How do you think auxins achieve this?
They move to the side thatβs away from light, causing the plant to bend!
Yes! The unequal distribution of auxins causes one side to elongate more, bending the plant towards the light.
Introduction & Overview
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Quick Overview
Standard
This section explores the various types of plant hormones, including auxins, gibberellins, cytokinins, abscisic acid, and ethylene, and their roles in processes such as cell division, elongation, and plant tropisms. It also discusses the impact of hormones on meristems and micropropagation techniques.
Detailed
Plant Hormones
Plant hormones, or phytohormones, are crucial in regulating plant growth and development. They function at low concentrations and have various roles:
- Auxins (like IAA): These hormones promote cell elongation by loosening the cell walls, are involved in phototropism (growth towards light) and gravitropism (growth in response to gravity), and maintain apical dominance, inhibiting lateral bud growth.
- Gibberellins: Primarily stimulate stem elongation, seed germination, and flowering processes. They are named from a fungus (Gibberella) that was found to cause excessive growth.
- Cytokinins: These hormones promote cell division and differentiation in plants and help delay leaf senescence (aging).
- Abscisic Acid (ABA): Known for its role in stress responses, ABA induces stomatal closure during water stress and maintains seed dormancy.
- Ethylene: A gaseous hormone that promotes fruit ripening and leaf abscission, signaling the plant to shed leaves under certain conditions.
Additionally, plant growth responses to environmental factors (tropisms) are mediated by these hormones, while techniques like micropropagation utilize specific hormone ratios to promote the desired growth outcomes.
Understanding these hormones is vital for both plant science and agricultural practices.
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Auxins (IAA)
Chapter 1 of 5
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Chapter Content
Auxins (e.g., IAA):
β Promote cell elongation by loosening cell walls.
β Involved in phototropism and gravitropism by redistributing in response to light and gravity.
β Maintain apical dominance by inhibiting lateral bud growth.
Detailed Explanation
Auxins, such as Indole-3-acetic acid (IAA), are plant hormones that play a critical role in promoting cell elongation, which allows plants to grow taller. They achieve this by loosening the cell walls, making it easier for the cells to expand. Auxin levels also change in response to light (phototropism) and gravity (gravitropism). For example, when a plant is exposed to light, auxins accumulate on the shaded side, causing those cells to elongate more and thus bending the plant towards the light. Furthermore, auxins help maintain apical dominance, meaning they inhibit the growth of lateral buds to keep the plant focused on growing upward rather than outward.
Examples & Analogies
Imagine you have a group of people trying to reach the top of a staircase. If the people at the front (the leaders) encourage everyone else to keep moving upward, the group will focus their energy on going higher rather than spreading out to the sides. In this analogy, the leaders represent auxins that promote upward growth, while the rest of the group represents other parts of the plant like lateral buds that are suppressed.
Gibberellins
Chapter 2 of 5
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Chapter Content
Gibberellins:
β Stimulate stem elongation, seed germination, and flowering.
Detailed Explanation
Gibberellins are another important class of plant hormones that stimulate growth processes. They particularly enhance stem elongation, which contributes to the overall height of the plant. Additionally, gibberellins play a vital role in the germination of seeds, where they help break dormancy and initiate growth. They are also involved in signaling the plant to flower, particularly in response to specific conditions like longer days and warmer temperatures.
Examples & Analogies
Think of gibberellins as pep talks for a sports team before a big game. Just as a coach encourages players to perform their best, gibberellins encourage seeds to grow, help stems elongate, and trigger flowers to bloom. They give plants that extra boost they need to reach their full potential.
Cytokinins
Chapter 3 of 5
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Chapter Content
Cytokinins:
β Promote cell division and differentiation.
β Delay leaf senescence.
Detailed Explanation
Cytokinins are hormones that are crucial for promoting cell division and differentiation, which are essential processes in plant growth. These hormones help stimulate the production of new cells in both roots and shoots, contributing to overall plant health. Additionally, cytokinins play a role in delaying leaf senescence, which is the process of aging and death in leaves. By keeping leaves healthier for longer, cytokinins assist the plant in maximizing its ability to photosynthesize.
Examples & Analogies
Consider cytokinins like a good manager at a factory who ensures that production lines are running efficiently and that workers are motivated to keep their jobs. Just as a good manager can help the factory grow by keeping workers engaged and productive, cytokinins enhance plant growth by promoting division and keeping leaves alive longer.
Abscisic Acid (ABA)
Chapter 4 of 5
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Chapter Content
Abscisic Acid (ABA):
β Induces stomatal closure during water stress.
β Maintains seed dormancy.
Detailed Explanation
Abscisic Acid (ABA) is a plant hormone that plays a crucial role in stress responses, particularly during water scarcity. It signals for the closure of stomata, which are tiny openings on leaf surfaces that allow gas exchange. By closing these stomata, the plant reduces water loss, which is vital during times of drought. Additionally, ABA is involved in maintaining seed dormancy by keeping seeds inactive until conditions are favorable for germination.
Examples & Analogies
Imagine a person deciding to close the windows in their house during a storm to keep water out. Similarly, abscisic acid helps plants conserve water when they are stressed by closing their stomata. Just as the person waits for the storm to pass before opening the windows again, seeds will remain dormant thanks to ABA until itβs the right time for them to grow.
Ethylene
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Chapter Content
Ethylene:
β Promotes fruit ripening and leaf abscission.
Detailed Explanation
Ethylene is a unique plant hormone that exists in gaseous form. It plays a significant role in the ripening of fruit, as it triggers the breakdown of cell walls, starches, and acids, leading to changes in texture and flavor. Ethylene also regulates the process of leaf abscission, which is the shedding of leaves. This is particularly important in autumn when trees prepare for winter by losing leaves to conserve resources.
Examples & Analogies
Think of ethylene as a countdown timer for fruit. As the fruit matures, it 'hears' the timer and starts the ripening process, much like how we prepare for a scheduled event. Similarly, in autumn, trees 'know' itβs time to drop their leaves, akin to how we may pack away summer clothes when the weather changes.
Key Concepts
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Plant hormones are crucial for growth regulation.
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Auxins promote cell elongation and affect phototropism.
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Gibberellins stimulate growth and flowering.
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Cytokinins delay aging and promote cell division.
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Abscisic acid helps prevent water loss.
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Ethylene influences fruit ripening.
Examples & Applications
Auxins are used in rooting hormone products for propagation.
Gibberellins are applied to enhance seedlessness in grapes.
Memory Aids
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Rhymes
Auxins help plants grow tall, Gibberellins make seeds all; Cytokinins keep leaves bright, ABA conserves in the night.
Stories
Once in a garden, a magical plant utilized auxins to stretch and follow the sun, while gibberellins danced around seeds, making them sprout joyfully.
Memory Tools
Remember 'AGE' for plant hormones: A for Auxin, G for Gibberellins, E for Ethylene.
Acronyms
Think of 'CAGE' to memorize Cytokinins, Abscisic acid, Gibberellins, Ethylene.
Flash Cards
Glossary
- Auxins
Plant hormones that promote cell elongation and regulate phototropism and gravitropism.
- Gibberellins
Hormones that stimulate stem elongation, seed germination, and flowering.
- Cytokinins
Hormones that promote cell division and delay leaf senescence.
- Abscisic Acid (ABA)
Hormone that induces stomatal closure during water stress and maintains seed dormancy.
- Ethylene
Gaseous hormone that promotes fruit ripening and leaf abscission.
- Phototropism
Plant growth response to light direction.
- Gravitropism
Plant growth response to gravity.
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