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  • [WELLS:] Only a small number

  • of human beings live like this today.

  • But from the time our species evolved some 200,000 years ago,

  • until the not-too-distant past,

  • all of us lived as hunter-gatherers.

  • Then, around 10,000 years ago,

  • people started domesticating animals for food,

  • living in settlements, and cultivating crops.

  • These cultural changes had profound biological impacts

  • on our species.

  • And you're about to encounter one surprising example.

  • It has to do with a familiar food.

  • I'm talking about milk,

  • the main ingredient in some

  • of our favorite things.

  • Almost all of us can digest it as babies.

  • But the story of how many adults can use it

  • as a food is a fascinating case study--

  • a study of the co-evolution of human culture and biology.

  • All infant mammals can digest milk.

  • In fact, producing milk for babies is a key trait

  • that distinguishes mammals from all other types of animals.

  • The main sugar in milk-- lactose--

  • can't easily pass through the intestinal wall.

  • So cells here make an enzyme called lactase,

  • which breaks lactose into glucose and galactose.

  • These two simpler sugars can then enter the bloodstream

  • where they can be used for energy.

  • Around the time young mammals stop drinking milk,

  • almost all of them stop making lactase,

  • so they lose their ability to digest milk.

  • They become "lactose intolerant."

  • What typically happens when an adult mammal drinks milk?

  • It's not pretty.

  • The lactose goes undigested straight

  • through the small intestine to the large intestine.

  • Here bacteria eat the sugar

  • and can cause cramps, gas, and diarrhea.

  • It's a bad idea to offer a bowl of milk to an adult cat.

  • We only know of one mammal species

  • in which some adults can drink milk without getting sick.

  • Yes, it's us.

  • Not all of us, but worldwide, about a third

  • of adults can digest lactose.

  • This minority is called "lactase persistent"

  • because their ability to produce the enzyme that breaks

  • down lactose persists beyond childhood,

  • and in fact throughout their lives.

  • How did lactase persistence come about?

  • Why does it occur only in some people?

  • I've come to University College London

  • to start my quest to find out.

  • Geneticist Dallas Swallow will show me how to figure

  • out whether someone can digest the sugar in milk.

  • [SWALLOW:] You're going to do a lactose tolerance test.

  • [WELLS:] I am.

  • [SWALLOW:] The idea is to look to see what the level

  • of glucose is in the blood

  • of the volunteer before the lactose load has been taken.

  • [WELLS:] After measuring my baseline glucose level I now

  • have to chug a liter of milk.

  • [SWALLOW:] You're allowed to breathe

  • in between, it's all right!

  • [WELLS:] If my body is still making lactase,

  • my blood glucose will shoot up.

  • After I drank the milk, here's what happened.

  • No doubt about it: My lactase enzyme is still working.

  • [SWALLOW:] Where do your family come from?

  • [WELLS:] Britain on my father's side, Denmark,

  • Holland on my mother's side.

  • But kind of northern Europe.

  • [SWALLOW:] Northern Europe, OK.

  • [SWALLOW:] You can see first of all that most people

  • in Europe are lactase persistent.

  • [WELLS:] My family background makes sense.

  • In only a few regions is a large majority

  • of people lactase persistent.

  • In other parts of the world few adults easily digest lactose.

  • What exactly is different about people

  • who are lactase persistent?

  • To get a clue, researchers looked at DNA.

  • They first compared the part of the lactase gene

  • that encodes the enzyme across persistent

  • and non-persistent people.

  • They didn't find a change in the DNA

  • that distinguished the two traits.

  • So what could explain the difference?

  • We know that genes, including lactase, are regulated--

  • turned on or off, dialed up or down--

  • by other pieces of DNA that act like switches.

  • In search of a possible mutation in a lactase switch,

  • a research team identified Finnish families

  • that had members who were lactase persistent,

  • as well as those who weren't.

  • Statistical geneticist Joe Terwilliger was part

  • of the team.

  • [TERWILLIGER:] We then looked to see if they shared DNA

  • around the region where the gene was

  • that we knew was affecting the metabolism of lactose.

  • [WELLS:] On chromosome 2, in and around the lactase gene,

  • a number of shared markers in the DNA allowed Terwilliger

  • and his colleagues to home in on a segment of DNA likely

  • to contain the lactase persistence mutation.

  • By comparing this segment base-by-base,

  • across lactase-persistent and non-persistent individuals,

  • they discovered the critical one-base difference--

  • a T instead of a C at one non-coding position.

  • The researchers had made an important discovery.

  • They'd found a mutation that causes lactase persistence

  • in Finns and other Europeans.

  • Do all lactase-persistent people carry this mutation?

  • [SWALLOW:] I thought there would be one mutation,

  • and that would be it.

  • So we went off to study samples from Africa,

  • and to our surprise, we found

  • that the mutation barely existed.

  • [WELLS:] Was a different mutation

  • at work on this continent?

  • Then a young professor,

  • geneticist Sarah Tishkoff traveled to a number

  • of African countries to find out.

  • [TISHKOFF:] We've now looked at Tanzania,

  • Kenya and the Sudan, and Ethiopia.

  • And so we've really looked at a broad range of groups and...

  • mainly in eastern Africa at this point.

  • [WELLS:] In one population, the Maasai, Tishkoff

  • and colleagues found a different lactase persistence mutation

  • from the one in Europeans.

  • The two mutations had arisen independently

  • in two different populations, in each case providing adults

  • with the ability to digest milk.

  • Tishkoff was more than pleased.

  • [TISHKOFF:] Thrilled.

  • Excited. You know, you rarely...

  • right? It's so unusual to actually find a variant

  • that appears to be correlated with such an interesting trait.

  • [WELLS:] What was special about both the Maasai

  • and the early Europeans

  • that might explain why they each independently evolved

  • this trait?

  • Both are pastoralists--

  • people who domesticated animals for food.

  • [TISHKOFF:] They adore their cows.

  • They are very possessive of their cows.

  • This is their monetary system.

  • Their wealth is determined by their cows.

  • The culture centers around the cow.

  • [WELLS:] Was the evolution

  • of lactase persistence driven by drinking milk?

  • If so, can we find evidence

  • of early milk use in these cultures?

  • In Bristol, England, organic chemist Richard Evershed is

  • examining fragments of old pots to find out.

  • [EVERSHED:] These look like they were probably cooking pots,

  • like the ancient saucepan.

  • We actually select pottery from the body or the upper parts

  • of vessels, because obviously fat floats on the surface

  • of water when you start the cooking process.

  • [WELLS:] Evershed has examined the fats trapped

  • in pots from ancient settlements across Europe and Africa

  • to determine if milk was on the Paleo menu.

  • [EVERSHED:] It is quite wondrous to think

  • that you are holding artifacts in your hands that were made

  • and then used by people just like us.

  • [WELLS:] To figure out whether these pots

  • once held milk, Evershed first had

  • to find a chemical signature of milk fats.

  • He started analyzing all kinds of fats

  • from contemporary animals.

  • [EVERSHED:] We go to farms

  • where they're using traditional farming methods, raising animals

  • on natural grazes and pastures as far as possible.

  • [WELLS:] Comparing the ratios of two carbon isotopes,

  • in two kinds of molecules in fats,

  • Evershed watched the measurements pour in.

  • [EVERSHED:] I sat at my desk with one of my students

  • and we were looking at some data; and we started to sort

  • of see patterns in the data.

  • Clustering in one part of the plot were body fats from pigs.

  • In another region were body fats from ruminants such as cows.

  • But there was more.

  • [EVERSHED:] I can remember the moment like as clear

  • as day when we sat there.

  • There were just these points disappearing off the bottom

  • of the graph.

  • They were the milk fats.

  • [WELLS:] Evershed now had a tool to look for evidence

  • of milk in the ancient pots.

  • He hoped that the tight pores

  • of the pottery material would preserve the milk fats.

  • To find out, his team grinds up potsherds...

  • and analyzes them with gas chromatography

  • and mass spectrometry-- just as they did

  • with present-day animal samples.

  • Evershed's detective work paid off.

  • Right where contemporary milk fats showed up,

  • there was now data from ancient pots.

  • They once contained milk.

  • African settlements 7,000

  • to 5,000 years ago were using dairy.

  • And potsherds from Europe

  • and the Middle East showed milk use 9,000 years ago--

  • the oldest ever discovered.

  • The dates reach back almost to the dawn of civilization.

  • Geneticists can date the origins of mutations by analyzing DNA.

  • Remarkably, the dates for when the European

  • and African lactase persistence mutations first spread

  • in populations are a good match with the archaeological evidence

  • of when people first started using milk in these regions.

  • How did dairying drive the spread

  • of the lactase persistence mutations?

  • Mutations, of course, occur at random.

  • So before humans kept dairy animals, if a mutation arose

  • that maintained lactase production,

  • it could have vanished from the population.

  • Without milk around, there's no known advantage to the mutation.

  • But if such a mutation existed when we started dairying,

  • then it could have increased in frequency in the population,

  • because lactase persistence now provided a selective advantage.

  • I spoke with Mark Thomas to find

  • out just how powerful that advantage was.

  • [THOMAS:] Mind-bendingly strong.

  • The estimates have put it at somewhere

  • around 5 or 10 percent.

  • Let's just say that it's 5 percent.

  • What that means is that for every person...

  • for every 100 people who would have survived

  • without this trait, 105 would have survived with this trait.

  • [WELLS:] And multiply that over a few generations, and--

  • [THOMAS:] And that's every generation,

  • it goes generation to generation.

  • You know how quickly generations happen.

  • [WELLS:] And why?

  • [THOMAS:] I don't know.

  • Look, I've got some ideas.

  • [WELLS:] So what are your ideas?

  • [THOMAS:] Naturally we have to start first

  • with just basic nutritional facts.

  • So, milk is very protein and fat-rich.

  • Both are good for us.

  • The protein in milk is of the highest quality.

  • It's the only food that we're aware of that was produced

  • with the intention of being consumed.

  • All other foods generally want to avoid being consumed,

  • whether consciously or otherwise.

  • [WELLS:] That's true, that's true.

  • [THOMAS:] Milk is a relatively uncontaminated fluid,

  • and so it reduces the exposure to pathogens and parasites.

  • [THOMAS:] You have these populations,

  • they're moving into northern Europe.

  • They're primarily not lactase persistent.

  • Now, imagine your crops fail.

  • Now, you become entirely dependent on your milk.

  • If you are in a famine situation,

  • so you are borderline starvation,

  • and you eat something that gives you diarrhea,

  • you're probably going to die.

  • And that's exactly the thing that's going to happen

  • to these people, because they've got nothing else to eat,

  • and they're eating more and more effectively toxic foods.

  • So I suspect that that's the real times that sorted

  • out the lactase-persistent from the lactase-non-persistent.

  • [WELLS:] While the exact selective advantage

  • of lactase persistence is still being debated,

  • it's clear that the nature of this selection was unusual.

  • It's a rare but powerful case

  • of what's called gene-culture co-evolution.

  • [THOMAS:] To understand our biological evolution absolutely

  • requires an understanding of our cultural evolution as well,

  • and that means that the human story is more a gene-culture

  • co-evolutionary story than it is for any other species on Earth.

[WELLS:] Only a small number

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B2 中高級 美國腔

乳糖耐受性的進化--HHMI生物交互式視頻播放 (The Evolution of Lactose Tolerance — HHMI BioInteractive Video)

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    Jane Wu 發佈於 2021 年 01 月 14 日
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