Difference between revisions of "Deoxyribonucleic acid"

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'''Deoxyribonucleic acid''' (DNA) is an [[organic compound|organic]] [[chemical compound]] made up of [[molecule]]s shaped like a [[double helix]], a continuously twisted ladder. The individual monomeric building blocks of DNA (and other nucleic acids) are [[nucleotide]]s, which themselves consist of three principle moieties: A nitrogenous base, a [[sugar]], and a [[phosphate]] group.   
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'''Deoxyribonucleic acid''' (DNA) is an [[organic compound|organic]] [[chemical compound]] made up of [[molecule]]s shaped like a [[double helix]]. The individual monomeric building blocks of DNA (and other nucleic acids) are [[nucleotide]]s, which themselves consist of three principle moieties: A nitrogenous base, a [[sugar]], and a [[phosphate]] group.   
  
DNA carries the [[gene|genet]]ic coding for the [[protein]]s that form the bodies of living [[organism]]s, as well as the blueprints for generating some [[RNA]]. All organisms contain DNA, and the DNA of a sexually reproducing organism is a mix of its parent's DNA.
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DNA contains genes that code for proteins by first being transcribed into RNA. All organisms contain DNA, except for a few viruses. Offspring of sexually producing organisms contain DNA from both parents.
  
 
==History==
 
==History==
 
In the late 19th century [[Friedrich Miescher]], a Swiss [[biochemist]], discovered an unusual [[acid]] in the [[nuclei]] of cells. The acid was named deoxyribonucleic acid, or DNA. In 1944 the American [[biologist]]s, [[Alfred Hershey]], [[Thomas Gilmore]] and [[Martha Chase]] used experiments with [[bacteria]] and [[bacteriophage]]s to show that DNA passed [[gene]]s from one generation to the next.
 
In the late 19th century [[Friedrich Miescher]], a Swiss [[biochemist]], discovered an unusual [[acid]] in the [[nuclei]] of cells. The acid was named deoxyribonucleic acid, or DNA. In 1944 the American [[biologist]]s, [[Alfred Hershey]], [[Thomas Gilmore]] and [[Martha Chase]] used experiments with [[bacteria]] and [[bacteriophage]]s to show that DNA passed [[gene]]s from one generation to the next.
  
At that time, it was unclear how this simple molecule could hold all the complex information controlling the development of humans, animals and plants. Scientists knew it was made of four chemical bases called [[adenine]] (A), [[thymine]] (T), [[guanine]] (G) and [[cytosine]] (C), plus [[phosphoric acid]] and a [[sugar]]. They also knew that there was always the same amount of A as T and of G as C in cells, but they did not know the rules that controlled the arrangement.
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At that time, it was unclear how this simple molecule could hold all the complex information controlling the development of humans, animals and plants. Scientists knew it was made of four chemical bases called [[adenine]] (A), [[thymine]] (T), [[guanine]] (G) and [[cytosine]] (C), plus [[phosphoric acid]] and a [[sugar]]. They also knew that the ratios of A and T as well as G and C were always the same, but they did not know the rules that controlled the arrangement.
  
British scientists [[Rosalind Franklin]] and [[Maurice Wilkins]]  passed [[X-ray|X-rays]] through DNA to study the patterns made when the crystals diffracted them. From studying photographs of patterns, Rosalind Franklin concluded that DNA must be be a [[helix]]. [[James Watson]] and [[Francis Crick]], working in [[Cambridge]], used this information to help them solve the puzzle of DNA structure. They built a model showing that if A always paired with T and G paired with C, DNA must be like a ladder made of two strands twisted together in a double helix. The sugar and phosphoric acid were the sides of the ladder, and the rungs were the paired bases.
+
British scientists [[Rosalind Franklin]] and [[Maurice Wilkins]]  passed [[X-ray|X-rays]] through DNA to study the patterns made when the crystals diffracted them. From studying photographs of patterns, Rosalind Franklin concluded that DNA must be be a [[helix]]. [[James Watson]] and [[Francis Crick]], working in [[Cambridge]], used this information to help them solve the puzzle of DNA structure. They built a model showing that if A always paired with T and G paired with C, DNA must be like a ladder made of two strands twisted together in a double helix. The sugar and phosphoric acid were the sides of the ladder, and the rungs were the paired bases that were held together through hydrogen bonding.
  
Watson and Crick suggested that DNA could unzip itself into two separate strands, and each strand could act as a pattern to grow a new strand. Crick showed later that each pair of genes worked in a group of three making the code for amino acids, the building blocks of proteins. These groups are called [[codon|codons]]. They make about fifty thousand different types of [[protein]], which make all the different types of cell in the body. Indian biochemist [[Har Gobind Khorana]] made all the possible codons and worked out which codons controlled which [[amino acid]].  
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Watson and Crick suggested that DNA could unzip itself into two separate strands, and each strand could act as a pattern to grow a new strand. Crick showed later that areas of the DNA known as genes worked in groups of three to code for amino acids, the building blocks of proteins. These groups are called [[codon|codons]]. They make about fifty thousand different types of [[protein]], which make all the different types of cell in the body. Indian biochemist [[Har Gobind Khorana]] made all the possible codons and worked out which codons controlled which [[amino acid]]. Most codons are redundant and code for the same amino acids, these mostly are different in only the third base pair. This means that differences in genotype can build up in the third position (thereby changing the genotype) without changing the protein (keeps the same phenotype).
  
If the DNA in one cell was stretched out, it would be about three feet long. Although DNA has a very simple structure, it can carry an enormous amount of [[information]]. Scientists do not yet understand all the DNA they see, but in 1991 a project called the [[Human Genome Project]] began to use computers to map the three billion base pairs which make up the 46 human [[chromosome|chromosomes]].
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If the DNA in one cell was stretched out, it would be about three feet long. Although DNA has a very simple structure, it can carry an enormous amount of [[information]]. Scientists do not yet understand the function of all DNA, but in 1991 a project called the [[Human Genome Project]] began to use computers to map the three billion base pairs which make up the 46 human [[chromosome|chromosomes]].
  
 
==Modern understanding==
 
==Modern understanding==
 
[[Image:818.gif|right|thumb|Structure of DNA.]]
 
[[Image:818.gif|right|thumb|Structure of DNA.]]
Small lengths of DNA called [[gene]]s serve as the instructions for the body to carry out its functions and give rise to the physical traits of the organism. <ref>"Eye-color genes, through the proteins they encode, direct the amount and placement of melanin in the iris." [http://www.hhmi.org/cgi-bin/askascientist/highlight.pl?kw=&file=answers%2Fgenetics%2Fans_044.html Ask A Scientist - Genes and eye color]</ref> DNA is packaged into [[chromosomes]]. Each individual human being has 23 pairs of chromosomes, where one set is inherited from his/her mother and the other set is inherited from his/her father. 22 of these chromosomes are referred to as autosomes, while the remaining chromosome determines gender (sex chromosome).
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Small lengths of DNA called [[gene]]s serve as the instructions for the body to carry out its functions and give rise to the physical traits of the organism. <ref>"Eye-color genes, through the proteins they encode, direct the amount and placement of melanin in the iris." [http://www.hhmi.org/cgi-bin/askascientist/highlight.pl?kw=&file=answers%2Fgenetics%2Fans_044.html Ask A Scientist - Genes and eye color]</ref> DNA is packaged into [[chromosomes]]. Each individual human being has 23 pairs of chromosomes, where one set is inherited from his/her mother and the other set is inherited from his/her father. 22 of these chromosomes are referred to as autosomes, while the remaining chromosome is the sex chromosome that determines gender.
  
[[Prokaryotic DNA]] is circular (a closed loop), while [[eukaryotic DNA]] is linear (with ends) with the exception of [[Mitochondrial DNA]] and chloroplast DNA, which is circular too. The ends of eukaryotic DNA is protected by [[telomere]]s, which are joined together in knots, except when the cell is undergoing [[mitosis]]. DNA in [[prokaryote]]s usually consists only of one closed loop chromosome.<ref>Campbell, Neil A, et. al. ''Biology''. 6th ed. San Francisco: Benjamin Cummings, 2002. 299, 530-31.</ref>
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[[Prokaryotic DNA]] is circular (a closed loop), while [[eukaryotic DNA]] is linear (with ends) with the exception of [[Mitochondrial DNA]] and chloroplast DNA which is separate from that of the eukaryotic organism. Both mitochondria and chloroplasts were thought to once be prokayotic organisms that became symbiotes within eukaryotic organisms, this explains why they still retain their circular DNA. The ends of eukaryotic DNA is protected by [[telomere]]s, which are joined together in knots, except when the cell is undergoing [[mitosis]]. DNA in [[prokaryote]]s usually consists only of one closed loop chromosome.<ref>Campbell, Neil A, et. al. ''Biology''. 6th ed. San Francisco: Benjamin Cummings, 2002. 299, 530-31.</ref>
  
 
Some viral [[genome]]s are composed of DNA, such as that of the [[influenza]] virus.
 
Some viral [[genome]]s are composed of DNA, such as that of the [[influenza]] virus.
  
DNA changes account for differences between individuals. However, they can also cause medical problems such as [[cancer]]. Such DNA-based diseases can be inherited.
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Mutations in DNA accumulate over time and build up to create differences between organisms. Most mutations in DNA are harmless and don't affect the phenotype of the organism. Others can have beneficial effects, but some can disrupt important functions. Many diseases such as Autism and Ellis-van Creveld syndrome have been shown to occur due to these harmful genetic mutations.
  
DNA is [[transcription|transcribed]] into [[mRNA]], which is in turn [[translation|translated]] into [[proteins]] built from [[amino acids]]. Additionally, DNA maybe transcribed into functional RNAs (ribosomal and transfer RNA) that do not undergo translation. [[RNA]] can also be reverse-transcribed back into DNA, which is the called [[Complementary DNA]] or [[cDNA]].
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DNA is [[transcription|transcribed]] into [[mRNA]], which is in turn [[translation|translated]] into [[proteins]] built from [[amino acids]]. Additionally, DNA maybe transcribed into functional RNAs such as ribosomal (rRNA) or transfer (tRNA) that do not undergo translation. [[RNA]] can also be reverse-transcribed back into DNA, which is the called [[Complementary DNA]] or [[cDNA]].
  
 
==DNA fingerprinting==
 
==DNA fingerprinting==
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As well as showing how different we all are, DNA shows how much we are all the same. Only one small part of one chromosome distinguishes a boy from a girl. Genes give us different colored eyes, hair and skin, but 99.5% of any human's DNA is in the same order as everybody else’s.  
 
As well as showing how different we all are, DNA shows how much we are all the same. Only one small part of one chromosome distinguishes a boy from a girl. Genes give us different colored eyes, hair and skin, but 99.5% of any human's DNA is in the same order as everybody else’s.  
  
Every living thing on earth has DNA that uses the same basic chemicals as human DNA, but because their chemicals are in a different order, the DNA of a worm or a tree encodes for different proteins, and those proteins make different cells. Evolutionists believe that all these cells developed from the first single-cell creatures formed three thousand million years ago, evolving gradually into new species to adapt to their environment. Creationists believe that God created living things as distinct [[baraminology|"kinds"]], and point to [[information]] theory to show that the information on the DNA could not have arisen by chance. Indeed, even the [[genetic code]] itself cannot be formed by chance, since a code with two bases per codon would not contain enough information, while a code with four bases per codon would create too much redundancy in the code, increasing the rate of translational errors.
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Human DNA is made up of the same components as the DNA of other organisms, most species even share the same genes which code for the same proteins. This is why even fruit flies and mice can be used as model organisms in order to help better understand human genetic diseases.
  
 
==External links==
 
==External links==

Revision as of 01:51, October 26, 2008

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Deoxyribonucleic acid (DNA) is an organic chemical compound made up of molecules shaped like a double helix. The individual monomeric building blocks of DNA (and other nucleic acids) are nucleotides, which themselves consist of three principle moieties: A nitrogenous base, a sugar, and a phosphate group.

DNA contains genes that code for proteins by first being transcribed into RNA. All organisms contain DNA, except for a few viruses. Offspring of sexually producing organisms contain DNA from both parents.

History

In the late 19th century Friedrich Miescher, a Swiss biochemist, discovered an unusual acid in the nuclei of cells. The acid was named deoxyribonucleic acid, or DNA. In 1944 the American biologists, Alfred Hershey, Thomas Gilmore and Martha Chase used experiments with bacteria and bacteriophages to show that DNA passed genes from one generation to the next.

At that time, it was unclear how this simple molecule could hold all the complex information controlling the development of humans, animals and plants. Scientists knew it was made of four chemical bases called adenine (A), thymine (T), guanine (G) and cytosine (C), plus phosphoric acid and a sugar. They also knew that the ratios of A and T as well as G and C were always the same, but they did not know the rules that controlled the arrangement.

British scientists Rosalind Franklin and Maurice Wilkins passed X-rays through DNA to study the patterns made when the crystals diffracted them. From studying photographs of patterns, Rosalind Franklin concluded that DNA must be be a helix. James Watson and Francis Crick, working in Cambridge, used this information to help them solve the puzzle of DNA structure. They built a model showing that if A always paired with T and G paired with C, DNA must be like a ladder made of two strands twisted together in a double helix. The sugar and phosphoric acid were the sides of the ladder, and the rungs were the paired bases that were held together through hydrogen bonding.

Watson and Crick suggested that DNA could unzip itself into two separate strands, and each strand could act as a pattern to grow a new strand. Crick showed later that areas of the DNA known as genes worked in groups of three to code for amino acids, the building blocks of proteins. These groups are called codons. They make about fifty thousand different types of protein, which make all the different types of cell in the body. Indian biochemist Har Gobind Khorana made all the possible codons and worked out which codons controlled which amino acid. Most codons are redundant and code for the same amino acids, these mostly are different in only the third base pair. This means that differences in genotype can build up in the third position (thereby changing the genotype) without changing the protein (keeps the same phenotype).

If the DNA in one cell was stretched out, it would be about three feet long. Although DNA has a very simple structure, it can carry an enormous amount of information. Scientists do not yet understand the function of all DNA, but in 1991 a project called the Human Genome Project began to use computers to map the three billion base pairs which make up the 46 human chromosomes.

Modern understanding

Structure of DNA.

Small lengths of DNA called genes serve as the instructions for the body to carry out its functions and give rise to the physical traits of the organism. [1] DNA is packaged into chromosomes. Each individual human being has 23 pairs of chromosomes, where one set is inherited from his/her mother and the other set is inherited from his/her father. 22 of these chromosomes are referred to as autosomes, while the remaining chromosome is the sex chromosome that determines gender.

Prokaryotic DNA is circular (a closed loop), while eukaryotic DNA is linear (with ends) with the exception of Mitochondrial DNA and chloroplast DNA which is separate from that of the eukaryotic organism. Both mitochondria and chloroplasts were thought to once be prokayotic organisms that became symbiotes within eukaryotic organisms, this explains why they still retain their circular DNA. The ends of eukaryotic DNA is protected by telomeres, which are joined together in knots, except when the cell is undergoing mitosis. DNA in prokaryotes usually consists only of one closed loop chromosome.[2]

Some viral genomes are composed of DNA, such as that of the influenza virus.

Mutations in DNA accumulate over time and build up to create differences between organisms. Most mutations in DNA are harmless and don't affect the phenotype of the organism. Others can have beneficial effects, but some can disrupt important functions. Many diseases such as Autism and Ellis-van Creveld syndrome have been shown to occur due to these harmful genetic mutations.

DNA is transcribed into mRNA, which is in turn translated into proteins built from amino acids. Additionally, DNA maybe transcribed into functional RNAs such as ribosomal (rRNA) or transfer (tRNA) that do not undergo translation. RNA can also be reverse-transcribed back into DNA, which is the called Complementary DNA or cDNA.

DNA fingerprinting

DNA can help police track down criminals if an attacker leaves something like hair or blood at a crime scene. Everybody’s DNA is unique unless they are identical twins, and the genetic ‘fingerprint’ of this material can be enough to confirm if a suspect was at the scene. Genetic fingerprinting can also show if somebody is closely related to somebody else. Archaeologists used samples from living relatives to identify whether bodies found buried in a forest in Russia were the remains of the Tsar and his family, killed during the 1919 Russian revolution.

As well as showing how different we all are, DNA shows how much we are all the same. Only one small part of one chromosome distinguishes a boy from a girl. Genes give us different colored eyes, hair and skin, but 99.5% of any human's DNA is in the same order as everybody else’s.

Human DNA is made up of the same components as the DNA of other organisms, most species even share the same genes which code for the same proteins. This is why even fruit flies and mice can be used as model organisms in order to help better understand human genetic diseases.

External links

References

  1. "Eye-color genes, through the proteins they encode, direct the amount and placement of melanin in the iris." Ask A Scientist - Genes and eye color
  2. Campbell, Neil A, et. al. Biology. 6th ed. San Francisco: Benjamin Cummings, 2002. 299, 530-31.
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