Nucleic Acid Structure & Function (DP IB Biology)
Revision Note
DNA & RNA: Comparison
Differences between DNA and RNA
Unlike DNA, RNA nucleotides never contain the nitrogenous base thymine (T) – in place of this they contain the nitrogenous base uracil (U)
Unlike DNA, RNA nucleotides contain the pentose sugar ribose (instead of deoxyribose)
Comparing DNA and RNA nucleotides diagram
An RNA nucleotide compared with a DNA nucleotide
Unlike DNA, RNA molecules are only made up of one polynucleotide strand (they are single-stranded)
Unlike DNA, RNA polynucleotide chains are relatively short compared to DNA
RNA structure
mRNA as an example of the structure of an RNA molecule
Nucleotide Structure Summary Table
Properties | DNA | RNA |
|---|---|---|
Pentose sugar | Deoxyribose | Ribose |
Bases | Adenine (A) | Adenine (A) |
Number of strands | Double-stranded (double helix) | Single-stranded |
Examiner Tips and Tricks
You need to know the difference between DNA and RNA molecules (base composition, number of strands, pentose sugar present). You also need to be able to sketch the difference between ribose and deoxyribose.
Complementary Base Pairing
The role of complementary base pairing
Complementary base pairing means that the DNA bases on different strands will always pair up in a very specific way:
Adenine (A) will pair up with Thymine (T)
Cytosine (C) will pair up with Guanine (G)
This is because the hydrogen bonds that hold the two DNA strands together can only form between these base pairs:
Two hydrogen bonds form between A and T
Three hydrogen bonds form between C and G
Complementary base pairing means that the base sequence on one DNA strand determines the sequence of the other strand
We say that one strand acts as a template of the other
This allows DNA to be copied very precisely during DNA replication which in turn ensures that the genetic code is accurately copied and expressed in newly formed cells
Complementary base pairs and hydrogen bonding diagram
A section of DNA showing nucleotide bonding and complementary base pair bonding
DNA: Information Storage Molecule
Diversity of DNA base sequences
Despite the genetic code only containing four bases (A, T, C, G), they can combine to form a very diverse range of DNA base sequences in DNA molecules of different lengths
This means that DNA has an almost limitless capacity for storing genetic information in living organisms
One way in which this storage capacity can be measured is by the number of genes contained within the DNA of an organism
Even the most simplistic forms of life may contain several thousand genes within their DNA
Comparing the Number of Genes between Different Organisms Table
Organism | Human | Dog | Water flea | Bacterium | Rice plant |
|---|---|---|---|---|---|
Approximate number of genes | 20 000 | 19 000 | 31 000 | 4 300 | 41 500 |
The storage capacity of DNA can also be measured in the number of base pairs contained within the genome of an organism
The DNA in the nucleus of a human cell contains about 3.2 gigabases
That is about 109 DNA base pairs
These base pairs are contained in DNA with a length of about 2 meters, that fits within the nucleus of each human cell
Given the fact that a nucleus is microscopic in size, is an indication of how incredibly well packaged this amount of genetic information is
This gives DNA an enormous capacity for storing genetic 'data' with great economy
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