Director's Brief
The Big Picture🎬 Plants Are Not Passive — They Respond
A plant cannot run from a drought, hide from a predator, or chase the sun across the sky on legs. But it can grow toward light, bend roots away from toxins, close stomata in drought, and even release chemical signals to warn neighbouring plants. These responses are slower than animal responses — but they are just as purposeful and just as precisely controlled.
Plant responses fall into two main categories: tropic responses (directional growth movements caused by a directional stimulus — the direction of the response depends on where the stimulus comes from) and nastic responses (non-directional — the response is the same regardless of stimulus direction).
| Response Type | Directional? | Stimulus Example | Plant Example |
|---|---|---|---|
| Positive tropism | ✅ Yes — toward stimulus | Light from one side | Shoot grows toward light |
| Negative tropism | ✅ Yes — away from stimulus | Gravity pulling down | Shoot grows upward (away from gravity) |
| Nastic response | ❌ No — same regardless of direction | Touch anywhere on leaf | Mimosa leaves fold shut |
| Taxis | ✅ Yes — whole organism moves | Light source | Single-celled algae swim toward light |
🎥 The Cast — Types of Tropism
☀️ Phototropism
Response to light. Shoots are positively phototropic — grow toward light. Roots are negatively phototropic — grow away from light.
⬇️ Gravitropism
Response to gravity. Roots are positively gravitropic — grow downward. Shoots are negatively gravitropic — grow upward.
💧 Hydrotropism
Response to water. Roots are positively hydrotropic — grow toward moisture. Can override gravitropism in dry conditions.
👆 Thigmotropism
Response to touch/contact. Tendrils of climbing plants curl around supports when they make contact — allowing the plant to climb.
Tropisms
Episode by EpisodeEach tropism is a documentary episode. Tap each card to see the narration and full mechanism.
⚙️ The Mechanism — Shoot
- Light causes unequal distribution of auxin (IAA)
- Auxin migrates away from the light — accumulates on the shaded side
- Higher auxin on dark side → faster cell elongation on that side
- Shaded side grows longer → shoot curves TOWARD light
- = Positive phototropism
⚙️ The Mechanism — Root
- Same auxin redistribution occurs in roots
- BUT roots are MORE sensitive to auxin than shoots
- High auxin concentration on shaded side INHIBITS root elongation
- Lit side grows longer → root curves AWAY from light
- = Negative phototropism
🔬 How Roots Detect Gravity
- Root cap cells contain statoliths — dense starch grains
- Statoliths sink to the lowest point in the cell in response to gravity
- Their position triggers redistribution of auxin toward the lower side
- High auxin on lower side inhibits root elongation there
- Upper side grows longer → root bends downward
- Root = positively gravitropic
🌱 How Shoots Respond
- Auxin also accumulates on the lower side of horizontal shoots
- In shoots, high auxin = more elongation (not inhibition)
- Lower side grows faster than upper side
- Shoot curves upward — away from gravity
- Shoot = negatively gravitropic
⚙️ Mechanism
- Specialised cells on the contact side detect mechanical pressure
- Auxin redistributes away from the contact side
- Cells on the non-contact side elongate more
- Tendril curves toward the contact side — curling around the support
- Repeated coiling tightens the grip
🌿 Why It Matters
- Allows climbing plants to reach light without thick supporting stems
- Energy-efficient — uses other structures for support
- Examples: pea plants, passionflower, grape vines
- The response is directional (toward the contact point) — so it IS a tropism, not a nastic response
⚙️ Mechanism
- Root cap cells detect differences in water concentration in soil
- Auxin accumulates on the drier side — inhibiting growth there
- Wetter side grows faster → root curves toward moisture
- Roots = positively hydrotropic
- In dry conditions, hydrotropism can override gravitropism
🌍 Real World Significance
- Tree roots notoriously grow toward water pipes and foundations
- Important in agriculture — irrigation placement affects root direction
- Helps plants survive drought by locating deeper water sources
Phytohormones
The Plant's Chemical Directors🧪 Plant Hormones — Slow Signals, Lasting Effects
Phytohormones (plant hormones) are chemical substances produced in small quantities in one part of a plant that are transported to other parts where they have specific effects. Unlike animal hormones, they don't travel in blood — they move through phloem, xylem, or by diffusing cell to cell. They control growth, development, responses to the environment, and reproduction.
📍 Production & Transport
- Produced in the apical meristem (shoot tip)
- Transported downward through the plant — polar auxin transport
- Can be redistributed laterally in response to light or gravity
- Moves by active transport — one direction only
⚙️ Effects
- Promotes cell elongation in shoot cells at low/moderate concentrations
- Inhibits cell elongation in roots at same concentrations (roots more sensitive)
- High concentrations inhibit lateral bud growth — apical dominance
- Promotes root formation on cuttings
- Synthetic auxins used as rooting powder and some herbicides
📍 What It Does
- Promotes internode elongation — makes stems grow taller
- Breaks seed dormancy — triggers germination
- Stimulates fruit development (sometimes without fertilisation)
- Works with auxin — together they produce more elongation than either alone
🌾 Applications
- Used commercially to produce seedless grapes (larger, without seeds)
- Applied to dwarf plants to make them grow to normal height
- Genetic dwarfism in plants = inability to produce gibberellins
- Barley germination uses gibberellins to activate enzymes that digest starch
⚙️ Effects
- Promotes fruit ripening — colour change, softening, sweetening
- Triggers leaf, flower, and fruit abscission (dropping)
- Promotes ageing (senescence) in plants
- Unusual hormone — it's a gas, not a liquid
🌍 Commercial Uses
- Bananas picked green → shipped → ethylene gas applied at destination to ripen
- Cold storage uses CO₂ to suppress ethylene — delays ripening
- Ethylene inhibitors extend shelf life of cut flowers
⚙️ Effects
- Closes stomata rapidly in drought — prevents water loss
- Promotes seed dormancy — prevents germination in unfavourable conditions
- Inhibits growth — "the stress brake"
- Antagonist to gibberellins — opposes germination signals
- Promotes leaf senescence (ageing and dropping)
🔬 Stomatal Closure Mechanism
- ABA binds to receptors on guard cells
- Triggers K⁺ ions to leave guard cells
- Guard cells lose water by osmosis → become flaccid → stomata close
- This happens within minutes of water stress being detected
Nastic Responses
Non-Directional Movements✨ Nastic Responses — Same Regardless of Direction
A nastic response is a plant movement that occurs in response to a stimulus but is NOT directional — the movement is the same no matter which direction the stimulus comes from. These are often faster and more dramatic than tropic responses, and can involve changes in cell water pressure rather than actual growth.
🌸 Photonasty — Flowers Opening and Closing
⚙️ Mechanism
Temperature and light changes trigger unequal growth of inner and outer petal cells. Inner cells elongate more with warmth/light → petals curve outward (open). Opposite at night → petals close. It is not reversible growth — it is differential growth rates.
🌺 Examples
- Tulips open in warmth, close in cold
- Daisies open in sunlight, close at night
- Responds to temperature AND light intensity
- NOT directional — opening is the same regardless of light direction
👆 Thigmonasty — The Touch Response
⚙️ Mechanism — Mimosa pudica
- Touch triggers an electrical signal (similar to animal nerves)
- Signal reaches pulvini — specialised motor cells at leaf base
- K⁺ and water rapidly leave pulvinus cells (osmosis)
- Cells become flaccid instantly → leaf folds down
- Recovery takes 15–30 minutes as water re-enters
🎯 Why It's Nastic (Not Thigmotropic)
- Response is the same no matter where you touch the leaf
- NOT growth — it's a turgor pressure change (reversible)
- Thigmotropism (tendrils) = permanent directional growth toward contact
- Thigmonasty = non-directional, reversible turgor-based movement
| Feature | Tropism | Nastic Response |
|---|---|---|
| Directional? | Yes — depends on stimulus direction | No — same regardless of direction |
| Mechanism | Unequal cell elongation (growth) | Turgor pressure changes OR differential growth |
| Reversible? | No — growth is permanent | Often yes — turgor changes are reversible |
| Speed | Hours to days | Seconds to hours |
| Hormone involved? | Yes — mainly auxin | Often turgor-based — no hormones needed |
| Example | Shoot bending toward light | Mimosa leaf folding when touched |
🎯 Documentary Final Exam
Eight questions. Did you pay attention during filming?