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<!-- Adithya Sagar-->
{{BAMBED
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|DATE=August 20, 2011
|OLDID=1286497
<applet load='B-DNA.pdb' size='330'frame='true' align='right' caption='B-DNA' scene='DNA/B-dna/7' />
|BAMBEDDOI=10.1002/bmb.20566
}}
<StructureSection load='B-DNA.pdb' size='450' side='right' scene='DNA/B-dna/7' caption='The double-helical structure of B-DNA, shown as ball-and-stick (colored by element {{Template:ColorKey_Element_C}} {{Template:ColorKey_Element_H}} {{Template:ColorKey_Element_O}} {{Template:ColorKey_Element_N}} {{Template:ColorKey_Element_P}}) with the helical conformation of the sugar-phosphate shown as orange ribbon, and the planes of the nucleobases (drag down in the viewer to see them) in orange as well.'>
 
'''Deoxyribonucleic acid''' or '''DNA'''  is a molecule which is the carrier of genetic information in nearly all the living organisms. It contains the biological instructions for the development, survival and reproduction of organisms.
'''Deoxyribonucleic acid''' or '''DNA'''  is a molecule which is the carrier of genetic information in nearly all the living organisms. It contains the biological instructions for the development, survival and reproduction of organisms.
DNA is found in the nucleus of a cell where it is packaged into a compact form called a chromosome with the help of several proteins known as histones. It is also found in cell structures called mitochondria. However in case of prokaryotes DNA is not enclosed in a nucleus or a membrane but is present in the cytoplasm. The DNA in prokaryotes in generally circular and supercoiled without any histones. DNA stores genetic information as a sequence of nucleotides in special regions known as genes which are used to make proteins. The expression of genetic information into proteins is a two-stage process wherein the sequence of nucleotides in DNA is converted to a molecule called Ribonucleic acid or [[RNA]] by a process called [[transcription]]. RNA is used to make proteins by another process called [[translation]]. The human genome contains nearly 3 · 10<sup>9</sup> bases with around 20,000 genes on 23 chromosomes. <ref name='gene'>http://www.genome.gov/25520880 </ref>  
DNA is found in the nucleus of a cell where it is packaged into a compact form called a chromosome with the help of several proteins known as histones. It is also found in cell structures called mitochondria. However in case of prokaryotes DNA is not enclosed in a nucleus or a membrane but is present in the cytoplasm. The DNA in prokaryotes in generally circular and supercoiled without any histones. DNA stores genetic information as a sequence of nucleotides in special regions known as genes which are used to make proteins. The expression of genetic information into proteins is a two-stage process wherein the sequence of nucleotides in DNA is converted to a molecule called Ribonucleic acid or [[RNA]] by a process called [[transcription]]. RNA is used to make proteins by another process called [[translation]]. The human genome contains nearly 3 · 10<sup>9</sup> bases with around 20,000 genes on 23 chromosomes. <ref name='gene'>http://www.genome.gov/25520880 </ref>  
   
   
DNA was first discovered by the German biochemist Frederich Miescher in the year 1869.<ref>PMID: 17901982</ref> Based on the works of Erwin Chargaff, James Watson, Francis Crick, Maurice Wilkins and Rosalind Franklin, the structure of DNA was discovered in the year 1953. The structure of DNA is a <scene name='DNA/B-dna/15'>double helix</scene>: two complementary strands of polynucleotides that run in opposite directions and are held together by hydrogen bonds between them. This structure helps the DNA replicate itself during cell division and also for a single strand to serve as template during transcription. <ref name='gene'>http://www.genome.gov/25520880 </ref>
DNA was first discovered by the German biochemist Frederich Miescher in the year 1869.<ref>PMID: 17901982</ref> Based on the works of Erwin Chargaff, James Watson, Francis Crick, Maurice Wilkins and Rosalind Franklin, the structure of DNA was discovered in the year 1953. The structure of DNA is a <scene name='DNA/B-dna/15'>double helix</scene>: two complementary strands of polynucleotides that run in opposite directions and are held together by hydrogen bonds between them.<ref name='structure'>A Structure for Deoxyribose Nucleic Acid
Watson J.D. and Crick F.H.C.
Nature 171, 737-738 (1953)</ref> This structure helps the DNA replicate itself during cell division and also for a single strand to serve as template during transcription. <ref name='gene'>http://www.genome.gov/25520880 </ref>


<scene name='DNA/B-dna/7'>Restore View</scene>
<scene name='DNA/B-dna/7'>Restore View</scene>
== Features of a DNA Molecule ==
== Features of a DNA Molecule ==
<applet load='B-DNA.pdb' size='540' frame='true' align='left' caption='B-DNA' scene ='User:Adithya_Sagar/Sandbox_DNA/B-dna/4'/>
=== Double Helix ===
=== Double Helix ===
 
<scene name='User:Adithya_Sagar/Sandbox_DNA/B-dna/4'>DNA</scene> consists of two polynucleotide chains, <scene name='DNA/B-dna/16'>twisted around each other to form a double helix</scene>. The <scene name='10/100853/Nucleotide/2'>nucleotide</scene> in DNA is composed of a <scene name='10/100853/Phosphate/3'>phosphate</scene> bonded to the 5' of <scene name='10/100853/Deoxyribose/2'>D-2'-deoxyribose</scene> which is connected by a beta-glycosidic bond to a purine or a pyrimidine <scene name='10/100853/Base/2'>base</scene>. The <scene name='10/100853/Ribose_pucker/3'>ring pucker</scene> of ribose is a main determinant of which of the [[Forms of DNA]] is present. In this scene, which shows B DNA, the 2' carbon is out of the plane of the other members of the five membered ringIn <scene name='10/100853/3_endo_a_dna/2'>A form DNA</scene>, the 3' carbon is out of the plane of the ribose ring.
DNA consists of two polynucleotide chains, <scene name='DNA/B-dna/16'>twisted around each other to form a double helix</scene>. The nucleotide in DNA is composed of of a <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/19'>5' phosphorylated sugar</scene> which is a beta-D-2'- deoxyribose and a purine or a pyrimidine <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/18'>base</scene>.  The four types of bases are the two double ringed purine base <scene name='DNA/B-dna/18'>Adenine (A)</scene> and <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/2'>Guanine (G)</scene> and the two single pyrimidine bases <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/6'>Thymine (T)</scene> and <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/5'>Cytosine (C)</scene>.Each nucleotide in a DNA chain is linked to another via <scene name='User:Adithya_Sagar/Workbench/Retest/B-dna/2'>3',5' phosphodiester bond</scene>. There are four nucleotides in DNA.  The sugar-phosphate backbone of the DNA is very regular owing to the phosphodiester linkage whereas the ordering of bases is highly irregular.<ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref>
The four types of bases are the two double-ringed purine base <scene name='10/100853/B-dna/38'>Adenine (A)</scene> and <scene name='10/100853/B-dna/39'>Guanine (G)</scene> and the two single-ringed pyrimidine bases <scene name='10/100853/B-dna/40'>Thymine (T)</scene> and <scene name='10/100853/B-dna/41'>Cytosine (C)</scene>. Hydrogen atoms on some nitrogen and oxygen atom can undergo tautomeric shifts. The nitrogen atoms that are involved in forming tautomer appear as amino or imino groups and the oxygen atoms are either in keto or enol forms. Using an isolate thymine to illustrate the <scene name='DNA/Thymine_enol/1'>imino/enol tautomer</scene> and the <scene name='DNA/Thymine_keto/3'>amino/keto tautomer</scene>. There is a preference for the amino and keto forms which is very crucial for the biological functioning of DNA as it provides a <scene name='10/100853/Amino-glycosidic/2'>ring nitrogen capable of forming a glycosidic bond</scene> with the deoxyribose and it leads to the specificity of hydrogen bonding in base pairing and thus complementarity of the chains.<ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref> The imino nitrogen can only serve as a donating atom in hydrogen bonding, but the amino nitrogen can also serve as a receiving atom. Each nucleotide in a DNA chain is linked to another via <scene name='10/100853/Diester/3'>3',5' phosphodiester bond</scene>. There are four nucleotides in DNA.  The sugar-phosphate backbone of the DNA is very regular owing to the phosphodiester linkage whereas the ordering of bases is highly irregular.<ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref>
 
<scene name='DNA/B-dna/17'>Restore View</scene>
{| class="wikitable" align= "center''
{| class="wikitable" align= "center''
|-
|-
<scene name='DNA/B-dna/17'>Restore View</scene>
|}
|}
{{Template:Button Toggle NucleicDrumsColorScheme}}
{{Template:Button Toggle NucleicDrumsColorScheme}}
{{Template:ColorKey Bases DNA}}  
{{Template:ColorKey Bases DNA}}  
 
{| class="wikitable" align= "center''
|-
|}
{{Template:Button Toggle PurinePyrimidineDrumsColorScheme}}
{{Template:Button Toggle PurinePyrimidineDrumsColorScheme}}
{{Template:ColorKey Purines Pyrimidines}}
{{Template:ColorKey Purines Pyrimidines}}
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=== Complementary Bases ===
=== Complementary Bases ===


The two chains in a DNA are joined by hydrogen bonds between specific bases. Adenine forms base pairs with thymine and guanine with cytosine. This specific base pairing between <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/14'>Adenine-Thymine</scene> and <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/15'>Guanine-Cytosine</scene> is known as the Watson-Crick base pairing.  The specificity of hydrogen bonding between bases leads to complementarity in the sequence of nucleotides in the two chains. Thus in a strand of DNA the content of adenine is equal to that of thymine  and the guanine content is equal to the cytosine content.  In general DNA with higher GC content is more stable than the one with higher AT content owing to the stabilization due to base stacking interactions.
The two chains in a DNA are joined by hydrogen bonds between specific bases. Adenine forms base pairs with thymine and guanine with cytosine. This specific base pairing between <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/14'>Adenine-Thymine</scene> and <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/15'>Guanine-Cytosine</scene> is known as the Watson-Crick base pairing.  The specificity of hydrogen bonding between bases leads to complementarity in the sequence of nucleotides in the two chains.<ref name='structure'>A Structure for Deoxyribose Nucleic Acid
Watson J.D. and Crick F.H.C.
Nature 171, 737-738 (1953)</ref> Thus in a strand of DNA the content of adenine is equal to that of thymine  and the guanine content is equal to the cytosine content.  In general DNA with higher GC content is more stable than the one with higher AT content owing to the stabilization due to [[base stacking]] interactions.


=== DNA denaturation and renaturation ===
=== DNA denaturation and renaturation ===


A DNA double strand can be separated into two single strands by breaking the hydrogen bonds between them. This is known as DNA denaturation.  Thermal energy provided by heating can be used to melt or denature DNA. Molecules with rich GC content are more stable and thus denature at higher temperatures compared to the ones with higher AT content. The melting temperature is defined as the temperature at which half the DNA strands are in double helical state and half are in random coil state.<ref>PMID: 9465037</ref> The denatured DNA single strands have an ability to renature and form double stranded DNA again.
A DNA double strand can be separated into two single strands by breaking the hydrogen bonds between them. This is known as DNA denaturation.  Thermal energy provided by heating can be used to melt or denature DNA. Molecules with rich GC content are more stable and thus denature at higher temperatures compared to the ones with higher AT content. The melting temperature is defined as the temperature at which half the DNA strands are in double helical state and half are in random coil state.<ref>PMID: 9465037</ref> The denatured DNA single strands have an ability to renature and form double stranded DNA again.
&nbsp;
&nbsp;


=== Grooves ===
=== Grooves ===
<applet load='B-DNA.pdb' size='330' frame='true' align='left' caption='B-DNA' scene ='DNA/Bdnasf/1' />
In a <scene name='DNA/Bdnasf/1'>DNA double helix</scene> the <scene name='DNA/Angled_gylcosidic/5'>beta-glycosyl bonds</scene> of bases which are paired <scene name='DNA/Angled_gylcosidic/7'>do not lie opposite</scene> to each other but are positioned at an angle.  
In a DNA double helix the <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/16'>beta-glycosyl bonds</scene> between C<sub>1'</sub>-N<sub>1</sub> branch off from one side of the base pair and do not lie opposite to each other. This results in unequally spaced sugar-phosphate backbones and gives rise to two grooves: the
<scene name='DNA/B-dna/5'>major groove</scene> and the <scene name='User:Adithya_Sagar/Workbench_newDNA/B-dna/21'>minor groove</scene> of different width and depth. The minor groove is at the O<sub>2</sub> side of base pair and the major groove is on the opposite side.The floor of major groove is filled with nitrogen and oxygen atoms that project inward whereas in the minor groove they project outward. The larger size of major groove allows for the binding of DNA specific  proteins.<ref name="Saenger"> Saenger, Wolfram (1984). ''Principles of Nucleic Acid Structure '' (1st ed). Springer-Verlag. pp. 398. ISBN 0-12-645750-6.</ref><ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref>


[[Image:DNA grooves.png|200px]]


&nbsp;
This results in unequally spaced sugar-phosphate backbones and gives rise to <scene name='10/100853/Grooves/2'>two grooves</scene>: the
<scene name='DNA/Major_groove/2'>major groove</scene> and the <scene name='DNA/Major_groove/7'>minor groove</scene> of different width and depth. The <scene name='DNA/Major_groove/8'>oxygen atoms of the furanose rings</scene> are on the surface of the minor groove, and the major groove is on the opposite side. The floor or surface of major groove is filled with the <scene name='DNA/Major_floor/2'>atoms of the bases</scene>. The larger size of major groove allows for the binding of DNA specific  proteins.<ref name="Saenger"> Saenger, Wolfram (1984). ''Principles of Nucleic Acid Structure '' (1st ed). Springer-Verlag. pp. 398. ISBN 0-12-645750-6.</ref><ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref>


&nbsp;
== Biological Functions ==
''Sources:''<ref name='Rawn' > Rawn,David J. "Biochemistry"(1st ed.) Harper&Row,Publishers, Inc.pp. 1024-1050. ISBN-0-06045335-4</ref>


===Tautomeric forms of bases===
=== Replication===
DNA undergoes what is known as semi conservative mode of replication wherein the daughter DNA contains one DNA strand of the parent. The replication proceeds through the unwinding of double helix followed by synthesis primers from where the replication begins. An enzyme DNA polymerase synthesizes complementary strands to each parent strand from 5'-3' direction.


The hydrogen atoms on the bases move from nitrogen or oxygen atom on ring to another through shifts known as tautomeric shifts.  However the hydrogens have preferred atomic locations. Based on the movement of hydrogen atoms the nitrogen atoms are in amino or imino configuration and the oxygen atoms are either in keto or enol forms. There is a preference for the amino and keto forms respectively which is very crucial for the biological functioning of DNA as it leads to the specificity in base pairing and thus complementarity of the chains.<ref name='Watson'> Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner ''Molecular Biology of Gene'' (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8</ref>
===Transcription and Translation===
 
The expression of genes into proteins and is a process involving two stages called transcription and translation. In the transcription stage a strand of DNA molecule serves as a template for the synthesis of an RNA molecule called messenger RNA. This messenger RNA is then translated into proteins on ribosomes.
&nbsp;
 
&nbsp;


==Forms of DNA==
==Forms of DNA==
''See Also: [[Z-DNA]]''
For a comparison of the different forms of DNA, see [[forms of DNA]].


&nbsp;
== History of DNA Structure ==


&nbsp;
The following summary is copied from an [http://atlas.molviz.org Atlas of Macromolecules] with permission:


=== A comparative representation of the three forms of DNA ===
:Genes were shown to reside in DNA in 1944 (Avery et al.) and this became widely accepted after the 1952 experiments of Hershey and Chase. The double helical structure of the DNA was predicted by James Watson and Francis Crick in 1953 (Nobel Prize, 1962). Their prediction was based in part upon X-ray diffraction studies by Rosalind Franklin, to whom Watson and Maurice Wilkins gave inadequate credit<ref>Maddox, Brenda: ''Rosalind Franklin: Dark Lady of DNA'', HarperCollins, 2002</ref>. The predicted B-form double helix was not confirmed with atomic-resolution crystal structures until 1973, first by using dinucleotides of RNA (Rosenberg et al.). The first crystal structure containing more than a full turn of the double helix was not solved until 1980 ([[1bna]], 1981, 12 base pairs). The lag of more than a quarter century between prediction and empirical confirmation involved development of [[X-ray crystallography]] for macromolecules, and the need to produce a short, defined sequence of DNA for crystallization. This brief account is based upon a review by Berman, Gelbin, and Westbrook <ref>PMID: 9284453</ref>, where the references will be found.
''Sources''<ref>http://203.129.231.23/indira/nacc/</ref>
<applet load='A-DNA.pdb' name='A' size='350' frame='true' align='right' caption='A-DNA' align='left' scene='User:Adithya_Sagar/Sandbox_DNA/A-dna/1'/>
<applet load='B-DNA.pdb' name='B' size='350' frame='true' align='right' caption='B-DNA' align='left' scene='User:Adithya_Sagar/Sandbox_DNA/B-dna/3'/>
<applet load='Z-DNA.pdb' name='Z' size='350' frame='true' align='right' caption='Z-DNA' align='left' scene='User:Adithya_Sagar/Sandbox_DNA/Z-dna/1'/>


{{Clear}}
== DNA Models ==
<center>
'''Synchronize the three applets showing A-, B- and Z-DNA by clicking the checkbox'''
<jmol>
  <jmolCheckbox>
    <target>A</target>
    <!--<scriptWhenChecked>set syncMouse ON;set syncScript OFF;sync jmolAppletB,jmolAppletZ; sync > "set syncMouse
ON;set syncScript OFF"</scriptWhenChecked>-->
            <scriptWhenChecked> sync jmolAppletB,jmolAppletZ </scriptWhenChecked>
    <scriptWhenUnchecked> sync OFF</scriptWhenUnchecked>
    <text> Synchronize</text>
</jmolCheckbox>
</jmol>
</center>


{{Clear}}
The model of DNA used in the scenes in the present article is a theoretical model<ref>PMID: 8832384</ref> ([[Image:B-DNA.pdb]]), not available in the [[Protein Data Bank]]. The [[PDB file]] does not follow certain PDB format conventions:
* Bases are designated ADE, CYT, GUA, and THY instead of the standard DA, DC, DG and DT.
* The chains are not named. Typically they would be named A and B.


=== Helical Parameters of the three forms of DNA ===
One chain contains residues numbered 1-12 in sequence CGCG AATT CGCG. The other chain contains residues numbered 13-24 with an identical (antiparallel) sequence.


DNA is a very flexible molecule and has the ability to exist in various forms based on the environmental conditions. Naturally occurring DNA double helices are classified into A, B and Z-types. A and B-forms of DNA are the right handed forms whereas [[Z-DNA]] is the left handed form. When hydrated the DNA generally assumes B-form. The A conformation is found when there is little water to interact with the helix and is also the conformation adopted by the RNA. The formation of Z-DNA occurs with the methylation of  deoxycytosine residues and also during transcription where negative supercoiling stabilizes it.
Theoretical models typically represent idealized DNA conformation, whereas real DNA may have various irregularities including kinks and bends (see examples bound to the [[Lac repressor]]). There are plenty of empirical models for DNA, the first having become available in the 1970's and 80's (see [[#History of DNA Structure|above]]). In May, 2012, the [[Protein Data Bank]] contains nearly 4,000 entries containing DNA. Over 1,300 contain only DNA, while over 2,000 contain protein-DNA complexes. Over 100 entries contain protein, DNA and [[RNA]], and over 100 contain DNA/RNA hybrid molecules.


{| class="wikitable" align= "center''
For more interactive visualizations of DNA, see [http://dna.molviz.org DNA.MolviZ.Org], a tutorial that is available in [http://biomodel.uah.es/model4/dna/ nine languages].
|-
!Parameter
!A-DNA
!B-DNA
!Z-DNA
|-
|Helix sense ||align="center"| right-handed ||align="center"| right-handed ||align="center"| left-handed
|-
|Residues per turn ||align="right"| 11 ||align="right"| 10.5 ||align="right"| 12
|-
|Axial rise [Å] ||align="right"| 2.55 ||align="right"| 3.4 ||align="right"| 3.7
|-
|Helix pitch(°) ||align="right"| 28 ||align="right"| 34 ||align="right"| 45
|-
|Base pair tilt(°) ||align="right"| 20 ||align="right"| −6 ||align="right"| 7
|-
|Rotation per residue (°) ||align="right"| 33||align="right"| 36||align="right"|-30
|-
|Diameter of helix [Å]||align="right"| 23||align="right"| 20||align="right"| 18
|-
|Glycosidic bond configuration<br\>dA,dT,dC<br\>dG ||align="center"| <br\>anti<br\>anti ||align="center"| <br\>anti<br\>anti ||align="center"| <br\>anti<br\>syn
|-
|Sugar pucker<br\>dA,dT,dC<br\>dG ||align="center"| <br\>C3'-endo<br\>C3'-endo ||align="center"|<br\> C2'-endo<br\>C2'-endo ||align="center"| <br\>C2'-endo<br\>C3'-endo
|-
|Intrastrand phosphate-phosphate distance [Å] <br\>dA,dT,dC<br\>dG ||align="center"| <br\>5.9<br\>5.9||align="center"| <br\>7.0<br\>7.0||align="center"| <br\>7.0<br\> 5.9
|-
|colspan="4"|''Sources:<ref name="Rich1984">PMID:6383204</ref><ref name="Rich1979">PMID: 514347</ref><ref> Sinden, Richard R (1994-01-15). ''DNA structure and function'' (1st ed.). Academic Press. pp. 398. ISBN 0-12-645750-6.</ref>
|}


== Structural Transformation between A and B DNA ==
</StructureSection>
 
<!-- Generation of smooth transition between animated morphs each of which depicts a different change-->
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<text>Click here and activate the below options </text>
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    <text>Change in Sugar Puckering from C2' endo in B-DNA to C3' endo in A-DNA</text>
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<text>Shift in Base Pair between A-B DNA</text>
</item>
  <item>
  <script> moveto 1.0 0 0 1 0 400.0 0.0 0.0; restore state ab;cartoon OFF;spacefill ON; spacefill 90; wireframe ON; wireframe 50;select 9:a; select!selected; color translucent 0.9; select!selected; centre selected;zoom 400;set echo bottom centre;font echo 20 serif bolditalic;color echo green; echo"Change in Sugar Puckering from C2' endo in B-DNA to C3' endo in A-DNA"</script>
    <text>Change in Sugar Puckering from C2' endo in B-DNA to C3' endo in A-DNA</text>
  </item>
  <item>
  <script>moveto 1.0 0 0 1 0 150.0 0.0 0.0;restore state ab;spacefill ON; spacefill 400; zoom 150; cartoon OFF;animation ON; animation mode PALINDROME;set echo bottom centre;font echo 20 serif bolditalic;color echo green; echo"Transition between A-B DNA spacefilling models"</script>
    <text>Transition between A-B DNA spacefilling models</text>
  </item>
  </jmolRadioGroup>
</jmol>
 
<jmol>
<jmolButton>
<target>6</target>
<script>moveto 1.0 0 0 1 0 100.0 0.0 0.0;load/wiki/images/5/50/Morph_test.pdb;animation ON; animation mode PALINDROME; cartoon ON;save state ab</script>
<text>Restore Original State </text>
</jmolButton>
</jmol>-->
 
''Morph Sources'' <ref>PMID: 10734184</ref>
 
 
<!-- Problems with script synchronization
<jmol>
  <jmolButton>
  <target>0</target>
    <script>sync jmolApplet1; sync * "geoSurface ON" ; sync* geoSurface vdw</script>
        <script>geoSurface ON; geoSurface vdw; color opaque cpk</script>
                  <script>spacefill ON; spacefill 600; hide all;color opaque cpk</script>
    <text>Spacefilling Model</text>
  </jmolButton>
</jmol>
 
Problems with script synchronization
<jmol>
  <jmolButton>
  <target>0</target>
  <script>sync jmolApplet1; sync "geoSurface OFF"</script>
            <script>geoSurface OFF</script>
    <text>Vanderwaals Surface OFF</text>
  </jmolButton>
</jmol>-->
 
== Biological Functions ==
''Sources:''<ref name='Rawn' > Rawn,David J. "Biochemistry"(1st ed.) Harper&Row,Publishers, Inc.pp. 1024-1050. ISBN-0-06045335-4</ref>
 
=== Replication===
DNA undergoes what is known as semi conservative mode of replication wherein the daughter DNA contains one DNA strand of the parent. The replication proceeds through the unwinding of double helix followed by synthesis primers from where the replication begins. An enzyme DNA polymerase synthesizes complementary strands to each parent strand from 5'-3' direction.
 
===Transcription and Translation===
The expression of genes into proteins and is a process involving two stages called transcription and translation. In the transcription stage a strand of DNA molecule serves as a template for the synthesis of an RNA molecule called messenger RNA. This messenger RNA is then translated into proteins on ribosomes.


__NOTOC__
== See Also ==
== See Also ==
===Proteopedia Articles===
*[[Forms of DNA]]
* Kinks vs. Bends in DNA are discussed in [[Lac repressor]].
* [[User:Karsten Theis/DNA bulges|DNA bulges]] occur when a nucleotide is inserted in one strand but not the other, causing an interruption in base pairing.
*[[1ply]]
*[[1ply]]
*[[DNA Replication, Repair, and Recombination]] - Articles in Proteopedia concerning DNA Replication, Repair, and/or Recombination
*[[DNA Replication, Repair, and Recombination]] - Articles in Proteopedia concerning DNA Replication, Repair, and/or Recombination
*[[DNA Replication,Transcription and Translation]]
*[[DNA Replication,Transcription and Translation]]
*[[Z-DNA]]
*[[Z-DNA]]
*[[1ehz|Transfer ribonucleic acid (tRNA)]]
*[[tRNA|Transfer ribonucleic acid (tRNA)]]
* For additional information, see: [[Nucleic Acids]]
* For additional information, see: [[Nucleic Acids]]
===External Resources===
* [http://dna.molviz.org DNA.MolviZ.Org], an interactive DNA Structure tutorial that is available in [http://biomodel.uah.es/model4/dna/ nine languages].
* [http://bioinformatics.org/molvis/atlas/atlas.htm#dnarna DNA / RNA Section of the Atlas of Macromolecules].
====Interpretation of X-Ray Diffraction by DNA====
* [http://www-tc.pbs.org/wgbh/nova/photo51/media/anatomy.swf Anatomy of Photo 51], Rosalind Franklin's diffraction pattern used by Watson & Crick in developing their model of the DNA double helix (at PBS.Org, US Public Broadcasting System).
* [http://www.dnalc.org/view/15014-Franklin-s-X-ray-diffraction-explanation-of-X-ray-pattern-.html Explanation of Franklin's X-Ray Diffraction Pattern] at Cold Spring Harbor Laboratory, USA.
* More technical: [http://homepages.ius.edu/kforinas/P105/PTE000140.pdf How Rosalind Franklin Discovered the Helical Structure of DNA: Experiments in Diffraction].


== References==
== References==
<references/>
<references/>


<!--Adithya Sagar-->
[[Category:Featured in BAMBED]]

Latest revision as of 18:17, 26 February 2025

This page, as it appeared on August 20, 2011, was featured in this article in the journal Biochemistry and Molecular Biology Education.


Deoxyribonucleic acid or DNA is a molecule which is the carrier of genetic information in nearly all the living organisms. It contains the biological instructions for the development, survival and reproduction of organisms. DNA is found in the nucleus of a cell where it is packaged into a compact form called a chromosome with the help of several proteins known as histones. It is also found in cell structures called mitochondria. However in case of prokaryotes DNA is not enclosed in a nucleus or a membrane but is present in the cytoplasm. The DNA in prokaryotes in generally circular and supercoiled without any histones. DNA stores genetic information as a sequence of nucleotides in special regions known as genes which are used to make proteins. The expression of genetic information into proteins is a two-stage process wherein the sequence of nucleotides in DNA is converted to a molecule called Ribonucleic acid or RNA by a process called transcription. RNA is used to make proteins by another process called translation. The human genome contains nearly 3 · 109 bases with around 20,000 genes on 23 chromosomes. [1]

DNA was first discovered by the German biochemist Frederich Miescher in the year 1869.[2] Based on the works of Erwin Chargaff, James Watson, Francis Crick, Maurice Wilkins and Rosalind Franklin, the structure of DNA was discovered in the year 1953. The structure of DNA is a : two complementary strands of polynucleotides that run in opposite directions and are held together by hydrogen bonds between them.[3] This structure helps the DNA replicate itself during cell division and also for a single strand to serve as template during transcription. [1]

Features of a DNA Molecule

Double Helix

consists of two polynucleotide chains, . The in DNA is composed of a bonded to the 5' of which is connected by a beta-glycosidic bond to a purine or a pyrimidine . The of ribose is a main determinant of which of the Forms of DNA is present. In this scene, which shows B DNA, the 2' carbon is out of the plane of the other members of the five membered ring. In , the 3' carbon is out of the plane of the ribose ring.

The four types of bases are the two double-ringed purine base and and the two single-ringed pyrimidine bases and . Hydrogen atoms on some nitrogen and oxygen atom can undergo tautomeric shifts. The nitrogen atoms that are involved in forming tautomer appear as amino or imino groups and the oxygen atoms are either in keto or enol forms. Using an isolate thymine to illustrate the and the . There is a preference for the amino and keto forms which is very crucial for the biological functioning of DNA as it provides a with the deoxyribose and it leads to the specificity of hydrogen bonding in base pairing and thus complementarity of the chains.[4] The imino nitrogen can only serve as a donating atom in hydrogen bonding, but the amino nitrogen can also serve as a receiving atom. Each nucleotide in a DNA chain is linked to another via . There are four nucleotides in DNA. The sugar-phosphate backbone of the DNA is very regular owing to the phosphodiester linkage whereas the ordering of bases is highly irregular.[4]

A C G T

Purines Pyrimidines

Complementary Bases

The two chains in a DNA are joined by hydrogen bonds between specific bases. Adenine forms base pairs with thymine and guanine with cytosine. This specific base pairing between and is known as the Watson-Crick base pairing. The specificity of hydrogen bonding between bases leads to complementarity in the sequence of nucleotides in the two chains.[3] Thus in a strand of DNA the content of adenine is equal to that of thymine and the guanine content is equal to the cytosine content. In general DNA with higher GC content is more stable than the one with higher AT content owing to the stabilization due to base stacking interactions.

DNA denaturation and renaturation

A DNA double strand can be separated into two single strands by breaking the hydrogen bonds between them. This is known as DNA denaturation. Thermal energy provided by heating can be used to melt or denature DNA. Molecules with rich GC content are more stable and thus denature at higher temperatures compared to the ones with higher AT content. The melting temperature is defined as the temperature at which half the DNA strands are in double helical state and half are in random coil state.[5] The denatured DNA single strands have an ability to renature and form double stranded DNA again.

Grooves

In a the of bases which are paired to each other but are positioned at an angle.

File:DNA grooves.png

This results in unequally spaced sugar-phosphate backbones and gives rise to : the

and the of different width and depth. The are on the surface of the minor groove, and the major groove is on the opposite side. The floor or surface of major groove is filled with the . The larger size of major groove allows for the binding of DNA specific proteins.[6][4]

Biological Functions

Sources:[7]

Replication

DNA undergoes what is known as semi conservative mode of replication wherein the daughter DNA contains one DNA strand of the parent. The replication proceeds through the unwinding of double helix followed by synthesis primers from where the replication begins. An enzyme DNA polymerase synthesizes complementary strands to each parent strand from 5'-3' direction.

Transcription and Translation

The expression of genes into proteins and is a process involving two stages called transcription and translation. In the transcription stage a strand of DNA molecule serves as a template for the synthesis of an RNA molecule called messenger RNA. This messenger RNA is then translated into proteins on ribosomes.

Forms of DNA

For a comparison of the different forms of DNA, see forms of DNA.

History of DNA Structure

The following summary is copied from an Atlas of Macromolecules with permission:

Genes were shown to reside in DNA in 1944 (Avery et al.) and this became widely accepted after the 1952 experiments of Hershey and Chase. The double helical structure of the DNA was predicted by James Watson and Francis Crick in 1953 (Nobel Prize, 1962). Their prediction was based in part upon X-ray diffraction studies by Rosalind Franklin, to whom Watson and Maurice Wilkins gave inadequate credit[8]. The predicted B-form double helix was not confirmed with atomic-resolution crystal structures until 1973, first by using dinucleotides of RNA (Rosenberg et al.). The first crystal structure containing more than a full turn of the double helix was not solved until 1980 (1bna, 1981, 12 base pairs). The lag of more than a quarter century between prediction and empirical confirmation involved development of X-ray crystallography for macromolecules, and the need to produce a short, defined sequence of DNA for crystallization. This brief account is based upon a review by Berman, Gelbin, and Westbrook [9], where the references will be found.

DNA Models

The model of DNA used in the scenes in the present article is a theoretical model[10] (File:B-DNA.pdb), not available in the Protein Data Bank. The PDB file does not follow certain PDB format conventions:

  • Bases are designated ADE, CYT, GUA, and THY instead of the standard DA, DC, DG and DT.
  • The chains are not named. Typically they would be named A and B.

One chain contains residues numbered 1-12 in sequence CGCG AATT CGCG. The other chain contains residues numbered 13-24 with an identical (antiparallel) sequence.

Theoretical models typically represent idealized DNA conformation, whereas real DNA may have various irregularities including kinks and bends (see examples bound to the Lac repressor). There are plenty of empirical models for DNA, the first having become available in the 1970's and 80's (see above). In May, 2012, the Protein Data Bank contains nearly 4,000 entries containing DNA. Over 1,300 contain only DNA, while over 2,000 contain protein-DNA complexes. Over 100 entries contain protein, DNA and RNA, and over 100 contain DNA/RNA hybrid molecules.

For more interactive visualizations of DNA, see DNA.MolviZ.Org, a tutorial that is available in nine languages.


The double-helical structure of B-DNA, shown as ball-and-stick (colored by element C H O N P) with the helical conformation of the sugar-phosphate shown as orange ribbon, and the planes of the nucleobases (drag down in the viewer to see them) in orange as well.

Drag the structure with the mouse to rotate


See AlsoSee Also

Proteopedia ArticlesProteopedia Articles

External ResourcesExternal Resources

Interpretation of X-Ray Diffraction by DNAInterpretation of X-Ray Diffraction by DNA

ReferencesReferences

  1. 1.0 1.1 http://www.genome.gov/25520880
  2. Dahm R. Discovering DNA: Friedrich Miescher and the early years of nucleic acid research. Hum Genet. 2008 Jan;122(6):565-81. Epub 2007 Sep 28. PMID:17901982 doi:10.1007/s00439-007-0433-0
  3. 3.0 3.1 A Structure for Deoxyribose Nucleic Acid Watson J.D. and Crick F.H.C. Nature 171, 737-738 (1953)
  4. 4.0 4.1 4.2 Watson, James D, Nancy H. Hopkins, Jeffrey W. Roberts, Joan Argetsinger Steitz, Alan M.Weiner Molecular Biology of Gene (4th ed.). The Benjamin/Cummings Publishing Company Inc.pp. 239-249. ISBN 0-8053-9612-8
  5. SantaLucia J Jr. A unified view of polymer, dumbbell, and oligonucleotide DNA nearest-neighbor thermodynamics. Proc Natl Acad Sci U S A. 1998 Feb 17;95(4):1460-5. PMID:9465037
  6. Saenger, Wolfram (1984). Principles of Nucleic Acid Structure (1st ed). Springer-Verlag. pp. 398. ISBN 0-12-645750-6.
  7. Rawn,David J. "Biochemistry"(1st ed.) Harper&Row,Publishers, Inc.pp. 1024-1050. ISBN-0-06045335-4
  8. Maddox, Brenda: Rosalind Franklin: Dark Lady of DNA, HarperCollins, 2002
  9. Berman HM, Gelbin A, Westbrook J. Nucleic acid crystallography: a view from the nucleic acid database. Prog Biophys Mol Biol. 1996;66(3):255-88. PMID:9284453
  10. Chandrasekaran R, Arnott S. The structure of B-DNA in oriented fibers. J Biomol Struct Dyn. 1996 Jun;13(6):1015-27. PMID:8832384

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Ala Jelani, Eran Hodis, Eric Martz, Joel L. Sussman, Adithya Sagar, Wayne Decatur, David Canner, Angel Herraez, Frédéric Dardel, Karl Oberholser, Joseph M. Steinberger, Alexander Berchansky, Ann Taylor, Karsten Theis
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