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In the 18th Century,
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Swedish botonist Carolus Linnaeus
designed the flower clock,
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a timepiece made of flowering plants
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that bloom and close
at specific times of day.
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Linnaeus's plan wasn't perfect,
but the idea behind it was correct.
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Flowers can indeed sense time,
after a fashion.
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Mornings glories unfurl their petals
like clockwork in the early morning.
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A closing white water lily
signals that it's late afternoon,
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and moon flowers, as the name suggests,
only bloom under the night sky.
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But what gives plants
this innate sense of time?
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It's not just plants, in fact.
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Many organisms on Earth
have a seemingly inherent awareness
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of where they are in the day's cycle.
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That's because of circadian rhythms,
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the internal timekeepers
that tick away inside many living things.
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These biological clocks allow organisms
to keep track of time
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and pick up on environmental cues
that help them adapt.
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That's important, because the planet's
rotations and revolutions
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put us in a state of constant flux,
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although it plays out in a repetitive,
predictable way.
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Circadian rhythms incorporate various cues
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to regulate when an organism
should wake and sleep,
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and perform certain activities.
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For plants, light and temperature
are the cues which trigger reactions
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that play out at a molecular scale.
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The cells in stems, leaves, and flowers
contain phytochromes,
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tiny molecules that detect light.
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When that happens, phytochromes
initiate a chain of chemical reactions,
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passing the message down
into the cellular nuclei.
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There, transcription factors trigger
the manufacture of proteins
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required to carry out
light-dependent processes,
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like photosynthesis.
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These phytochromes not only sense
the amount of light the plant receives,
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but can also detect tiny differences
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in the distribution of wavelengths
the plant takes in.
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With this fine tuned sensing,
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phytochromes allow the plant
to discern both time,
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the difference between
the middle of the day and the evening,
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and place, whether
it is in direct sunlight or shade,
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enabling the plant to match
its chemical reactions to its environment.
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This makes for early risers.
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A few hours before sunrise,
a typical plant is already active,
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creating MRNA templates
for its photosynthesizing machinery.
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As the phytochromes
detect increasing sunlight,
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the plant readies
its light-capturing molecules
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so it can photosynthesize
and grow throughout the morning.
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After harvesting their morning light,
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plants use the rest of the day
to build long chains of energy
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in the form of glucose polymers,
like starch.
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The sun sets, and the day's work is done,
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though a plant is anything
but inactive at night.
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In the absence of sunlight,
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they metabolize and grow,
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breaking down the starch from
the previous day's energy harvest.
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Many plants have seasonal rhythms as well.
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As spring melts the winter frost,
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phytochromes sense the longer days
and increasing light,
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and a currently unknown mechanism
detects the temperature change.
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These systems pass the news
throughout the plant
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and make it produce blooming flowers
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in preparation for the pollinators
brought out by warmer weather.
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Circadian rhythms act as link
between a plant and its environment.
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These oscillations come
from the plants themselves.
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Each one has a default rhythm.
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Even so, these clocks
can adapt their oscillations
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to environmental changes and cues.
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On a plant that's in constant flux,
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it's the circadian rhythms that enable
a plant to stay true to its schedule
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and to keep its own time.
closed TED
