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  • [INTRO ♪]

  • Plants don't have brains.

  • This is probably not news to anyone.

  • Plants also don't have muscles, or anything resembling a nervous system, and yetthey can move.

  • In some plants, this is actually pretty dramaticthink Venus flytraps.

  • But there are tons of plants that move more slowly, and they do it in time with the coming of day and night.

  • So how do they move, and how do they know when to do it, all without a brain or any of that other stuff?

  • Many plants, such as members of the legume and wood sorrel families, tuck their leaves in at night.

  • We don't totally understand how this happens, and we have almost no idea why.

  • But scientists have identified some of the players involved.

  • The process of how plants tuck themselves in at night is called nyctinasty.

  • Nastic movements are a plant's movement in response to a stimulus that doesn't occur in a particular direction.

  • The leaves don't follow the moon or anythingthey just droop.

  • Temperature change plays a role in this response: the cooler night air can help signal the plant's reaction, and the warming sun in the morning does the opposite.

  • But it gets quite a bit more sophisticated than that, involving not just temperature changes, but several different types of chemical reactions.

  • One player in this process is a molecule called phytochrome, which absorbs light.

  • Phytochrome participates in a reversible chemical reaction, meaning it doesn't just react to form a product and then stop.

  • Instead, it can switch back and forth between two different forms, depending on the conditions.

  • These two forms are called Pr and Pfr.

  • Initially, phytochrome takes the form Pr, so called because it absorbs red light, which there's more of during the day when the sun is out.

  • As Pr absorbs red light, however, it is converted into Pfr, which absorbs far red light insteadbasically the less intense wavelengths as the sun sets.

  • Absorption of far red light causes Pfr to convert back to Pr.

  • Some of it will change back over time in the absence of any light, as well.

  • Which means the phytochrome automatically cycles back and forth between forms depending on whether it's day or night.

  • These changing forms of phytochrome are important in structures called pulvini.

  • A pulvinus is a region of bulbous tissue at the base of a leaf that acts as a flexible jointit's like a “plant elbow”.

  • When enough Pfr is present in the pulvinus, the plant pumps water to a specific section of the joint.

  • The change in water pressure within the cells, called turgor pressure, basically flexes the joint like a muscle, which bundles the leaves up for the night.

  • When the chemical reaction reverses, the turgor pressure shifts back.

  • Additional leaf chemicals called leaf-closing and leaf-opening substances also play a part in nighttime, well, leaf opening and closing.

  • There's a lot of variety in these chemicals, but the general idea of oscillating chemical reactions is similar.

  • In the same way, many flowers open in the morning and close at night, for reasons that are even more poorly understood.

  • It might be to conserve a flower's scent, to protect their nectar, to keep pollen dry, or some other reasonbut the mechanism might be similar.

  • Petals, after all, are just a type of leaf.

  • This isn't the only kind of day and night plant movement, either: many species actively follow the sun during the day, in a process called heliotropism.

  • Unlike nastic movements, tropisms are plant movements that are oriented in a specific direction.

  • Heliotropism can help leaves get the most possible sunlight.

  • Often, heliotropism in leaves is also controlled by turgor pressure in pulvini, if you wanted a lot of new terminology all in one sentence.

  • Though in this case the leaves can move continuously to track the sun throughout the day, rather than just opening and closing.

  • And some flowers follow the sun too.

  • It seems to have a few benefits, like providing a nice warm place for pollinators and helping the plants' seeds develop.

  • But many heliotropic flowers have no pulvini.

  • Young sunflowers instead turn to face the sun by growing their stem on one side at a time.

  • It's not totally clear what chemicals the sunflowers use to sense sunlight.

  • But the changes in stem growth appear to be governed by a hormone called auxin, which in this case tells certain parts of the plant to grow in response to light.

  • The stem of the sunflower grows faster on the side that gets less sunlight, thanks to a higher level of auxin activity on the shady side.

  • That tilts the developing flower head toward the sun.

  • At night, in the absence of sunlight, sunflower stems reorient themselves to face east again, and in the morning, the light-directed growth process resumes.

  • But sunflower stalks don't keep growing forever.

  • Solar tracking only happens in young sunflowers.

  • Once they're fully mature, the flowers face east, and never move again.

  • So now you know how to tell what direction things are if you're in the middle of a sunflower field.

  • And you also know that plants don't need brains or nervous systems or muscles to respond to their environments, as long as they've got chemistry on their side.

  • And they're more sophisticated about it than we think, able to keep track of time and act appropriately.

  • Which ispretty smart.

  • Thanks for watching this episode of SciShow, which was supported by our community of patrons.

  • If you like what we do here, and you're interested in being a part of it, check out patreon.com/scishow.

  • [OUTRO ♪]

[INTRO ♪]

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