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  • Hi. I'm John Green and welcome to Crash Course Big History where today we are going to get

  • a life. Or at least the Earth is going to get a life.

  • But first, today we have to start with a disclaimer. The origin of life is in many ways a "blank

  • spot" in the pages of history. Like, the mystery surrounding the big bang or dark matter - the

  • origin of life is still pretty puzzling to us. Like, thanks to scientific research, we

  • have a general idea of what needed to happen to bring about life, but we're pretty fuzzy

  • on the details.

  • Mr Green, Mr Green! I mean, if we don't know, then why are we studying it as history? Maybe

  • we should just like, let scientists figure all that stuff out and then they'll get back

  • to us, like, after this class is over?

  • Well, Me From the Past, I'm sure the thousands of scientists working on that question appreciate

  • your patience, but even when we have blank pages in the annals of history, it's still

  • history! Like, there's still competing ideas and theories about the presidency of Franklin

  • Delano Roosevelt, but the fact that there are open questions doesn't mean it didn't happen!

  • Sometimes we don't have a clear narrative of events, and it's up to us to collect more

  • evidence and refine those theories. But first, we have to know about the current evidence

  • and the current theories. I mean, ultimately, that's what history is!

  • I'm Hank Green, and this is still Crash Course Big History. Last time we left off with a

  • newly-born Earth that was molten hot and pelted by asteroids. Then millions of years of torrential

  • rainfall cooled the surface and created the first oceans.

  • We know that life emerged in the oceans between 3.5 and 4 billion years ago. We have solid

  • fossil evidence for life 3.5 billion years ago and many scientists are pretty confident

  • that life was around 3.8 billion years ago.

  • It's pretty clear that life is a different thing from the rest of the universe, but what

  • makes up that difference? I'm kind of surprised that this turns out to be a super puzzling

  • question that we have yet to come up with a 100% satisfying answer to. But some of the

  • major characteristics of most life are: it adapts to the environment, it has a metabolism

  • that processes energy to keep itself going (like humans do with pizza), and it reproduces

  • - whether it be a cell splitting in two or two animals... doing their thing in nature.

  • Even these simple criteria have their problems though. Some animals like mules are born unable

  • to have offspring. Some micro-organisms can shut down their metabolisms for long stretches

  • of time, but neither are exactly dead or not life.

  • Given the incredible variety of species, definitions for life are, by necessity, very broad. But

  • one such definition by big historian Fred Spire, is, and I quote "a regime that contains

  • a hereditary program for defining and directing molecular mechanisms that actively extract

  • matter and energy from the environment, with the aid of which, matter and energy are converted

  • into building blocks for its own maintenance, and if possible, reproduction."

  • In other words, what makes you different from a star is that while a star burns down till

  • it dies and doesn't actively float around the cosmos looking for more fuel, a living

  • organism does actively seek out pizza to keep itself going, preferably long enough to, you

  • know, have some babies.

  • But how do we know what we know? How do we know that life is just a different kind of

  • molecular mechanism, not something more profound? Well, we can test these claims. And we do!

  • Using science.

  • Because life looks so radically different from the inanimate universe, people once thought

  • that life was made of completely different stuff. Then, in 1828, a German chemist, Friedrich

  • hler, used inorganic chemicals to synthesize an organic chemical. This was a big deal - just

  • as Newton's theory of gravity showed that the heavens and Earth followed the same physical

  • laws, Wöhler's experiment proved that life and non-life follow the same chemical laws,

  • which implied that life could emerge from non-life.

  • Even this idea wasn't completely new. For centuries, the Aristotelian idea that life

  • just spontaneously emerged from non-life was widely believed. For example, if you put some

  • rotten meat out in the sun, eventually the meat would transform itself into maggots.

  • You can probably work out the weaknesses in this theory. Seventeenth century scientists

  • took meat and various other objects thought to spontaneously generate life, boiled them

  • to kill off any eggs previously laid by insects, sealed them in jars and nothing happened.

  • Oh, Aristotle, first you told us that snot was our brain coming out of our noses, and

  • now you made all those nice people waste their steak dinner!

  • This, however, did not rule out some form of life-force in the air. Some invisible force

  • from the Earth's atmosphere that could enter an object and literally breathe life into

  • it. But spores from plants can also travel in the air, as can microorganisms. So in the

  • mid-nineteenth century, Louis Pasteur boiled some organic broth, friendly to life and placed

  • it in a flask with a swan neck, to trap plant spores in smaller particles. If a life-force

  • was in the air, it could enter freely, while spores and other particles would get trapped

  • in the U-bend. And what happened? Nothing! A century and a half later, those flasks are

  • still devoid of life. The conclusion? The ancients were wrong. After a dose of claim-testing,

  • it became clear that life must emerge from the inanimate world by chemical processes

  • that are discoverable by science.

  • But what did early life look like? Well, for a whopping 2.1 billion of the 3.8 billion

  • years of the evolutionary epic, history was made by tiny single-cell organisms called

  • prokaryotes. That's roughly 55% of the entire story of life. Now, some of those prokaryotes

  • evolved about 1.7 billion years ago into slightly bigger single-celled organisms called eukaryotes,

  • and then, you know, that kept happening and then eventually - us!

  • But for now, let's just talk about prokaryotes. Prokaryotes lived in the seas and ate chemicals

  • in their surrounding environment. Now these microscopic prokaryotes might not sound very

  • impressive, but they do make up the vast majority of your family tree. They're also distant

  • relatives of the modern bacteria that are everywhere, crawling around the room that

  • you're in right now, crawling all over you, crawling inside of your intestines... That's

  • right! Somewhere right now, there is a bacterium that will give you food poisoning, in an under-cooked

  • hamburger, and it is your cousin!

  • But the thing is, even in its earliest stages, single-cell life was massively complex compared

  • to the inanimate universe. I mean, I know these are tiny, little specks, but compared

  • to everything else that had happened on Earth until them, they were an immense tangle of

  • chemical networks and building blocks.

  • But how did an object as ridiculously complex as a prokaryote first emerge? Well, first

  • of all, it's very difficult to think of how life would form in an oxygen-rich atmosphere

  • like present-day Earth. Oxygen is kind of a nasty, highly-reactive chemical. In fact,

  • if the oxygen levels in this room were substantially higher and I was to just rub my hands together

  • really fast, I could burst into flames! And while that would make for a nice viral YouTube

  • video, I would rather not be on fire than get lots of views!

  • 3.8 billion years ago, the free oxygen content of the atmosphere was at negligible levels,

  • which had some not-so-pleasant consequences. For millions upon millions upon millions of

  • years, life dwelled fairly deeply in the ocean, eating chemicals and staying where the Earth's

  • heat kept it warm. Eventually, some prokaryotes floated near to the top of the ocean and started

  • using sunlight, water, and the carbon dioxide that was abundant in the Earth's atmosphere

  • to sustain their own complexity using this sweet chemical process they'd come up with

  • called photosynthesis. The waste product of this chemical process is oxygen, and these

  • photosynthesizing prokaryotes pumped a lot of it into the atmosphere.

  • By around 2.5 billion years ago the amount of free oxygen in the atmosphere was up to

  • about 3%. Oxygen can be nasty, and so scores and scores of tiny single-celled organisms

  • couldn't handle it, and died off in a massive wave, sometimes known as The Oxygen Holocaust.

  • So many species of single-celled organisms, each with the potential to evolve into more

  • complex life were wiped out. Even at this early stage, our evolutionary ancestors were

  • squeezed through a bottleneck. And this would not be the last such disaster that nearly

  • wiped everything out. Next time you have a bad day, remember that it is amazing that

  • you are alive at all, much less a member of a self-aware species, living at the height

  • of human technological progress.

  • Speaking of ancestors, somewhere between 1.6 and 2 billion years ago, the eukaryotes evolved.

  • And because you, your dog, the chicken you ate last week, and the mushroom you ate the

  • week before all descended from them, they really put the "you" in "eukaryotes."

  • And eukaryotes contained organelles, like cellular organs that enhanced their abilities.

  • About 1.5 billion years ago, eukaryotes invented sex. Up until that point, single-celled organisms

  • split in two or cloned, with no need to find a partner for romance and DNA exchange. Sexually

  • reproducing eukaryotes possibly obtained these abilities through cannibalism - just eating

  • each other, which may have led to some accidental exchange of DNA. After that, the evolutionary

  • advantages of sex probably resulted in it catching on. Having a partner means having

  • two sets of genes and thus a wider range of genetic diversity from which evolution can

  • pick and choose.

  • Sex, is a huge deal. It enhanced evolution and therefore deserves to be classed as one

  • of the most revolutionary advances in the history of life on Earth. And, a huge leap

  • forward in the rise of complexities since the very beginning of the Universe.

  • So where did these complex single-celled organisms come from in the first place? Well, Charles

  • Darwin's own hypothesis was that life evolved in some, quote, "warm, little pond, suitable

  • for fostering life". Other scientists postulate that life may have formed from organic chemicals

  • next to the warmth of underwater volcanoes. And still others champion the idea of panspermia

  • which states that life may have evolved elsewhere in the solar system and then been transported

  • here by an asteroid, which seeded the Earth.

  • Like I said, this is a 'blank spot', where many different historical theories are seeking

  • evidence to clarify what happened. It is possible, actually, that this problem could be solved

  • in our lifetimes, which is pretty exciting.

  • Anyway, whatever physical forces were at play, primitive organic chemicals eventually came

  • together into balls with protective membranes. They would've reproduced and proliferated

  • much as life does today, but the earliest blobs of organic chemicals would have reproduced

  • clumsily, inaccurately, with many useful adaptations getting lost. Essentially, these molecular

  • mechanisms were badly programmed.

  • In 1950s, James Watson, Francis Crick, Mauris Wilkins, and Rosalind Franklin discovered

  • how living cells replicate, using DNA, or deoxyribonucleic acid. DNA is a double-stranded

  • molecule that contains a list of orders for how it wants a living cell to be constructed.

  • And then, a single strand, RNA, reads those program orders and sets in motion the production

  • of the proteins necessary to accomplish them. All life on Earth has DNA, which is one of

  • the reasons we know that all living things on Earth, from farmers to fish, from moles to microbes,

  • have a common ancestor. It's why you share 98.4% of your DNA with a chimpanzee, and why

  • you share nearly half of your DNA with the banana that it likes to eat. Not quite cannibalism,

  • but we do eat a lot of our distant cousins.

  • But where do DNA and RNA come from? Another mystery. How could such complex programming

  • evolve from simpler organic forms? One leading contender is the RNA World Hypothesis, which

  • postulates that there might've been an earlier version of just RNA, which was capable of

  • both coding and self-replicating, and out of which separate and more complex structures

  • evolved, DNA. DNA and RNA operate in extremely complex ways themselves, which is what you'd

  • expect with something with as many connections and varied building blocks as life.

  • By the way, we're not expecting you to come away from this video with a complete understanding

  • of how DNA works. There is a link in the description to our Crash Course Biology video on DNA,

  • though, if you want this mind-boggling concept to come down a few boggles on the boggles-scale.

  • Remember this as well: when looking at a historical narrative, it's always useful to know how

  • things work. But it is still more useful to know why they work, because they can influence

  • the future sequence of events. Like, you don't have to know exactly how to design, build,

  • assemble, and fire a fifteenth century longbow to understand the French and English conflict

  • in the Hundred Years War; all you need to know is that longbows made things pretty unpleasant

  • for a lot of French people. Like, "There's a piece of wood sticking out of me!"-unpleasant.

  • DNA replication is an amazing, flabbergasting process that allows life to copy itself and

  • sustain its own complexity. It copies a living organism with stunning precision. But even

  • this impeccable copying process can occasionally be... somewhat, peccable. Once every billion

  • copies or so, there is an error. These errors result in a slight mutation. These can have

  • no effect, they can be very good, or they can be very bad. If useful, it allows an

  • organism to be more successful and likely to pass on its genes. If not so useful, things

  • go poorly, and the gene does not get passed on. On the scale of millions of years, these

  • copying errors are the engine of evolution and the origin of new species. They allow

  • the tiny layer of fragile organic materials sitting atop of the hulking geological structures

  • of the Earth to be shaped and reshaped like play-doh from prokaryotes to eukaryotes to

  • trilobites to dinosaurs to Abraham Lincoln.

  • As Charles Darwin put it at the end of the Origin of Species, "there is a grandeur in

  • this view of life, with its several powers, having been originally breathed into a few

  • forms or into one, and that whilst this planet has gone cycling on according to the fixed

  • law of gravity, from so simple a beginning, endless forms most beautiful and most wonderful

  • have been, and are being, evolved."

  • More on that next time.

Hi. I'm John Green and welcome to Crash Course Big History where today we are going to get

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B1 中級 美國腔

生命的開始。速成班 大歷史 第四期 (Life Begins: Crash Course Big History #4)

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    稲葉白兎 發佈於 2021 年 01 月 14 日
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