Daily Archives: September 14, 2016

Transhumanism Australia

Posted: September 14, 2016 at 1:11 am

[Update 2016.06.20] -Treat ageing as a disease - let's spread the word on election day!

Meow-Ludo Disco Gamma Meow-Meow Really Wants You To Care About Science -The Huffington Post

Chip Implants - The New Credit Cards?

[Update 2016.05.21]- Triple H FM radio interview with transhumanist and Science Party Candidate for Berowra, Brendan Clarke!

[Update 2016.05.18] - Matt Barrie Supports Science Party

[Update 2016.05.10]- Podcast with Questionable Content - AI For Prime Minister!

[Update 2016.05.05]- Coverage of Zoltan Istvan and the Transhumanist Partyby Vocativ!

[Update 2016.04.27]- Transhumanism Australia Update blog is up!Science Party Candidates, Design Workshops, Biohackers, Effective Altruism and More!

[Update 2016.04.09]- "CRISPR: A Genetic Cut and Paste Tool" from The Verge

[Update 2016.03.21]- Blog update is up! Future Day, Biohack+Ethereum, Basic Income and More!

[Update 2016.03.20] - The Tiny Key To Ageing

[Update 2016.03.18]- Dr Brian Greene in Sydney, Luna Park During Q&A

[Update 2016.03.12]- Real Future: Meet Zoltan Istvan, the Transhumanist Running For President (Episode 5)

Cleaned up homepage and moved old stuff to Archives

[Update 2016.3.01]- Happy Future Day! The videos from the Sydney event are up!

[Update 2016.02.26] - Transhumanism Australia on Vice AU!

[Update 2016.02.25]- Zoltan on The Feed - SBS 2!

[Update 2016.01.26] - New AI blog on Sightings from the Edge: Artificial Intelligence - January 2016. See our page dedicated to AI

[Update 2016.01.23] - How Will You Die? (Unless We Do Something About It)

Sign the petition to deem ageing as a disease.

[Update 2016.01.10]- Update to our page onAutomation. Enjoy!

[Update 2016.01.06] - Podcast with Questionable Content onSimulated Transhuman Overlords!

[Update 2016.01.02] -We've started uploading videos on our Facebook page and YouTube channel!

[Update 2015.12.31] - Zoltan's 2015 wrap up!

[Update 2015.12.30] -Join the chat group on Slack for all transhumanists around the world! If you haven't received an invite already, send an email to info@transhumanism.com.au

[Update 2015.11.29] -Check out our new page onTranshumanism in pop culture!

[Update 2015.11.09]

Join us in signing this petition to deem ageing as a disease!

[Update 2015.10.17]Transhumanist Leandro Brun joins Sunday Night Safran on Triple J radio! (Skip to 43:45)

INTRO

Welcome to the official site shared by Transhumanism Australia - the nonprofit organisation, and Transhumanist Party Australia - the Australian political organisation.

TRANSHUMANISM

Transhumanism(abbreviated as H+ or h+) is an international cultural and intellectual movement with an eventual goal of fundamentally transforming the human condition by developing and making widely available technologies to greatly enhance human intellectual, physical, and psychological capacities.

Transhumanismis a positive philosophy about the future based in optimism, rational thinking and the application of science and technology to improve the human condition. We seek to live longer, stay healthier, and become smarter and even more physically fit. We want to develop tools and technologies to help ourselves and others do the same.

Here's a well designed FAQ on What Is Transhumanism.

TRANSHUMANISM AUSTRALIA

Transhumanism in Australia is a nonprofit organisation dedicated to our communities which educate and invest in scientific research and technologies enhancing the human biological condition.

Get involved with the Transhumanist movement today!

For a timeline of Transhumanism throughout history, check out the coverage by The Verge.

TRANSHUMANIST PARTY AUSTRALIA (TPAU)

TPAU is an Australian political organisation dedicated to putting science, health, and technology at the forefront of the Australian political agenda.

TPAU aims to uphold the energy and political might of millions of transhumanist advocates around the world who desire to usescience and technology to significantly improve our lives.

The co-founders of TPAU arelisted here. Join ourFacebook groupto meet our existing TPAU admins and the transhumanist community in Australia!

Our party's core ideas and goals can be found in theTranshumanistDeclaration.The Transhumanist Party in the United States wasfoundedby futurist and philosopherZoltan Istvanon October 7, 2014 as a nonprofit organisation. Istvan manages the party and is its 2016 US Presidential candidate.

Check out thecalendarfor a list of upcoming events, and please considervolunteering for the partyormaking a donation.

Together we can vastly improve Australia through effective policy and investment in science, health and technology. Help us create a better future for all Australians.

Become a member today!

Find out more about us belowand get to know our team.

TPAU is not currently registered with the AEC. We have an alliance with theScience Partyto pool our votes and therefore contribute to shaping the policies of the Science Party. The Science Party's values are aligned with ours and you can find out about their policieshere.

Please support us by clicking on the sponsored ad below or throughout the website, or by making a donation!

GLOBAL NETWORK OF TRANSHUMANISTS

Transhumanist Party Globalis an organisation co-founded byAmon TwymanandZoltan Istvan,dedicated to supporting Transhumanist Parties around the world and encouraging effective cooperation between them.

H+Pedia is a wiki for a single source of truth on all things transhumanism, created by Chris Monteiro and David Wood

2045 Initiative

MAKING TRANSHUMANISM MAINSTREAM

Transhumanism is becoming more and more popular every day, and we hope to desensitise the term itself so that people can understand what the movement is about. Here's a video fromRhett & LinkfromGood Mythical Morningthat did a great job of this:

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Transhumanism Australia

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About – Coinbase

Posted: at 1:09 am

In brief

Founded in June of 2012, Coinbase is a digital currency wallet and platform where merchants and consumers can transact with new digital currencies like bitcoin and ethereum. We're based in San Francisco, California.

Bitcoin is the world's most widely used alternative currency with a total market cap of approximately $10 billion. The bitcoin network is made up of thousands of computers run by individuals all over the world.

Adam Draper

Greg Kidd

Garry Tan

Bitcoin & Ethereum are changing how we use and think about money. Coinbase, the most trusted company in the space, is looking for you to join our rapidly growing team.

Open positions

Bitcoin & Ethereum are changing how we use and think about money. Coinbase, the most trusted company in the space, is looking for you to join our rapidly growing team.

Open Positions

We make Bitcoin & Ethereum easy to use, strive to be the trusted brand in the space, and have built the world's leading platform for Bitcoin and Ethereum integration.

Our Values

Mailing Address

548 Market St #23008 San Francisco, CA

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About - Coinbase

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The bizarre world of bitcoin mining finds a new home in …

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Inside a metal shed in the Tibetan highlands of western China, thousands of microprocessors flank narrow corridors, generating a constant hum and stifling waves of heat.

Outside, the sky is clear and blue, with a mountain peak looming at the top of a narrow wooded valley. A flock of goats ambles idly past a pile of discarded foam packaging. Inside, though, tranquility is transformed into clamor. Red, blue and green lights constantly flash; cooling water trickles down the walls, and large ventilation fans thrum as they struggle to shift the hot air produced by all this concentrated computing power.

This is a bitcoin mine, the engine room of the worlds leading digital currency. The microprocessors here approve and record all the transactions that keep the bitcoin system running. They also compete to solve complex mathematical problems and are rewarded with bitcoins: Thats a way of putting fresh digital currency into circulation and incentivizing more people to set up mining operations.

Bitcoin began as a utopian, libertarian dream, a decentralized currency outside the control of governments, a system that gives its users the anonymity of cash and the instant, global power of email. This was a system built not just for convenience, but also for those who cant bring themselves to trust the global financial system, created by a programmer whose identity remains a mystery.

Across Tibet, China is busy pulling mineral resources out of the ground; there is even a gold mine close by. But here in Kongyu, most of the mining is virtual. It is here because of extremely cheap hydropower, cheap wages and perhaps because Chinese entrepreneurs have a knack for the business.

[Chinas scary lesson to the world: Censoring the Internet works]

For a while, bitcoin was effectively kidnapped by drug dealers, becoming the anonymous payment backbone of the Silk Road, a black market in illegal drugs that flourished on the dark Net until the FBI closed that market down in 2013.

Today it is an industry that is starting to come of age, but whose center of gravity has shifted to China, and away from utopian dreamers toward venture capitalists.

When bitcoin was invented, the people dedicated to it were mostly crypto-punks and libertarians, said Eric Mu, the chief marketing officer with HaoBTC, which operates the bitcoin mine in this township in Chinas western Sichuan province. Now they are more like bankers and lawyers who see opportunities in the industry. And as they join, the industry is changing.

In this case, changing also means moving to China.

Today, mines run by Chinese companies account for about 70percent of the worlds bitcoin processing power, its factories produce the cheapest microprocessors to run these mines, and its exchanges account for about 70percent of the worlds bitcoin trade.

It is increasingly big business. Altogether there around more than 15 million bitcoin in existence: Each is worth $615 at current prices, with a market capitalization of $9.2 billion.

For some, Chinese domination of an industry once controlled by libertarian crypto-punks is a rich irony. For others, it is a more practical threat: Chinese miners, some argued, have been standing in the way of reforms needed to speed up transaction speeds on bitcoins fast-expanding network of users.

But those concerns might be overblown.

Some people in the Western world were painting Chinese miners with too broad a brush, said Emin Gn Sirer, a computer science professor at Cornell University. Its not the case that all Chinese miners are part of the same enterprise or are colluding.

But Sirer identifies one risk with the concentration of mining power here: If the Chinese government wanted, it could in theory crack down on miners and force them to block certain bitcoin accounts.

They would not be able to usurp funds, but they could stop the motion of funds, he said, describing exactly the sort of government control bitcoin was supposed to guard against.

These are concerns that have parallels with the way China is using its digital market power to reshape the Internet and influence the global debate about censorship and surveillance.

But here, in the mountains of Sichuan, it is hard to see much evidence of a Chinese plot to bring bitcoin to heel.

The Chinese government has employed a fairly light touch. Although it banned banks from taking part in bitcoin trading in 2013, it left ordinary people free to buy and trade the crypto-currency, and miners free to operate.

[Internet activists are finding ways around Chinas Great Firewall]

The industry is run by a disparate mix of investors and dreamers and is manned by electricians and IT experts. There are people like Ryan Xu, an infectiously enthusiastic Chinese-born Australian who first became interested in libertarian economics while working as a reactor operator in a nuclear power plant. He now describes himself as both a utopian and a venture capitalist.

We need to foresee the next five or 10 years, he said in a wide-ranging conversation over dinner in the western city of Kangding. All the governments are printing money and diluting peoples wealth. Is that justice or robbery? The financial system also keeps crashing every five or 10 years. I think thats an illness in the monetary system and it needs a cure.

He says he is not sure bitcoin is the answer, but it is at least an experiment that might work.

So why China?

Running microprocessors sucks electricity. Competition is intense, and profit margins are narrow: Xu has moved his mines around the world in search of the cheapest power, from Iceland to Georgia, and then to Washington state, from the coal fields of Chinas northern Inner Mongolia province and now to the mountains of Sichuan.

His latest mine is still under construction, between a hydroelectric power plant and the concrete shell of a disused power transmission station, between Kongyu and the city of Kangding.

As Chinas economy boomed, private companies set up hydroelectric plants in western Sichuan; then, as the economy slowed, they found themselves unable to sell to the national grid, elbowed out of the market by more politically powerful state-owned firms.

It took a lot of money to build the plants, but it doesnt cost that much to maintain them, said HaoBTCs Mu. So it makes sense for them to sell the power to anyone willing to buy, even at a low rate.

Maintenance staffers are cheaper here than in the West. Mu says his company employs 10 people at three mines in the mountains, paying them around 6,000 yuan ($900) a month, a decent salary for this part of the world. HaoBTC runs one other mine in Sichuan and one farther west in Xinjiang, with more than 11,000 machines, earning more than 80 bitcoin a day a daily income stream worth more than $745,000.

[These viral selfie apps with 1 billion downloads are shaping Chinas start-up culture]

But it is not only Chinese entrepreneurs who have taken to bitcoin. Deprived of good investment opportunities at home, and burned by a volatile stock market, a growing number of Chinese people have begun speculating and investing in bitcoin.

Bobby Lee, a former Silicon Valley engineer who founded Chinas first bitcoin exchange, BTCC, attributes it partly to a natural instinct to buy and sell.

If you look at Las Vegas or Macau or casinos worldwide, how come most of the clientele are of Asian descent, or Chinese specifically? he asked. It has to do with some cultural instinct. Chinese people like to gamble.

Yet as bitcoin matures, it is also experiencing some significant growing pains.

Bitcoin is virtual money that cuts out banks and credit card companies, and has gotten more popular recently. Here's what you need to know about the original cryptocurrency. (Davin Coburn/The Washington Post)

On Aug. 2, the Bitfinex exchange in Hong Kong was forced to admit that hackers had stolen nearly 120,000 bitcoin worth $72million from customers accounts. That news caused the bitcoin price to fall by more than 20 percent and underlined the safety concerns that many ordinary people feel about owning digital money.

At the same time, the system is showing signs of overloading. Bitcoins current technology can process only around three digital transactions a second minuscule compared with the roughly 24,000 transactions per second that Visa can manage.

Delays in processing transactions have grown, as have transaction fees, and the industry has become deeply divided about how to reform the system to solve the problem.

Jeff Garzik, a leading bitcoin developer based in Atlanta, argues that a technological fix is in the pipeline that soon will allow bitcoin to process tens of thousands of transactions a second.

I think that with new technologies coming down the pipeline, it can scale up to everyone buying their coffee with bitcoin in the entire world, he said. It really can be the first really good substitute for physical in-your-hand cash.

Like Sirer, he isnt too worried about the current concentration of mining power in China, partly because the market is so dynamic and the dominant players change every year.

Its much easier to challenge the dominant players in this space because market entry is so easy, he said. If the Chinese miners suddenly power off their rigs, within 24 hours well see the emergence of another competitor.

Here in the mountains, miners while away their free time playing mah-jongg or poker, smoking cigarettes or surfing on their smartphones. Site manager Guo Hua used to run a small camera-repair shop and still likes fiddling around with machines. Marketing manager Mu, who spends only a few weeks of the year here, likes to translate books in his free time or run to the nearest town to buy cigarettes for his colleagues. Sometimes he hikes into the mountains, toward a remote Tibetan village or a looming peak, a welcome change of change of pace from Beijing and its polluted air.

And all the time, the microprocessors keep on running.

Australian entrepreneur Craig Wright has come forward as the mysterious creator behind the virtual currency Bitcoin. Here's a look at what we know about the creator's pseudonym Satoshi Nakamoto, Bitcoin's history and Wright's claims. (Jenny Starrs/The Washington Post)

Xu Yangjingjing contributed to this report.

Read more:

America wants to believe China cant innovate. Tech tells a different story.

The Internet was supposed to foster democracy. China has different ideas.

Todays coverage from Post correspondents around the world

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The bizarre world of bitcoin mining finds a new home in ...

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What is DNA? | DNA Encyclopedia

Posted: at 1:08 am

In order to truly answer the question of What is DNA? one has to go back to the elementary or high school biology classes.

DNA is the complex chemical that carries genetic information.

DNA dictates life in two manners:

There are elements called chromosomes in each cell of the human body. To be more precise, each cell contains 23 pairs of chromosomes.

Youll be astonished to know that some 50 to 100 thousand genes are held within these chromosomes. Since each of these genes could take value from one of the two values of its parent cells, hence you can imagine the possible variability in this structure.

These genes are made up of what is called DNA that is Deoxyribose Nucleic Acids. Apart from these genes that carry essential genetic information and only account for 2% of DNAs structure, the rest of the 98% of DNA is still a mystery.

Biologists call it junk DNA as there are no known proteins or traits that are coded or built by this part of DNA. This junk DNA, as well as the genetic information-carrying part only, varies in structure owing to the presence of four nucleotide bases throughout the DNA in differing order and sequence.

Think of these four nucleotide bases in DNA as letters that form an alphabet. Just like the way the order of letters determines the meaning of the word that is formed, the sequence of these nucleotide bases concludes what information is available for the production of proteins that consequently take an active part in the formation and growth of the body.

Most of the DNA is present within the nucleus of the cells. This is known as nuclear DNA. Mitochondria also hold a modest quantity of DNA, which is termed as mitochondrial DNA. The latter is useful in tests related to someones distant maternal lineage.

What is great about DNA is that it has a very autonomous self-replication mechanism in action. The replication process makes use of the two strands of DNA. Each of these strands acts as a template and after going through a series of steps is converted into dual stranded DNA once again. This replication is very important because when the cell divides, the newly formed cell requires the same set of instructions for it to function and grow and the replicated DNA serves this purpose.

Summing up the answer for what is DNA, it could easily be said that its a well-designed program spanning thousands of lines of codes that has instructions for everything that the cell needs to perform.

DNA, no matter how short the acronym sounds, is a vast topic that requires serious dedication of time and energy before one can grasp what it is and how it affects the life within and around us.

This article sets the foundations for a series of articles in which we will cover various aspects of DNA, the concepts, the technology and its applications. Right now, without going into the peculiar details, we are only going to briefly introduce these topics. You can think of it as a short glossary for DNA terminology.

Learning about DNA starts with a sound knowledge of what is it made up of and how these chemicals interact with each other to form a structure that builds a DNA molecule. You have to look carefully at what essential functions DNA performs in the cell that it is located in, by the way, its present in each cell of human as well as a body of living organisms.

In most basic terms, DNA is the master plan of life that works all the way from inception to growth. It holds all of the hereditary information and passes it from generation to generation.

Once you have encountered the double helix structure of DNA, as proposed by James Watson and Francis Crick in 1953, you should move on to advance topics like DNA replication. DNA replication tells us that each DNA is able to produce an exact copy of itself and this is made possible with the help of DNA polymerase, an enzyme that takes an active role in the process. Youll also come across DNA synthesis, which is an artificial technique to produce copies of DNA and is based on the concept of DNA replication.

While DNA holds all of the information required for the cell to perform its actions and produce the essential proteins, it is important to note that DNA doesnt interfere directly with the elements of cytoplasm outside the cell nucleus and disseminates this useful information through a messenger RNA. This is done through a process called DNA transcription.

The buzz words that have really boosted the popularity of DNA among the masses are DNA cloning and DNA testing. Who has not heard of Dolly, the first ever cloned animal? DNA testing, owing to a large number of social, commercial and forensic uses, has drawn the attention towards further studies and research in DNA.

DNA is the short term for Deoxyribonucleic Acid. Almost every cell in an individuals body has the same DNA, as the DNA is located in the cell nucleons. People, most of the times, learn what is DNA and its importance for the human body, in school.

Anyway, properly understanding what DNA is, is always important, mostly if you are working in areas in which DNA results have importance on the evolution of some cases. For starter, to understand what is DNA, you need to know that it contains all the information used in the development and functioning of all living organisms.

What is the structure of DNA, is also a common question that people seem to ask?

Human DNA consists of about 3 billion bases and more than 99 percent of them are the same, for all individuals. Another important aspect of what is DNA is that it can replicate and make copies of itself. The use of DNA linked information has become more important in science and medicine, as researchers have found that it can be used to cure diseases, or better said to avoid babies from inheriting diseases their parents are suffering from. This currently, is considered to be a major goal for scientists, who are searching for treatments, cure and also for prevention when it comes to genetic conditions. DNA becomes even more important for people who think that such risks are higher in their particular cases.

Researchers aim to detect individuals who are predisposed to develop such diseases and that means that scientists can find treatments, to be used for the purpose to prevent genetic conditions. DNA is simple to understand, but the way DNA functions is more complex.

The discovery of DNA, in fact, revolutionized both science and medicine, having numerous effects on other linked domains, such as legal and social areas. Samples of DNA are, all the times, taken from the scene of a crime, and it is a safe way to find and convict criminals, being an accepted and trusted evidence in court.

What is DNA can be easily answered when you understand that it transfers hereditary information from one generation to another, determining, at the same time, the structure of cells.

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What is DNA? | DNA Encyclopedia

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Family Tree DNA – Customer Sign In

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We encourage you to search for a family surname in our SURNAMES DATABASE. Our database contains family names of clients who have already ordered a DNA profile from Family Tree DNA.

After you have searched for the surname that interests you, the name will appear in the result screen with a number after the name, e.g. Bowling (62). This indicates that the name Bowling is in our database and that 62 people with that surname (or a derivative) have already ordered a DNA sample tested. It is possible that not all 62 Bowlings have been added yet to our Recent Ancestral Origins (RAO) Database as we may be awaiting the analysis from the Lab for some of them.

A link will be provided for you to order a genetic test below the result screen. If the surname you desire is not located in our database, you will receive a message entitled "Name not found," and a form will be provided below the message to enable you to order a test kit for that surname.

Posting and updating to our database is instant. After you have registered your surname, you can search again to find the name in the updated database. Happy relative hunting!

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Family Tree DNA - Customer Sign In

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The Structure and Function of DNA – Molecular Biology of the …

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Biologists in the 1940s had difficulty in accepting DNA as the genetic material because of the apparent simplicity of its chemistry. DNA was known to be a long polymer composed of only four types of subunits, which resemble one another chemically. Early in the 1950s, DNA was first examined by x-ray diffraction analysis, a technique for determining the three-dimensional atomic structure of a molecule (discussed in Chapter 8). The early x-ray diffraction results indicated that DNA was composed of two strands of the polymer wound into a helix. The observation that DNA was double-stranded was of crucial significance and provided one of the major clues that led to the Watson-Crick structure of DNA. Only when this model was proposed did DNA's potential for replication and information encoding become apparent. In this section we examine the structure of the DNA molecule and explain in general terms how it is able to store hereditary information.

A DNA molecule consists of two long polynucleotide chains composed of four types of nucleotide subunits. Each of these chains is known as a DNA chain, or a DNA strand. Hydrogen bonds between the base portions of the nucleotides hold the two chains together (). As we saw in Chapter 2 (Panel 2-6, pp. 120-121), nucleotides are composed of a five-carbon sugar to which are attached one or more phosphate groups and a nitrogen-containing base. In the case of the nucleotides in DNA, the sugar is deoxyribose attached to a single phosphate group (hence the name deoxyribonucleic acid), and the base may be either adenine (A), cytosine (C), guanine (G), or thymine (T). The nucleotides are covalently linked together in a chain through the sugars and phosphates, which thus form a backbone of alternating sugar-phosphate-sugar-phosphate (see ). Because only the base differs in each of the four types of subunits, each polynucleotide chain in DNA is analogous to a necklace (the backbone) strung with four types of beads (the four bases A, C, G, and T). These same symbols (A, C, G, and T) are also commonly used to denote the four different nucleotidesthat is, the bases with their attached sugar and phosphate groups.

DNA and its building blocks. DNA is made of four types of nucleotides, which are linked covalently into a polynucleotide chain (a DNA strand) with a sugar-phosphate backbone from which the bases (A, C, G, and T) extend. A DNA molecule is composed of two (more...)

The way in which the nucleotide subunits are lined together gives a DNA strand a chemical polarity. If we think of each sugar as a block with a protruding knob (the 5 phosphate) on one side and a hole (the 3 hydroxyl) on the other (see ), each completed chain, formed by interlocking knobs with holes, will have all of its subunits lined up in the same orientation. Moreover, the two ends of the chain will be easily distinguishable, as one has a hole (the 3 hydroxyl) and the other a knob (the 5 phosphate) at its terminus. This polarity in a DNA chain is indicated by referring to one end as the 3 end and the other as the 5 end.

The three-dimensional structure of DNAthe double helixarises from the chemical and structural features of its two polynucleotide chains. Because these two chains are held together by hydrogen bonding between the bases on the different strands, all the bases are on the inside of the double helix, and the sugar-phosphate backbones are on the outside (see ). In each case, a bulkier two-ring base (a purine; see Panel 2-6, pp. 120121) is paired with a single-ring base (a pyrimidine); A always pairs with T, and G with C (). This complementary base-pairing enables the base pairs to be packed in the energetically most favorable arrangement in the interior of the double helix. In this arrangement, each base pair is of similar width, thus holding the sugar-phosphate backbones an equal distance apart along the DNA molecule. To maximize the efficiency of base-pair packing, the two sugar-phosphate backbones wind around each other to form a double helix, with one complete turn every ten base pairs ().

Complementary base pairs in the DNA double helix. The shapes and chemical structure of the bases allow hydrogen bonds to form efficiently only between A and T and between G and C, where atoms that are able to form hydrogen bonds (see Panel 2-3, pp. 114115) (more...)

The DNA double helix. (A) A space-filling model of 1.5 turns of the DNA double helix. Each turn of DNA is made up of 10.4 nucleotide pairs and the center-to-center distance between adjacent nucleotide pairs is 3.4 nm. The coiling of the two strands around (more...)

The members of each base pair can fit together within the double helix only if the two strands of the helix are antiparallelthat is, only if the polarity of one strand is oriented opposite to that of the other strand (see and ). A consequence of these base-pairing requirements is that each strand of a DNA molecule contains a sequence of nucleotides that is exactly complementary to the nucleotide sequence of its partner strand.

Genes carry biological information that must be copied accurately for transmission to the next generation each time a cell divides to form two daughter cells. Two central biological questions arise from these requirements: how can the information for specifying an organism be carried in chemical form, and how is it accurately copied? The discovery of the structure of the DNA double helix was a landmark in twentieth-century biology because it immediately suggested answers to both questions, thereby resolving at the molecular level the problem of heredity. We discuss briefly the answers to these questions in this section, and we shall examine them in more detail in subsequent chapters.

DNA encodes information through the order, or sequence, of the nucleotides along each strand. Each baseA, C, T, or Gcan be considered as a letter in a four-letter alphabet that spells out biological messages in the chemical structure of the DNA. As we saw in Chapter 1, organisms differ from one another because their respective DNA molecules have different nucleotide sequences and, consequently, carry different biological messages. But how is the nucleotide alphabet used to make messages, and what do they spell out?

As discussed above, it was known well before the structure of DNA was determined that genes contain the instructions for producing proteins. The DNA messages must therefore somehow encode proteins (). This relationship immediately makes the problem easier to understand, because of the chemical character of proteins. As discussed in Chapter 3, the properties of a protein, which are responsible for its biological function, are determined by its three-dimensional structure, and its structure is determined in turn by the linear sequence of the amino acids of which it is composed. The linear sequence of nucleotides in a gene must therefore somehow spell out the linear sequence of amino acids in a protein. The exact correspondence between the four-letter nucleotide alphabet of DNA and the twenty-letter amino acid alphabet of proteinsthe genetic codeis not obvious from the DNA structure, and it took over a decade after the discovery of the double helix before it was worked out. In Chapter 6 we describe this code in detail in the course of elaborating the process, known as gene expression, through which a cell translates the nucleotide sequence of a gene into the amino acid sequence of a protein.

The relationship between genetic information carried in DNA and proteins.

The complete set of information in an organism's DNA is called its genome, and it carries the information for all the proteins the organism will ever synthesize. (The term genome is also used to describe the DNA that carries this information.) The amount of information contained in genomes is staggering: for example, a typical human cell contains 2 meters of DNA. Written out in the four-letter nucleotide alphabet, the nucleotide sequence of a very small human gene occupies a quarter of a page of text (), while the complete sequence of nucleotides in the human genome would fill more than a thousand books the size of this one. In addition to other critical information, it carries the instructions for about 30,000 distinct proteins.

The nucleotide sequence of the human -globin gene. This gene carries the information for the amino acid sequence of one of the two types of subunits of the hemoglobin molecule, which carries oxygen in the blood. A different gene, the -globin (more...)

At each cell division, the cell must copy its genome to pass it to both daughter cells. The discovery of the structure of DNA also revealed the principle that makes this copying possible: because each strand of DNA contains a sequence of nucleotides that is exactly complementary to the nucleotide sequence of its partner strand, each strand can act as a template, or mold, for the synthesis of a new complementary strand. In other words, if we designate the two DNA strands as S and S, strand S can serve as a template for making a new strand S, while strand S can serve as a template for making a new strand S (). Thus, the genetic information in DNA can be accurately copied by the beautifully simple process in which strand S separates from strand S, and each separated strand then serves as a template for the production of a new complementary partner strand that is identical to its former partner.

DNA as a template for its own duplication. As the nucleotide A successfully pairs only with T, and G with C, each strand of DNA can specify the sequence of nucleotides in its complementary strand. In this way, double-helical DNA can be copied precisely. (more...)

The ability of each strand of a DNA molecule to act as a template for producing a complementary strand enables a cell to copy, or replicate, its genes before passing them on to its descendants. In the next chapter we describe the elegant machinery the cell uses to perform this enormous task.

Nearly all the DNA in a eucaryotic cell is sequestered in a nucleus, which occupies about 10% of the total cell volume. This compartment is delimited by a nuclear envelope formed by two concentric lipid bilayer membranes that are punctured at intervals by large nuclear pores, which transport molecules between the nucleus and the cytosol. The nuclear envelope is directly connected to the extensive membranes of the endoplasmic reticulum. It is mechanically supported by two networks of intermediate filaments: one, called the nuclear lamina, forms a thin sheetlike meshwork inside the nucleus, just beneath the inner nuclear membrane; the other surrounds the outer nuclear membrane and is less regularly organized ().

A cross-sectional view of a typical cell nucleus. The nuclear envelope consists of two membranes, the outer one being continuous with the endoplasmic reticulum membrane (see also Figure 12-9). The space inside the endoplasmic reticulum (the ER lumen) (more...)

The nuclear envelope allows the many proteins that act on DNA to be concentrated where they are needed in the cell, and, as we see in subsequent chapters, it also keeps nuclear and cytosolic enzymes separate, a feature that is crucial for the proper functioning of eucaryotic cells. Compartmentalization, of which the nucleus is an example, is an important principle of biology; it serves to establish an environment in which biochemical reactions are facilitated by the high concentration of both substrates and the enzymes that act on them.

Genetic information is carried in the linear sequence of nucleotides in DNA. Each molecule of DNA is a double helix formed from two complementary strands of nucleotides held together by hydrogen bonds between G-C and A-T base pairs. Duplication of the genetic information occurs by the use of one DNA strand as a template for formation of a complementary strand. The genetic information stored in an organism's DNA contains the instructions for all the proteins the organism will ever synthesize. In eucaryotes, DNA is contained in the cell nucleus.

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DNA – structure – chemguide

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DNA - STRUCTURE

This page, looking at the structure of DNA, is the first in a sequence of pages leading on to how DNA replicates (makes copies of) itself, and then to how information stored in DNA is used to make protein molecules. This material is aimed at 16 - 18 year old chemistry students. If you are interested in this from a biological or biochemical point of view, you may find these pages a useful introduction before you get more information somewhere else.

Chemistry students at UK A level (or its various equivalents) should not waste time on this. The booklet is written for A level biology students, and goes into far more detail than you will need for chemistry purposes.

A quick look at the whole structure of DNA

These days, most people know about DNA as a complex molecule which carries the genetic code. Most will also have heard of the famous double helix.

I'm going to start with a diagram of the whole structure, and then take it apart to see how it all fits together. The diagram shows a tiny bit of a DNA double helix.

Normally I prefer to draw my own diagrams, but my drawing software isn't sophisticated enough to produce convincing twisted "ribbons".

Exploring a DNA chain

The sugars in the backbone

The backbone of DNA is based on a repeated pattern of a sugar group and a phosphate group. The full name of DNA, deoxyribonucleic acid, gives you the name of the sugar present - deoxyribose.

Deoxyribose is a modified form of another sugar called ribose. I'm going to give you the structure of that first, because you will need it later anyway. Ribose is the sugar in the backbone of RNA, ribonucleic acid.

This diagram misses out the carbon atoms in the ring for clarity. Each of the four corners where there isn't an atom shown has a carbon atom.

The heavier lines are coming out of the screen or paper towards you. In other words, you are looking at the molecule from a bit above the plane of the ring.

So that's ribose. Deoxyribose, as the name might suggest, is ribose which has lost an oxygen atom - "de-oxy".

The only other thing you need to know about deoxyribose (or ribose, for that matter) is how the carbon atoms in the ring are numbered.

The carbon atom to the right of the oxygen as we have drawn the ring is given the number 1, and then you work around to the carbon on the CH2OH side group which is number 5.

You will notice that each of the numbers has a small dash by it - 3' or 5', for example. If you just had ribose or deoxyribose on its own, that wouldn't be necessary, but in DNA and RNA these sugars are attached to other ring compounds. The carbons in the sugars are given the little dashes so that they can be distinguished from any numbers given to atoms in the other rings.

You read 3' or 5' as "3-prime" or "5-prime".

Attaching a phosphate group

The other repeating part of the DNA backbone is a phosphate group. A phosphate group is attached to the sugar molecule in place of the -OH group on the 5' carbon.

I don't want to get bogged down in this. The version I am using is fine for chemistry purposes, and will make it easy to see how the DNA backbone is put together. We are soon going to simplify all this down anyway!

Attaching a base and making a nucleotide

The final piece that we need to add to this structure before we can build a DNA strand is one of four complicated organic bases. In DNA, these bases are cytosine (C), thymine (T), adenine (A) and guanine (G).

These bases attach in place of the -OH group on the 1' carbon atom in the sugar ring.

What we have produced is known as a nucleotide.

We now need a quick look at the four bases. If you need these in a chemistry exam at this level, the structures will almost certainly be given to you.

Here are their structures:

The nitrogen and hydrogen atoms shown in blue on each molecule show where these molecules join on to the deoxyribose. In each case, the hydrogen is lost together with the -OH group on the 1' carbon atom of the sugar. This is a condensation reaction - two molecules joining together with the loss of a small one (not necessarily water).

For example, here is what the nucleotide containing cytosine would look like:

Joining the nucleotides into a DNA strand

A DNA strand is simply a string of nucleotides joined together. I can show how this happens perfectly well by going back to a simpler diagram and not worrying about the structure of the bases.

The phosphate group on one nucleotide links to the 3' carbon atom on the sugar of another one. In the process, a molecule of water is lost - another condensation reaction.

. . . and you can continue to add more nucleotides in the same way to build up the DNA chain.

Now we can simplify all this down to the bare essentials!

Both are right and, equally, both are misleading! The shape of the bonds around the phosphorus atom is tetrahedral, and all of the bonds are at approximately 109 to each other. Whichever way you choose to draw this in 2-dimensions on paper, it still represents the same molecule in reality.

To take a simpler example, if you draw a structural formula for CH2Cl2 using simple bond notation, you could equally well draw the chlorine atoms at right angles to each other or opposite each other. The molecule would still be exactly the same. This is one of the things you had to learn when you first started drawing structures for organic molecules. If you still aren't sure about this, look again at the page about drawing organic molecules.

Building a DNA chain concentrating on the essentials

What matters in DNA is the sequence the four bases take up in the chain. We aren't particularly interested in the backbone, so we can simplify that down. For the moment, we can simplify the precise structures of the bases as well.

We can build the chain based on this fairly obvious simplification:

There is only one possible point of confusion here - and that relates to how the phosphate group, P, is attached to the sugar ring. Notice that it is joined via two lines with an angle between them.

By convention, if you draw lines like this, there is a carbon atom where these two lines join. That is the carbon atom in the CH2 group if you refer back to a previous diagram. If you had tried to attach the phosphate to the ring by a single straight line, that CH2 group would have got lost!

Joining up lots of these gives you a part of a DNA chain. The diagram below is a bit from the middle of a chain. Notice that the individual bases have been identified by the first letters of the base names. (A = adenine, etc). Notice also that there are two different sizes of base. Adenine and guanine are bigger because they both have two rings. Cytosine and thymine only have one ring each.

If the top of this segment was the end of the chain, then the phosphate group would have an -OH group attached to the spare bond rather than another sugar ring.

Similarly, if the bottom of this segment of chain was the end, then the spare bond at the bottom would also be to an -OH group on the deoxyribose ring.

Joining the two DNA chains together

The importance of "base pairs"

Have another look at the diagram we started from:

If you look at this carefully, you will see that an adenine on one chain is always paired with a thymine on the second chain. And a guanine on one chain is always paired with a cytosine on the other one.

So how exactly does this work?

The first thing to notice is that a smaller base is always paired with a bigger one. The effect of this is to keep the two chains at a fixed distance from each other all the way along.

But, more than this, the pairing has to be exactly . . .

That is because these particular pairs fit exactly to form very effective hydrogen bonds with each other. It is these hydrogen bonds which hold the two chains together.

The base pairs fit together as follows.

The A-T base pair:

The G-C base pair:

If you try any other combination of base pairs, they won't fit!

If hydrogen bonding worries you, follow this link for detailed explanations. Use the BACK button on your browser to return here later.

A final structure for DNA showing the important bits

Notice that the two chains run in opposite directions, and the right-hand chain is essentially upside-down. You will also notice that I have labelled the ends of these bits of chain with 3' and 5'.

If you followed the left-hand chain to its very end at the top, you would have a phosphate group attached to the 5' carbon in the deoxyribose ring. If you followed it all the way to the other end, you would have an -OH group attached to the 3' carbon.

In the second chain, the top end has a 3' carbon, and the bottom end a 5'.

This 5' and 3' notation becomes important when we start talking about the genetic code and genes. The genetic code in genes is always written in the 5' to 3' direction along a chain.

It is also important when we take a very simplified look at how DNA makes copies of itself on the next page . . .

To the next page about DNA . . .

To the amino acid and other biochemistry menu . . .

To the menu of other organic compounds . . .

To Main Menu . . .

Jim Clark 2007 (modified May 2016)

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DNA – Definition by AcronymFinder

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DNA Department(al) Network Administrator DNA Does Not Apply DNA Deoxyribonucleic Acid DNA Genentech, Inc (stock symbol) DNA Data Not Available DNA Dermatology Nurses' Association DNA Directia Nationala Anticoruptie (Romanian) DNA Defense Nuclear Agency DNA Do Not Adopt (used by animal shelters to refer to animal abusers) DNA Det Norske Arbeiderparti (Norwegian Labour Party) DNA Distributed Internet Applications Architecture (Microsoft) DNA Dynamic Network Administration (Ericsson) DNA De Nieuw Amsterdam (theater group) DNA Distributed Network Attack DNA Do Not Announce (hospital patient privacy) DnA Do Not Abbreviate (online gaming clan) DNA Deutscher Normenausschuss (German Committee of Standards) DNA National Dyslexia Association (humor) DNA Direct Network Access DNA Dernire Nouvelles d'Alsace (French newspaper) DNA DoNotAge (OSPF) DNA Datanetwork Associates (Software) DNA Dinebeiina Nahiilna be Agaditahe (Navajo legal counselors) DNA Did Not Answer DNA Did Not Attend DNA Do Not Ask DNA Definitely Not Attractive DNA Down Auxiliary DNA Distributed Internetwork Architecture (Microsoft) DNA Did Not Attack (Dana Carvey) DNA Do Not Approve DNA Do Not Answer (cell phone) DNA Do Not Admit DNA Drug 'n Alcohol (band) DNA Diversified Naval Architects, Inc. (Ottawa, Ontario, Canada) DNA Dorchester Neighborhood Association (Waldorf, Maryland) DNA Djibouti National Army DNA Digital Narrowband Analysis DNA Distributed Networking Agent DNA Downriver Numismatic Association DNA Designated National Authority DNA Douglas Noel Adams (late British author of the Hitchhiker's Guide to the Galaxy series) DNA Development Needs Analysis DNA Digital Network Architecture DNA Digital Nonlinear Accelerator DNA Direction de la Navigation Arienne (French: Directorate of Air Navigation; Morocco) DNA Direction Nationale de l'Arbitrage (French: National Directorate of Arbitration) DNA Direzione Nazionale Antimafia (Italian: National Anti-Mafia Directorate) DNA Distributed interNet Applications DNA Detroit News Agency DNA Die Neue Allianz (German: The New Alliance) DNA Dernires Nouvelles d'Algrie (French: Latest News from Algeria) DNA Department of Native Affairs (various locations) DNA Dpense Non Admise (French: Non-Deductible Expense) DNA Delaware Nurses Association DNA Delayed Neutron Activation DNA Delivery Network Accelerator (BitTorrent) DNA Delta Nu Alpha DNA Denver Newspaper Agency (Denver, CO) DNA Daily News and Analysis (India; newspaper) DNA Dark Native Apostle (gaming) DNA Domain Name Authority (various locations) DNA Doctors Net Access DNA Distribution Nationale Airsoft (French airsoft supply company) DNA Distributed Network Analyzer DNA Do Not Abbreviate DNA Dynamic Network Analyzer (Lucent) DNA Dynamic Network Architecture

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DNA - Definition by AcronymFinder

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Chapter 1: How Genes Work: The New Genetics – National …

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People have known for many years that living things inherit traits from their parents. That common-sense observation led to agriculture, the purposeful breeding and cultivation of animals and plants for desirable characteristics. Firming up the details took quite some time, though. Researchers did not understand exactly how traits were passed to the next generation until the middle of the 20th century.

Now it is clear that genes are what carry our traits through generations and that genes are made of deoxyribonucleic acid (DNA). But genes themselves don't do the actual work. Rather, they serve as instruction books for making functional molecules such as ribonucleic acid (RNA) and proteins, which perform the chemical reactions in our bodies.

Proteins do many other things, too. They provide the body's main building materials, forming the cell's architecture and structural components. But one thing proteins can't do is make copies of themselves. When a cell needs more proteins, it uses the manufacturing instructions coded in DNA.

The DNA code of a genethe sequence of its individual DNA building blocks, labeled A (adenine), T (thymine), C (cytosine) and G (guanine) and collectively called nucleotides spells out the exact order of a protein's building blocks, amino acids.

Occasionally, there is a kind of typographical error in a gene's DNA sequence. This mistake which can be a change, gap or duplicationis called a mutation.

A mutation can cause a gene to encode a protein that works incorrectly or that doesn't work at all. Sometimes, the error means that no protein is made.

But not all DNA changes are harmful. Some mutations have no effect, and others produce new versions of proteins that may give a survival advantage to the organisms that have them. Over time, mutations supply the raw material from which new life forms evolve (see Chapter 3, "Life's Genetic Tree").

The monk Gregor Mendel first described how traits are inherited from one generation to the next.

In 1900, three European scientists independently discovered an obscure research paper that had been published nearly 35 years before. Written by Gregor Mendel, an Austrian monk who was also a scientist, the report described a series of breeding experiments performed with pea plants growing in his abbey garden.

Mendel had studied how pea plants inherited the two variant forms of easy-to-see traits. These included flower color (white or purple) and the texture of the peas (smooth or wrinkled). Mendel counted many generations of pea plant offspring and learned that these characteristics were passed on to the next generation in orderly, predictable ratios.

When he cross-bred purple-flowered pea plants with white-flowered ones, the next generation had only purple flowers. But directions for making white flowers were hidden somewhere in the peas of that generation, because when those purple-flowered plants were bred to each other, some of their offspring had white flowers. What's more, the second-generation plants displayed the colors in a predictable pattern. On average, 75 percent of the second-generation plants had purple flowers and 25 percent of the plants had white flowers. Those same ratios persisted, and were reproduced when the experiment was repeated many times over.

Trying to solve the mystery of the missing color blooms, Mendel imagined that the reproductive cells of his pea plants might contain discrete "factors," each of which specified a particular trait, such as white flowers. Mendel reasoned that the factors, whatever they were, must be physical material because they passed from parent to offspring in a mathematically orderly way. It wasn't until many years later, when the other scientists unearthed Mendel's report, that the factors were named genes.

Early geneticists quickly discovered that Mendel's mathematical rules of inheritance applied not just to peas, but also to all plants, animals and people. The discovery of a quantitative rule for inheritance was momentous. It revealed that a common, general principle governed the growth and development of all life on Earth.

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Up until the 1950s, scientists knew a good deal about heredity, but they didn't have a clue what DNA looked like. In order to learn more about DNA and its structure, some scientists experimented with using X rays as a form of molecular photography.

In 1953, Watson and Crick created their historic model of the shape of DNA: the double helix. COLD SPRING HARBOR LABORATORY ARCHIVES

Rosalind Franklin, a physical chemist working with Maurice Wilkins at King's College in London, was among the first to use this method to analyze genetic material. Her experiments produced what were referred to at the time as "the most beautiful X-ray photographs of any substance ever taken."

Other scientists, including zoologist James Watson and physicist Francis Crick, both working at Cambridge University in the United Kingdom, were trying to determine the shape of DNA too. Ultimately, this line of research revealed one of the most profound scientific discoveries of the 20th century: that DNA exists as a double helix.

The 1962 Nobel Prize in physiology or medicine was awarded to Watson, Crick and Wilkins for this work. Although Franklin did not earn a share of the prize due to her untimely death at age 38, she is widely recognized as having played a significant role in the discovery.

Rosalind Franklin's original X-ray diffraction photo revealed the physical structure of DNA. OREGON STATE UNIVERSITY LIBRARIES SPECIAL COLLECTIONS

The spiral staircase-shaped double helix has attained global status as the symbol for DNA. But what is so beautiful about the discovery of the twisting ladder structure isn't just its good looks. Rather, the structure of DNA taught researchers a fundamental lesson about genetics. It taught them that the two connected strandswinding together like parallel handrailswere complementary to each other, and this unlocked the secret of how genetic information is stored, transferred and copied.

In genetics, complementary means that if you know the sequence of nucleotide building blocks on one strand, you know the sequence of nucleotide building blocks on the other strand: A always matches up with T and C always links to G (see drawing).

Long strings of nucleotides form genes, and groups of genes are packaged tightly into structures called chromosomes. Every cell in your body except for eggs, sperm and red blood cells contains a full set of chromosomes in its nucleus.

If the chromosomes in one of your cells were uncoiled and placed end to end, the DNA would be about 6 feet long. If all the DNA in your body were connected in this way, it would stretch approximately 67 billion miles! That's nearly 150,000 round trips to the Moon.

The long, stringy DNA that makes up genes is spooled within chromosomes inside the nucleus of a cell. (Note that a gene would actually be a much longer stretch of DNA than what is shown here.)

DNA consists of two long, twisted chains made up of nucleotides. Each nucleotide contains one base, one phosphate molecule and the sugar molecule deoxyribose. The bases in DNA nucleotides are adenine, thymine, cytosine and guanine.

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Humans have 23 pairs of chromosomes. Male DNA (pictured here) contains an X and a Y chromosome, whereas female DNA contains two X chromosomes. CYTOGENETICS LABORATORY, BRIGHAM AND WOMEN'S HOSPITAL

It's astounding to think that your body consists of trillions of cells. But what's most amazing is that it all starts with one cell. How does this massive expansion take place?

As an embryo progresses through development, its cells must reproduce. But before a cell divides into two new, nearly identical cells, it must copy its DNA so there will be a complete set of genes to pass on to each of the new cells.

To make a copy of itself, the twisted, compacted double helix of DNA has to unwind and separate its two strands. Each strand becomes a pattern, or template, for making a new strand, so the two new DNA molecules have one new strand and one old strand.

The copy is courtesy of a cellular protein machine called DNA polymerase, which reads the template DNA strand and stitches together the complementary new strand. The process, called replication, is astonishingly fast and accurate, although occasional mistakes, such as deletions or duplications, occur. Fortunately, a cellular spell-checker catches and corrects nearly all of these errors.

When DNA polymerase makes an error while copying a gene's DNA sequence, the mistake is called a mutation. In this example, the nucleotide G has been changed to an A.

During DNA replication, each strand of the original molecule acts as a template for the synthesis of a new, complementary DNA strand.

Mistakes that are not corrected can lead to diseases such as cancer and certain genetic disorders. Some of these include Fanconi anemia, early aging diseases and other conditions in which people are extremely sensitive to sunlight and some chemicals.

DNA copying is not the only time when DNA damage can happen. Prolonged, unprotected sun exposure can cause DNA changes that lead to skin cancer, and toxins in cigarette smoke can cause lung cancer.

It may seem ironic, then, that many drugs used to treat cancer work by attacking DNA. That's because these chemotherapy drugs disrupt the DNA copying process, which goes on much faster in rapidly dividing cancer cells than in other cells of the body. The trouble is that most of these drugs do affect normal cells that grow and divide frequently, such as cells of the immune system and hair cells.

Understanding DNA replication better could be a key to limiting a drug's action to cancer cells only.

After copying its DNA, a cell's next challenge is getting just the right amount of genetic material into each of its two offspring.

Most of your cells are called diploid ("di" means two, and "ploid" refers to sets of chromosomes) because they have two sets of chromosomes (23 pairs). Eggs and sperm are different; these are known as haploid cells. Each haploid cell has only one set of 23 chromosomes so that at fertilization the math will work out: A haploid egg cell will combine with a haploid sperm cell to form a diploid cell with the right number of chromosomes: 46.

Chromosomes are numbered 1 to 22, according to size, with 1 being the largest chromosome. The 23rd pair, known as the sex chromosomes, are called X and Y. In humans, abnormalities of chromosome number usually occur during meiosis, the time when a cell reduces its chromosomes from diploid to haploid in creating eggs or sperm.

What happens if an egg or a sperm cell gets the wrong number of chromosomes, and how often does this happen?

Trisomy, the hallmark of Down syndrome, results when a baby is born with three copies of chromosome 21 instead of the usual two.

Molecular biologist Angelika Amon of the Massachusetts Institute of Technology in Cambridge says that mistakes in dividing DNA between daughter cells during meiosis are the leading cause of human birth defects and miscarriages. Current estimates are that 10 percent of all embryos have an incorrect chromosome number. Most of these don't go to full term and are miscarried.

In women, the likelihood that chromosomes won't be apportioned properly increases with age. One of every 18 babies born to women over 45 has three copies of chromosome 13, 18 or 21 instead of the normal two, and this improper balancing can cause trouble. For example, three copies of chromosome 21 lead to Down syndrome.

To make her work easier, Amonlike many other basic scientistsstudies yeast cells, which separate their chromosomes almost exactly the same way human cells do, except that yeast do it much faster. A yeast cell copies its DNA and produces daughter cells in about 1 1/2 hours, compared to a whole day for human cells.

The yeast cells she uses are the same kind bakeries use to make bread and breweries use to make beer!

Amon has made major progress in understanding the details of meiosis. Her research shows how, in healthy cells, gluelike protein complexes called cohesins release pairs of chromosomes at exactly the right time. This allows the chromosomes to separate properly.

These findings have important implications for understanding and treating infertility, birth defects and cancer.

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So, we've described DNAits basic properties and how our bodies make more of it. But how does DNA serve as the language of life? How do you get a protein from a gene?

There are two major steps in making a protein. The first is transcription, where the information coded in DNA is copied into RNA. The RNA nucleotides are complementary to those on the DNA: a C on the RNA strand matches a G on the DNA strand.

1. RNA polymerase transcribes DNA to make messenger RNA (mRNA). 2. The mRNA sequence (dark red strand) is complementary to the DNA sequence (blue strand). 3. On ribosomes, transfer RNA (tRNA) helps convert mRNA into protein. 4. Amino acids link up to make a protein.

The only difference is that RNA pairs a nucleotide called uracil (U), instead of a T, with an A on the DNA.

A protein machine called RNA polymerase reads the DNA and makes the RNA copy. This copy is called messenger RNA, or mRNA, because it delivers the gene's message to the protein-producing machinery.

At this point you may be wondering why all of the cells in the human body aren't exactly alike, since they all contain the same DNA.What makes a liver cell different from a brain cell? How do the cells in the heart make the organ contract, but those in skin allow us to sweat?

Cells can look and act differently, and do entirely different jobs, because each cell "turns on," or expresses, only the genes appropriate for what it needs to do.

RNA polymerase (green) and one end of a DNA strand (blue) are attached to clear beads pinned down in two optical traps. As RNA polymerase moves along the DNA, it creates an RNA copy of a gene, shown here as a pink strand. STEVEN BLOCK

That's because RNA polymerase does not work alone, but rather functions with the aid of many helper proteins. While the core part of RNA polymerase is the same in all cells, the helpers vary in different cell types throughout the body.

You'd think that for a process so essential to life, researchers would know a lot about how transcription works. While it's true that the basics are clearbiologists have been studying gene transcribing by RNA polymerases since these proteins were first discovered in 1960 some of the details are actually still murky.

The biggest obstacle to learning more has been a lack of tools. Until recently, researchers were unable to get a picture at the atomic level of the giant RNA polymerase protein assemblies inside cells to understand how the many pieces of this amazing, living machine do what they do, and do it so well.

But our understanding is improving fast, thanks to spectacular technological advances. We have new X-ray pictures that are far more sophisticated than those that revealed the structure of DNA. Roger Kornberg of Stanford University in California used such methods to determine the structure of RNA polymerase. This work earned him the 2006 Nobel Prize in chemistry. In addition, very powerful microscopes and other tools that allow us to watch one molecule at a time provide a new look at RNA polymerase while it's at work reading DNA and producing RNA.

For example, Steven Block, also of Stanford, has used a physics technique called optical trapping to track RNA polymerase as it inches along DNA. Block and his team performed this work by designing a specialized microscope sensitive enough to watch the real-time motion of a single polymerase traveling down a gene on one chromosome.

The researchers discovered that molecules of RNA polymerase behave like battery-powered spiders as they crawl along the DNA ladder, adding nucleotides one at a time to the growing RNA strand. The enzyme works much like a motor, Block believes, powered by energy released during the chemical synthesis of RNA.

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Genes are often interrupted by stretches of DNA (introns, blue) that do not contain instructions for making a protein. The DNA segments that do contain protein-making instructions are known as exons (green).

Several types of RNA play key roles in making a protein. The gene transcript (the mRNA) transfers information from DNA in the nucleus to the ribosomes that make protein. Ribosomal RNA forms about 60 percent of the ribosomes. Lastly, transfer RNA carries amino acids to the ribosomes. As you can see, all three types of cellular RNAs come together to produce new proteins.

But the journey from gene to protein isn't quite as simple as we've just made it out to be. After transcription, several things need to happen to mRNA before a protein can be made. For example, the genetic material of humans and other eukaryotes (organisms that have a nucleus) includes a lot of DNA that doesn't encode proteins. Some of this DNA is stuck right in the middle of genes.

To distinguish the two types of DNA, scientists call the coding sequences of genes exons and the pieces in between introns (for intervening sequences).

If RNA polymerase were to transcribe DNA from the start of an intron-containing gene to the end, the RNA would be complementary to the introns as well as the exons.

To get an mRNA molecule that yields a working protein, the cell needs to trim out the intron sections and then stitch only the exon pieces together (see drawing). This process is called RNA splicing.

Arranging exons in different patterns, called alternative splicing, enables cells to make different proteins from a single gene.

Splicing has to be extremely accurate. An error in the splicing process, even one that results in the deletion of just one nucleotide in an exon or the addition of just one nucleotide in an intron, will throw the whole sequence out of alignment. The result is usually an abnormal proteinor no protein at all. One form of Alzheimer's disease, for example, is caused by this kind of splicing error.

Molecular biologist Christine Guthrie of the University of California, San Francisco, wants to understand more fully the mechanism for removing intron RNA and find out how it stays so accurate.

She uses yeast cells for these experiments. Just like human DNA, yeast DNA has introns, but they are fewer and simpler in structure and are therefore easier to study. Guthrie can identify which genes are required for splicing by finding abnormal yeast cells that mangle splicing.

So why do introns exist, if they're just going to be chopped out? Without introns, cells wouldn't need to go through the splicing process and keep monitoring it to be sure it's working right.

As it turns out, splicing also makes it possible for cells to create more proteins.

Think about all the exons in a gene. If a cell stitches together exons 1, 2 and 4, leaving out exon 3, the mRNA will specify the production of a particular protein. But instead, if the cell stitches together exons 1, 2 and 3, this time leaving out exon 4, then the mRNA will be translated into a different protein (see drawing).

By cutting and pasting the exons in different patterns, which scientists call alternative splicing, a cell can create different proteins from a single gene. Alternative splicing is one of the reasons why human cells, which have about 20,000 genes, can make hundreds of thousands of different proteins.

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Until recently, researchers looked at genes, and the proteins they encode, one at a time. Now, they can look at how large numbers of genes and proteins act, as well as how they interact. This gives them a much better picture of what goes on in a living organism.

Already, scientists can identify all of the genes that are transcribed in a cellor in an organ, like the heart. And although researchers can't tell you, right now, what's going on in every cell of your body while you read a book or walk down the street, they can do this sort of "whole-body" scan for simpler, single-celled organisms like yeast.

Using a technique called genome-wide location analysis, Richard Young of the Massachusetts Institute of Technology unraveled a "regulatory code" of living yeast cells, which have more than 6,000 genes in their genome. Young's technique enabled him to determine the exact places where RNA polymerase's helper proteins sit on DNA and tell RNA polymerase to begin transcribing a gene.

Since he did the experiment with the yeast exposed to a variety of different conditions,Young was able to figure out how transcription patterns differ when the yeast cell is under stress (say, in a dry environment) or thriving in a sugary-rich nutrient solution. Done one gene at a time, using methods considered state-of-the-art just a few years ago, this kind of analysis would have taken hundreds of years.

After demonstrating that his technique worked in yeast, Young then took his research a step forward. He used a variation of the yeast method to scan the entire human genome in small samples of cells taken from the pancreases and livers of people with type 2 diabetes. He used the results to identify genes that aren't transcribed correctly in people with the disease.

This information provides researchers with an important tool for understanding how diabetes and other diseases are influenced by defective genes. By building models to predict how genes respond in diverse situations, researchers may be able to learn how to stop or jump-start genes on demand, change the course of a disease or prevent it from ever happening.

While most genetic research uses lab organisms, test tubes and petri dishes, the results have real consequences for people. Your first encounter with genetic analysis probably happened shortly after you were born, when a doctor or nurse took a drop of blood from the heel of your tiny foot.

Lab tests performed with that single drop of blood can diagnose certain rare genetic disorders as well as metabolic problems like phenylketonuria (PKU).

Screening newborns in this way began in the 1960s in Massachusetts with testing for PKU, a disease affecting 1 in 14,000 people. PKU is caused by an enzyme that doesn't work properly due to a genetic mutation. Those born with this disorder cannot metabolize the amino acid phenylalanine, which is present in many foods. Left untreated, PKU can lead to mental retardation and neurological damage, but a special diet can prevent these outcomes. Testing for this condition has made a huge difference in many lives.

Newborn screening is governed by individual states. This means that the state in which a baby is born determines the genetic conditions for which he or she will be screened. Currently, states test for between 28 and 54 conditions. All states test for PKU.

Although expanded screening for genetic diseases in newborns is advocated by some, others question the value of screening for conditions that are currently untreatable. Another issue is that some children with mild versions of certain genetic diseases may be treated needlessly.

In 2006, the Advisory Committee on Heritable Disorders in Newborns and Children, which assists the Secretary of the U.S. Department of Health and Human Services, recommended a standard, national set of newborn tests for 29 conditions, ranging from relatively common hearing problems to very rare metabolic diseases.

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A ribosome consists of large and small protein subunits with transfer RNAs nestled in the middle. RIBOSOME STRUCTURE COURTESY OF JAMIE CATE, MARAT YUSUPOV, GULNARA YUSUPOVA, THOMAS EARNEST AND HARRY NOLLER. GRAPHIC COURTESY OF ALBION BAUCOM, UNIVERSITY OF CALIFORNIA, SANTA CRUZ.

After a gene has been read by RNA polymerase and the RNA is spliced, what happens next in the journey from gene to protein? The next step is reading the RNA information and fitting the building blocks of a protein together. This is called translation, and its principal actors are the ribosome and amino acids.

Ribosomes are among the biggest and most intricate structures in the cell. The ribosomes of bacteria contain not only huge amounts of RNA, but also more than 50 different proteins. Human ribosomes have even more RNA and between 70 and 80 different proteins!

Harry Noller of the University of California, Santa Cruz, has found that a ribosome performs several key jobs when it translates the genetic code of mRNA. As the messenger RNA threads through the ribosome protein machine, the ribosome reads the mRNA sequence and helps recognize and recruit the correct amino acid-carrying transfer RNA to match the mRNA code. The ribosome also links each additional amino acid into a growing protein chain (see drawing).

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Chapter 1: How Genes Work: The New Genetics - National ...

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