2.6 Structure of DNA and RNA
Essential idea: The structure of DNA allows efficient storage of genetic information.
Embedded Files
2.6.U1 The nucleic acids DNA and RNA are polymers of nucleotides.
2.6.U1 The nucleic acids DNA and RNA are polymers of nucleotides.
Be able to:
- State the two types of nucleic acid.
- State the two types of nucleic acid.
- Outline the parts of a nucleotide.
- Identify and label carbons by number (for example, C1, C2, C3) on a nucleotide drawing.
- Explain how nucleotides can connect to form a nucleic acid polymer.
- State the names of the nitrogenous bases found in DNA and RNA.
- Identify nitrogenous bases as either a pyrimidine or purine.
- State the complementary base pairing rules.
Nucleotides consist of three parts:
Nucleotides consist of three parts:
Sugar has five carbon atoms meaning it a pentose sugar
a phosphate group, acidic, negatively-charged part of nucleic acids
base that contains nitrogen and has either one or two rings of atoms in it’s structure
Both the phosphate group and nitrogenous base are attached to the central pentose sugar
The nitrogenous base is attached to the 1’– carbon atom (right point)
The phosphate base is attached to the 5’– carbon atom (left point)
The base and phosphate are both linked together by covalent bonds to the pentose sugar.
covalent bonds are formed between the phosphate of one nucleotide and the pentose sugar of the next nucleotide, creating a strong backbone for the molecule of alternating sugar and phosphate groups, with a base linked to each sugar
different bases in both DNA & RNA = Four different nucleotides
The four different nucleotides can be linked together in any sequence because the phosphate and sugar used to link them are the same in every nucleotide. Any base sequence is possible along a DNA or RNA molecule.
This is the key to nucleic acids acting as a store of genetic information. Base sequence = store of information. Sugar phosphate backbone = ensures that the store is stable and secure
2.6.U2 DNA differs from RNA in the number of strands present, the base composition and the type of pentose.
2.6.U2 DNA differs from RNA in the number of strands present, the base composition and the type of pentose.
Be able to:
- Compare the structure of DNA and RNA.
There are two types of nucleic acids present in cells – DNA and RNA
DNA (deoxyribonucleic acid) is a more stable double stranded form that stores the genetic blueprint for cells
RNA (ribonucleic acid) is a more versatile single stranded form that transfers the genetic information for decoding
2.6.U3 DNA is a double helix made of two antiparallel strands of nucleotides linked by hydrogen bonding between complementary base pairs.
2.6.U3 DNA is a double helix made of two antiparallel strands of nucleotides linked by hydrogen bonding between complementary base pairs.
Be able to:
- Define antiparallel in relation to DNA structure.
- Outline the formation of a DNA double helix by hydrogen bonding between nitrogenous bases.
- Identify the four bases of DNA based on the numbers of rings (purines or pyrimidines) and the number of hydrogen bonds it can form.
- State the number of nitrogenous bases per complete turn of the DNA double helix.
Nucleic acids are composed of nucleotide monomers which are linked into a single strand via condensation reactions
The phosphate group of one nucleotide attaches to the sugar of another nucleotide (at the 3’– hydroxyl (-OH) group)
This results in a phosphodiester bond forming between the two nucleotides (and water is produced as a by-product)
Successive condensation reactions result in the formation of long polynucleotide strands
Each strand has a chain of nucleotides linked by covalent bonds, two strands are parallel but run in opposite directions so they are antiparallel. As the antiparallel chains lengthen, the atoms will organise themselves into the most stable energy configuration. This atomic arrangement results in the double-stranded DNA forming a double helix (~10 – 15 bases per twist)
The strands are held together by hydrogen bonds between the nitrogenous bases
Adenine (A) & thymine (T)
Guanine (G) & cytosine (C)
This is called complementary base pairing – A and T complement each other by forming base pairs and same with G and C
2.6.A1 Crick and Watson’s elucidation of the structure of DNA using model making.
2.6.A1 Crick and Watson’s elucidation of the structure of DNA using model making.
Be able to:
- Outline the role of Chargaff, Watson, Crick, Franklin and Wilkins in the discovery of DNA structure.
- Explain how Watson and Crick used model building to determine the structure of DNA.
The structural organisation of the DNA molecule was correctly proposed in 1953 by James Watson and Francis Crick. These scientists constructed models to quickly visualise and assess the viability of potential structures. Their efforts were guided by an understanding of molecular distances and bond angles developed by Linus Pauling, and were based upon some key experimental discoveries:
DNA is composed of nucleotides made up of a sugar, phosphate and base – Phoebus Levene, 1919
DNA is composed of an equal number of purines (A + G) and pyrimidines (C + T) – Erwin Chargaff, 1950
DNA is organised into a helical structure – Rosalind Franklin, 1953 (data shared without permission)
Making DNA Models
Using trial and error, Watson and Crick were able to assemble a DNA model that demonstrated the following:
DNA strands are antiparallel and form a double helix
DNA strands pair via complementary base pairing (A = T ; C Ξ G)
Outer edges of bases remain exposed (allows access to replicative and transcriptional proteins)
The Rosalind Franklin Controversy
The final construction of a correct DNA molecule owed heavily to the X-ray crystallography data generated by Rosalind Franklin. This data confirmed the arrangement of the DNA strands into a helical structure. The data was shared without Franklin’s knowledge or permission and contributed profoundly to the final design. Hence, Franklin is now recognized as a key contributor to the elucidation of DNA structure
As Watson and Crick’s model building was based on trial and error, a number of early models possessed faults:
The first model generated was a triple helix
Early models had bases on the outside and sugar-phosphate residues in the centre
Nitrogenous bases were not initially configured correctly and hence did not demonstrate complementary
2.6.S1 Drawing simple diagrams of the structure of single nucleotides of DNA and RNA, using circles, pentagons and rectangles to represent phosphates, pentoses and bases.
2.6.S1 Drawing simple diagrams of the structure of single nucleotides of DNA and RNA, using circles, pentagons and rectangles to represent phosphates, pentoses and bases.
Be able to:
Draw the basic structure of a single nucleotide (using circle, pentagon and rectangle).
Draw a simple diagram of the structure of RNA.
Draw a simple diagram of the structure of DNA.
Identify and label the 5’ and 3’ ends on a DNA or RNA diagram
Both the phosphate group and nitrogenous base are attached to the central pentose sugar
The nitrogenous base is attached to the 1’– carbon atom (right point)
The phosphate base is attached to the 5’– carbon atom (left point)Circles for phosphate
pentagons for pentose sugar
rectangles for bases
C, carbon atom is on the right hand side of the pentose sugar
phosphate is linked to C5, the carbon atom on the side chain on the upper left side of the pentose sugar
Nature of science
Nature of science
Using models as representation of the real world—Crick and Watson used model making to discover the structure of DNA.
Be able to:
List types of models used in science.
State a common feature of models in science.
List ways in which models are different from the structure or process it represents.
Report abuse