时间:2019-02-16 作者:英语课 分类:英语语言学习


英语课
Now, extinction 1 is a different kind of death. It's bigger. We didn't really realize that until 1914, when the last passenger pigeon, a female named Martha, died at the Cincinnati zoo. This had been the most abundant bird in the world that'd been in North America for six million years. Suddenly it wasn't here at all. Flocks that were a mile wide and 400 miles long used to darken the sun. Aldo Leopold said this was a biological storm, a feathered tempest. And indeed it was a keystone species that enriched the entire eastern deciduous 2 forest, from the Mississippi to the Atlantic, from Canada down to the Gulf 3. But it went from five billion birds to zero in just a couple decades. What happened?
 
Well, commercial hunting happened. These birds were hunted for meat that was sold by the ton, and it was easy to do because when those big flocks came down to the ground, they were so dense 4 that hundreds of hunters and netters could show up and slaughter 5 them by the tens of thousands. It was the cheapest source of protein in America. By the end of the century, there was nothing left but these beautiful skins in museum specimen 6 drawers.
 
There's an upside to the story. This made people realize that the same thing was about to happen to the American bison, and so these birds saved the buffalos.
 
But a lot of other animals weren't saved. The Carolina parakeet was a parrot that lit up backyards everywhere. It was hunted to death for its feathers. There was a bird that people liked on the East Coast called the heath hen. It was loved. They tried to protect it. It died anyway. A local newspaper spelled out, "There is no survivor 7, there is no future, there is no life to be recreated in this form ever again." There's a sense of deep tragedy that goes with these things, and it happened to lots of birds that people loved. It happened to lots of mammals. Another keystone species is a famous animal called the European aurochs. There was sort of a movie made about it recently. And the aurochs was like the bison. This was an animal that basically kept the forest mixed with grasslands 8 across the entire Europe and Asian continent, from Spain to Korea. The documentation of this animal goes back to the Lascaux cave paintings.
 
The extinctions still go on. There's an ibex in Spain called the bucardo. It went extinct in 2000. There was a marvelous animal, a marsupial 9 wolf called the thylacine in Tasmania, south of Australia, called the Tasmanian tiger. It was hunted until there were just a few left to die in zoos. A little bit of film was shot.
 
Sorrow, anger, mourning. Don't mourn. Organize. What if you could find out that, using the DNA 10 in museum specimens 11, fossils maybe up to 200,000 years old could be used to bring species back, what would you do? Where would you start?
 
Well, you'd start by finding out if the biotech is really there. I started with my wife, Ryan Phelan, who ran a biotech business called DNA Direct, and through her, one of her colleagues, George Church, one of the leading genetic 13 engineers who turned out to be also obsessed 14 with passenger pigeons and a lot of confidence that methodologies he was working on might actually do the deed.
 
So he and Ryan organized and hosted a meeting at the Wyss Institute in Harvard bringing together specialists on passenger pigeons, conservation ornithologists, bioethicists, and fortunately passenger pigeon DNA had already been sequenced by a molecular 15 biologist named Beth Shapiro. All she needed from those specimens at the Smithsonian was a little bit of toe pad tissue, because down in there is what is called ancient DNA. It's DNA which is pretty badly fragmented, but with good techniques now, you can basically reassemble the whole genome.
 
Then the question is, can you reassemble, with that genome, the whole bird? George Church thinks you can. So in his book, "Regenesis," which I recommend, he has a chapter on the science of bringing back extinct species, and he has a machine called the Multiplex Automated 17 Genome Engineering machine. It's kind of like an evolution machine. You try combinations of genes 16 that you write at the cell level and then in organs on a chip, and the ones that win, that you can then put into a living organism. It'll work. The precision of this, one of George's famous unreadable slides, nevertheless points out that there's a level of precision here right down to the individual base pair. The passenger pigeon has 1.3 billion base pairs in its genome.
 
So what you're getting is the capability 18 now of replacing one gene 12 with another variation of that gene. It's called an allele. Well that's what happens in normal hybridization anyway. So this is a form of synthetic 19 hybridization of the genome of an extinct species with the genome of its closest living relative. Now along the way, George points out that his technology, the technology of synthetic biology, is currently accelerating at four times the rate of Moore's Law. It's been doing that since 2005, and it's likely to continue.
 
Okay, the closest living relative of the passenger pigeon is the band-tailed pigeon. They're abundant. There's some around here. Genetically 20, the band-tailed pigeon already is mostly living passenger pigeon. There's just some bits that are band-tailed pigeon. If you replace those bits with passenger pigeon bits, you've got the extinct bird back, cooing at you.
 
Now, there's work to do. You have to figure out exactly what genes matter. So there's genes for the short tail in the band-tailed pigeon, genes for the long tail in the passenger pigeon, and so on with the red eye, peach-colored breast, flocking, and so on. Add them all up and the result won't be perfect. But it should be be perfect enough, because nature doesn't do perfect either.
 
So this meeting in Boston led to three things.
 
First off, Ryan and I decided 21 to create a nonprofit called Revive and Restore that would push de-extinction generally and try to have it go in a responsible way, and we would push ahead with the passenger pigeon.
 
Another direct result was a young grad student named Ben Novak, who had been obsessed with passenger pigeons since he was 14 and had also learned how to work with ancient DNA, himself sequenced the passenger pigeon, using money from his family and friends. We hired him full-time 22. Now, this photograph I took of him last year at the Smithsonian, he's looking down at Martha, the last passenger pigeon alive. So if he's successful, she won't be the last.
 
The third result of the Boston meeting was the realization 23 that there are scientists all over the world working on various forms of de-extinction, but they'd never met each other. And National Geographic 24 got interested because National Geographic has the theory that the last century, discovery was basically finding things, and in this century, discovery is basically making things. De-extinction falls in that category. So they hosted and funded this meeting. And 35 scientists, they were conservation biologists and molecular biologists, basically meeting to see if they had work to do together. Some of these conservation biologists are pretty radical 25. There's three of them who are not just re-creating ancient species, they're recreating extinct ecosystems 27 in northern Siberia, in the Netherlands, and in Hawaii.
 
Henri, from the Netherlands, with a Dutch last name I won't try to pronounce, is working on the aurochs. The aurochs is the ancestor of all domestic cattle, and so basically its genome is alive, it's just unevenly 28 distributed. So what they're doing is working with seven breeds of primitive 29, hardy-looking cattle like that Maremmana primitivo on the top there to rebuild, over time, with selective back-breeding, the aurochs. Now, re-wilding is moving faster in Korea than it is in America, and so the plan is, with these re-wilded areas all over Europe, they will introduce the aurochs to do its old job, its old ecological 30 role, of clearing the somewhat barren, closed-canopy forest so that it has these biodiverse meadows in it.
 
Another amazing story came from Alberto Fernández-Arias. Alberto worked with the bucardo in Spain. The last bucardo was a female named Celia who was still alive, but then they captured her, they got a little bit of tissue from her ear, they cryopreserved it in liquid nitrogen, released her back into the wild, but a few months later, she was found dead under a fallen tree. They took the DNA from that ear, they planted it as a cloned egg in a goat, the pregnancy 31 came to term, and a live baby bucardo was born. It was the first de-extinction in history.
 
(Applause)
 
It was short-lived. Sometimes interspecies clones have respiration 32 problems. This one had a malformed lung and died after 10 minutes, but Alberto was confident that cloning has moved along well since then, and this will move ahead, and eventually there will be a population of bucardos back in the mountains in northern Spain.
 
Cryopreservation pioneer of great depth is Oliver Ryder. At the San Diego zoo, his frozen zoo has collected the tissues from over 1,000 species over the last 35 years. Now, when it's frozen that deep, minus 196 degrees Celsius 33, the cells are intact and the DNA is intact. They're basically viable 34 cells, so someone like Bob Lanza at Advanced Cell Technology took some of that tissue from an endangered animal called the Javan banteng, put it in a cow, the cow went to term, and what was born was a live, healthy baby Javan banteng, who thrived and is still alive.
 
The most exciting thing for Bob Lanza is the ability now to take any kind of cell with induced pluripotent stem cells and turn it into germ cells, like sperm 35 and eggs.
 
So now we go to Mike McGrew who is a scientist at Roslin Institute in Scotland, and Mike's doing miracles with birds. So he'll take, say, falcon 36 skin cells, fibroblast, turn it into induced pluripotent stem cells. Since it's so pluripotent, it can become germ plasm. He then has a way to put the germ plasm into the embryo 37 of a chicken egg so that that chicken will have, basically, the gonads of a falcon. You get a male and a female each of those, and out of them comes falcons 38. (Laughter) Real falcons out of slightly doctored chickens.
 
Ben Novak was the youngest scientist at the meeting. He showed how all of this can be put together. The sequence of events: he'll put together the genomes of the band-tailed pigeon and the passenger pigeon, he'll take the techniques of George Church and get passenger pigeon DNA, the techniques of Robert Lanza and Michael McGrew, get that DNA into chicken gonads, and out of the chicken gonads get passenger pigeon eggs, squabs, and now you're getting a population of passenger pigeons.
 
It does raise the question of, they're not going to have passenger pigeon parents to teach them how to be a passenger pigeon. So what do you do about that? Well birds are pretty hard-wired, as it happens, so most of that is already in their DNA, but to supplement it, part of Ben's idea is to use homing pigeons to help train the young passenger pigeons how to flock and how to find their way to their old nesting grounds and feeding grounds.
 
There were some conservationists, really famous conservationists like Stanley Temple, who is one of the founders 39 of conservation biology, and Kate Jones from the IUCN, which does the Red List. They're excited about all this, but they're also concerned that it might be competitive with the extremely important efforts to protect endangered species that are still alive, that haven't gone extinct yet. You see, you want to work on protecting the animals out there. You want to work on getting the market for ivory in Asia down so you're not using 25,000 elephants a year.
 
But at the same time, conservation biologists are realizing that bad news bums 40 people out. And so the Red List is really important, keep track of what's endangered and critically endangered, and so on. But they're about to create what they call a Green List, and the Green List will have species that are doing fine, thank you, species that were endangered, like the bald eagle, but they're much better off now, thanks to everybody's good work, and protected areas around the world that are very, very well managed. So basically, they're learning how to build on good news. And they see reviving extinct species as the kind of good news you might be able to build on.
 
Here's a couple related examples. Captive breeding will be a major part of bringing back these species. The California condor 41 was down to 22 birds in 1987. Everybody thought is was finished. Thanks to captive breeding at the San Diego Zoo, there's 405 of them now, 226 are out in the wild. That technology will be used on de-extincted animals. Another success story is the mountain gorilla 42 in Central Africa. In 1981, Dian Fossey was sure they were going extinct. There were just 254 left. Now there are 880. They're increasing in population by three percent a year. The secret is, they have an eco-tourism program, which is absolutely brilliant. So this photograph was taken last month by Ryan with an iPhone. That's how comfortable these wild gorillas 43 are with visitors.
 
Another interesting project, though it's going to need some help, is the northern white rhinoceros 44. There's no breeding pairs left. But this is the kind of thing that a wide variety of DNA for this animal is available in the frozen zoo. A bit of cloning, you can get them back.
 
So where do we go from here? These have been private meetings so far. I think it's time for the subject to go public. What do people think about it? You know, do you want extinct species back? Do you want extinct species back?
 
(Applause)
 
Tinker Bell is going to come fluttering down. It is a Tinker Bell moment, because what are people excited about with this? What are they concerned about?
 
We're also going to push ahead with the passenger pigeon. So Ben Novak, even as we speak, is joining the group that Beth Shapiro has at UC Santa Cruz. They're going to work on the genomes of the passenger pigeon and the band-tailed pigeon. As that data matures, they'll send it to George Church, who will work his magic, get passenger pigeon DNA out of that. We'll get help from Bob Lanza and Mike McGrew to get that into germ plasm that can go into chickens that can produce passenger pigeon squabs that can be raised by band-tailed pigeon parents, and then from then on, it's passenger pigeons all the way, maybe for the next six million years. You can do the same thing, as the costs come down, for the Carolina parakeet, for the great auk, for the heath hen, for the ivory-billed woodpecker, for the Eskimo curlew, for the Caribbean monk 45 seal, for the woolly mammoth 46.
 
Because the fact is, humans have made a huge hole in nature in the last 10,000 years. We have the ability now, and maybe the moral obligation, to repair some of the damage. Most of that we'll do by expanding and protecting wildlands, by expanding and protecting the populations of endangered species. But some species that we killed off totally we could consider bringing back to a world that misses them.
 
Thank you.
 
(Applause)
 
Chris Anderson: Thank you. I've got a question. So, this is an emotional topic. Some people stand. I suspect there are some people out there sitting, kind of asking tormented 47 questions, almost, about, well, wait, wait, wait, wait, wait, wait a minute, there's something wrong with mankind interfering 48 in nature in this way. There's going to be unintended consequences. You're going to uncork some sort of Pandora's box of who-knows-what. Do they have a point?
 
Stewart Brand: Well, the earlier point is we interfered 49 in a big way by making these animals go extinct, and many of them were keystone species, and we changed the whole ecosystem 26 they were in by letting them go. Now, there's the shifting baseline problem, which is, so when these things come back, they might replace some birds that are there that people really know and love. I think that's, you know, part of how it'll work. This is a long, slow process -- One of the things I like about it, it's multi-generation. We will get woolly mammoths back.
 
CA: Well it feels like both the conversation and the potential here are pretty thrilling. Thank you so much for presenting. SB: Thank you.
 
CA: Thank you. (Applause)

n.熄灭,消亡,消灭,灭绝,绝种
  • The plant is now in danger of extinction.这种植物现在有绝种的危险。
  • The island's way of life is doomed to extinction.这个岛上的生活方式注定要消失。
adj.非永久的;短暂的;脱落的;落叶的
  • Overgrown deciduous shrubs can be cut back at this time of year.过于繁茂的落叶灌木可以在每年的这个时候修剪。
  • Deciduous trees shed their leaves in autumn.落叶树木在秋天落叶。
n.海湾;深渊,鸿沟;分歧,隔阂
  • The gulf between the two leaders cannot be bridged.两位领导人之间的鸿沟难以跨越。
  • There is a gulf between the two cities.这两座城市间有个海湾。
a.密集的,稠密的,浓密的;密度大的
  • The general ambushed his troops in the dense woods. 将军把部队埋伏在浓密的树林里。
  • The path was completely covered by the dense foliage. 小路被树叶厚厚地盖了一层。
n.屠杀,屠宰;vt.屠杀,宰杀
  • I couldn't stand to watch them slaughter the cattle.我不忍看他们宰牛。
  • Wholesale slaughter was carried out in the name of progress.大规模的屠杀在维护进步的名义下进行。
n.样本,标本
  • You'll need tweezers to hold up the specimen.你要用镊子来夹这标本。
  • This specimen is richly variegated in colour.这件标本上有很多颜色。
n.生存者,残存者,幸存者
  • The sole survivor of the crash was an infant.这次撞车的惟一幸存者是一个婴儿。
  • There was only one survivor of the plane crash.这次飞机失事中只有一名幸存者。
n.草原,牧场( grassland的名词复数 )
  • Songs were heard ringing loud and clear over the grasslands. 草原上扬起清亮激越的歌声。 来自《现代汉英综合大词典》
  • Grasslands have been broken and planted to wheat. 草原已经开垦出来,种上了小麦。 来自《简明英汉词典》
adj.有袋的,袋状的
  • Koala is an arboreal Australian marsupial.考拉是一种澳大利亚树栖有袋动物。
  • The marsupial has been in decline for decades due to urban sprawl from car accidentsdog attacks.这种有袋动物其数量在过去几十年间逐渐减少,主要原因是城市的扩张、车祸和狗的袭击。
(缩)deoxyribonucleic acid 脱氧核糖核酸
  • DNA is stored in the nucleus of a cell.脱氧核糖核酸储存于细胞的细胞核里。
  • Gene mutations are alterations in the DNA code.基因突变是指DNA密码的改变。
n.样品( specimen的名词复数 );范例;(化验的)抽样;某种类型的人
  • Astronauts have brought back specimens of rock from the moon. 宇航员从月球带回了岩石标本。
  • The traveler brought back some specimens of the rocks from the mountains. 那位旅行者从山上带回了一些岩石标本。 来自《简明英汉词典》
n.遗传因子,基因
  • A single gene may have many effects.单一基因可能具有很多种效应。
  • The targeting of gene therapy has been paid close attention.其中基因治疗的靶向性是值得密切关注的问题之一。
adj.遗传的,遗传学的
  • It's very difficult to treat genetic diseases.遗传性疾病治疗起来很困难。
  • Each daughter cell can receive a full complement of the genetic information.每个子细胞可以收到遗传信息的一个完全补偿物。
adj.心神不宁的,鬼迷心窍的,沉迷的
  • He's obsessed by computers. 他迷上了电脑。
  • The fear of death obsessed him throughout his old life. 他晚年一直受着死亡恐惧的困扰。
adj.分子的;克分子的
  • The research will provide direct insight into molecular mechanisms.这项研究将使人能够直接地了解分子的机理。
  • For the pressure to become zero, molecular bombardment must cease.当压强趋近于零时,分子的碰撞就停止了。
n.基因( gene的名词复数 )
  • You have good genes from your parents, so you should live a long time. 你从父母那儿获得优良的基因,所以能够活得很长。 来自《简明英汉词典》
  • Differences will help to reveal the functions of the genes. 它们间的差异将会帮助我们揭开基因多种功能。 来自英汉非文学 - 生命科学 - 生物技术的世纪
a.自动化的
  • The entire manufacturing process has been automated. 整个生产过程已自动化。
  • Automated Highway System (AHS) is recently regarded as one subsystem of Intelligent Transport System (ITS). 近年来自动公路系统(Automated Highway System,AHS),作为智能运输系统的子系统之一越来越受到重视。
n.能力;才能;(pl)可发展的能力或特性等
  • She has the capability to become a very fine actress.她有潜力成为杰出演员。
  • Organizing a whole department is beyond his capability.组织整个部门是他能力以外的事。
adj.合成的,人工的;综合的;n.人工制品
  • We felt the salesman's synthetic friendliness.我们感觉到那位销售员的虚情假意。
  • It's a synthetic diamond.这是人造钻石。
adv.遗传上
  • All the bees in the colony are genetically related. 同一群体的蜜蜂都有亲缘关系。
  • Genetically modified foods have already arrived on American dinner tables. 经基因改造加工过的食物已端上了美国人的餐桌。 来自英汉非文学 - 生命科学 - 基因与食物
adj.决定了的,坚决的;明显的,明确的
  • This gave them a decided advantage over their opponents.这使他们比对手具有明显的优势。
  • There is a decided difference between British and Chinese way of greeting.英国人和中国人打招呼的方式有很明显的区别。
adj.满工作日的或工作周的,全时间的
  • A full-time job may be too much for her.全天工作她恐怕吃不消。
  • I don't know how she copes with looking after her family and doing a full-time job.既要照顾家庭又要全天工作,我不知道她是如何对付的。
n.实现;认识到,深刻了解
  • We shall gladly lend every effort in our power toward its realization.我们将乐意为它的实现而竭尽全力。
  • He came to the realization that he would never make a good teacher.他逐渐认识到自己永远不会成为好老师。
adj.地理学的,地理的
  • The city's success owes much to its geographic position. 这座城市的成功很大程度上归功于它的地理位置。 来自《简明英汉词典》
  • Environmental problems pay no heed to these geographic lines. 环境问题并不理会这些地理界限。 来自英汉非文学 - 环境法 - 环境法
n.激进份子,原子团,根号;adj.根本的,激进的,彻底的
  • The patient got a radical cure in the hospital.病人在医院得到了根治。
  • She is radical in her demands.她的要求十分偏激。
n.生态系统
  • This destroyed the ecosystem of the island.这样破坏了岛上的生态系统。
  • We all have an interest in maintaining the integrity of the ecosystem.维持生态系统的完整是我们共同的利益。
n.生态系统( ecosystem的名词复数 )
  • There are highly sensitive and delicately balanced ecosystems in the forest. 森林里有高度敏感、灵敏平衡的各种生态系统。 来自《简明英汉词典》
  • Madagascar's ecosystems range from rainforest to semi-desert. 马达加斯加生态系统类型多样,从雨林到半荒漠等不一而足。 来自辞典例句
adv.不均匀的
  • Fuel resources are very unevenly distributed. 燃料资源分布很不均匀。
  • The cloth is dyed unevenly. 布染花了。
adj.原始的;简单的;n.原(始)人,原始事物
  • It is a primitive instinct to flee a place of danger.逃离危险的地方是一种原始本能。
  • His book describes the march of the civilization of a primitive society.他的著作描述了一个原始社会的开化过程。
adj.生态的,生态学的
  • The region has been declared an ecological disaster zone.这个地区已经宣布为生态灾难区。
  • Each animal has its ecological niche.每种动物都有自己的生态位.
n.怀孕,怀孕期
  • Early pregnancy is often accompanied by nausea.怀孕早期常有恶心的现象。
  • Smoking during pregnancy increases the risk of miscarriage.怀孕期吸烟会增加流产的危险。
n.呼吸作用;一次呼吸;植物光合作用
  • They tried artificial respiration but it was of no avail.他们试做人工呼吸,可是无效。
  • They made frequent checks on his respiration,pulse and blood.他们经常检查他的呼吸、脉搏和血液。
adj.摄氏温度计的,摄氏的
  • The temperature tonight will fall to seven degrees Celsius.今晚气温将下降到七摄氏度。
  • The maximum temperature in July may be 36 degrees Celsius.七月份最高温度可能达到36摄氏度。
adj.可行的,切实可行的,能活下去的
  • The scheme is economically viable.这个计划从经济效益来看是可行的。
  • The economy of the country is not viable.这个国家经济是难以维持的。
n.精子,精液
  • Only one sperm fertilises an egg.只有一个精子使卵子受精。
  • In human reproduction,one female egg is usually fertilized by one sperm.在人体生殖过程中,一个精子使一个卵子受精。
n.隼,猎鹰
  • The falcon was twice his size with pouted feathers.鹰张开羽毛比两只鹰还大。
  • The boys went hunting with their falcon.男孩子们带着猎鹰出去打猎了。
n.胚胎,萌芽的事物
  • They are engaging in an embryo research.他们正在进行一项胚胎研究。
  • The project was barely in embryo.该计划只是个雏形。
n.猎鹰( falcon的名词复数 )
  • Peregrine falcons usually pluck the feathers and strip the flesh off their bird prey. 游隼捕到鸟类猎物时,通常是先拔掉它们的羽毛,再把肉撕下来。 来自《简明英汉词典》
  • Though he doubted the wisdom of using falcons, Dr. de la Fuente undertook the project. 虽然德·拉·富恩特博士怀疑使用游隼是否明智,但他还是执行了这项计划。 来自辞典例句
n.创始人( founder的名词复数 )
  • He was one of the founders of the university's medical faculty. 他是该大学医学院的创建人之一。 来自辞典例句
  • The founders of our religion made this a cornerstone of morality. 我们宗教的创始人把这看作是道德的基石。 来自辞典例句
n.秃鹰;秃鹰金币
  • The condor soars above the mountain heights.禿鹰翱翔于高山之上。
  • A condor prepares to fly in Colombia.一只兀鹰在哥伦比亚准备振翅高飞。
n.大猩猩,暴徒,打手
  • I was awed by the huge gorilla.那只大猩猩使我惊惧。
  • A gorilla is just a speechless animal.猩猩只不过是一种不会说话的动物。
n.大猩猩( gorilla的名词复数 );暴徒,打手
  • the similitude between humans and gorillas 人类和大猩猩的相像
  • Each family of gorillas is led by a great silverbacked patriarch. 每个大星星家族都由一个魁梧的、长着银色被毛的族长带领着。 来自《简明英汉词典》
n.犀牛
  • The rhinoceros has one horn on its nose.犀牛鼻子上有一个角。
  • The body of the rhinoceros likes a cattle and the head likes a triangle.犀牛的形体像牛,头呈三角形。
n.和尚,僧侣,修道士
  • The man was a monk from Emei Mountain.那人是峨眉山下来的和尚。
  • Buddhist monk sat with folded palms.和尚合掌打坐。
n.长毛象;adj.长毛象似的,巨大的
  • You can only undertake mammoth changes if the finances are there.资金到位的情况下方可进行重大变革。
  • Building the new railroad will be a mammoth job.修建那条新铁路将是一项巨大工程。
饱受折磨的
  • The knowledge of his guilt tormented him. 知道了自己的罪责使他非常痛苦。
  • He had lain awake all night, tormented by jealousy. 他彻夜未眠,深受嫉妒的折磨。
v.干预( interfere的过去式和过去分词 );调停;妨碍;干涉
  • Complete absorption in sports interfered with his studies. 专注于运动妨碍了他的学业。 来自《简明英汉词典》
  • I am not going to be interfered with. 我不想别人干扰我的事情。 来自《简明英汉词典》
学英语单词
2-methylcortisol
aceraius grandis
Aconitum refracticarpum
allantois chorioidea
aquachloral
arsecheek
avant-gardists
back-channeled
be better of
bean tree
Biankouma
body-thrusts
buarques
bwe
C-Prolog
cable distribution point
Chattertonian
claisen para-rearrangement
coati-mundi
colour screw
Crookes' lens
cumulative error
cylinder cover bolt
date of clearance
dibutyryl
Diphyllobothrium erinacei
diplosomites
dome cap
drip gasoline
drywell ambient temperature
error locating
Euro share market
exhibition space
famale worker
fineberg
flunk
foam in hibitors
foreign exchange option
furnace transformer
gross out
half-bottles
heavy lorry
heterodyne repeater
household word
immanacled
income tax authority
intermodal freight terminal
johann maier ecks
josher
khanaqin
Kundsen-langmuir equation
Kutta-Joukowski airfoil
line broadening
linearly equivalence
lorente
lump salt
mating plug
melomelus
Middeldorpf's triangle
near-optimality
neurogenin
non-parametric cointegration
non-provisional
normal atmosphere
nucleus of the solitary tract
nurserygirl
Odawara
orbitosphenoids
Oto-Manguean
owner-like
phase contour
pig pile
plocamium telfairiae
Plutonian
positive vector
pressure-feed oiling
pullulatings
rabbet line
residual noise
reverse intergenerational influence
rodder
sael
sales record
sayan
scrambly
Silicon Wadi
single-action pressing
spongy brake pedal
structural basis
submolecule
sunk-in
Talodex
test harnesses
thunder thighs
torcious
transition state,transition complex
trimmed in bunker
unaccused
unbenzoled petrol
white mahogany
whitenest
zoocoenology