Nucleic acids, Study notes of Genetics

Deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are made up of nucleic acids found in the nuclei of living cells. They are the vehicles of genetic ...

Typology: Study notes

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Nucleic acids
Deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are made up of nucleic acids found in the
nuclei of living cells. They are the vehicles of genetic inheritance.
Nucleic acids are condensation polymers of nucleotides. To understand their functions you will find it
helpful to look at how their molecules are built up and the structures of these molecules.
The building blocks
Three types of chemicals make up the building blocks for nucleic acids.
Phosphates
These are based on the inorganic acid H3PO4 (phosphoric acid).
Phosphoric acid
Two other acids may be formed from phosphoric acid by condensation reactions
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Nucleic acids

Deoxyribonucleic acid (DNA) and ribonucleic acid (RNA) are made up of nucleic acids found in the nuclei of living cells. They are the vehicles of genetic inheritance.

Nucleic acids are condensation polymers of nucleotides. To understand their functions you will find it helpful to look at how their molecules are built up and the structures of these molecules.

The building blocks

Three types of chemicals make up the building blocks for nucleic acids.

Phosphates

These are based on the inorganic acid H 3 PO 4 (phosphoric acid).

Phosphoric acid

Two other acids may be formed from phosphoric acid by condensation reactions

Two important reactions of the hydroxyl groups in phosphoric acid are:

  • with alcohols to form ester groups
  • with amines to form amide groups

Sugars

The sugars in DNA and RNA are pentoses.

> See the topic about Carbohydrates

  • in DNA the sugar is deoxyribose
  • in RNA the sugar is ribose

Both these sugars have hydroxyl groups. Ribose has four and deoxyribose has three (hence the prefix 'deoxy'). These groups can react with carboxylic acids and phosphoric acid to form esters.

Deoxyribose (hydrogens not shown for clarity) Ribose (hydrogens not shown for clarity)

Adenine Guanine

Thymine Cytosine

In RNA the four bases are the same except for thymine which is replaced by uracil (U), a pyrimidine base.

Uracil

Adenine, guanine, thymine, cytosine and uracil are bases because of the presence of one or more of the following groups: - NH 2 , - NH - and = N - groups. Importantly, - NH 2 and - NH - groups can react with carboxylic acids and phosphoric acid to form amides.

Putting the building blocks together

The basic structure of a nucleotide is shown below.

In all nucleotide molecules the bonds holding the phosphate group to the sugar and the base to the sugar are both products of condensation reactions. Water is eliminated when they form. In both cases the oxygen to form the water has come from the sugar's -OH groups.

Nucleic acids

Nucleotides can link together by the formation of phosphate ester bonds. The hydroxyl group of a phosphate on one nucleotide undergoes a condensation reaction with the hydroxyl group on the carbohydrate ring of another nucleotide. The process may continue, building up nucleic acid molecules. These are polymers called polynucleotides.

Nucleic acids are the 'building blocks' of DNA and RNA.

The structure of DNA

DNA is formed from two polynucleotide chains. Each chain has a helical structure (a helix), in other words the molecule is coiled like a spring.

The two helices are then intertwined to give a double helix. The bases are on the inside of the helix and the phosphate groups are on the outside.

The two helices are held together by pairing of the nucleotides' bases through hydrogen bonding. Because the double ring purines are bigger than the single ring pyrimidines the structure can only form with purine bases opposite pyrimidine bases. A big one complements a little one to take up about the same space.

The structure is sometimes described as a ladder where the sugar-phosphate chains are the sides of the ladder and the base-base bonds are the rungs. Intermolecular forces twist the ladder into a double helix shape.

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