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Introduction to nucleotides
Nucleotides are nitrogen-containing organic substances that form the basis of the nucleic acids DNA and RNA.
All nucleotides contain the following three groups:
In DNA the sugar is deoxyribose, whereas in RNA the sugar is ribose.
a phosphate group
a pentose sugar
a nitrogen-containing base
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Bases
There are five bases, split into two types:
adenine (A) and guanine (G) are purine bases.
A G
T U
thymine (T), cytosine (C) and uracil (U) are pyrimidine bases.
DNA contains A, G, T and C, whereas RNA contains A, G, U and C.
C
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Identifying bases
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Base pairing rules
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Formation of nucleotides
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Formation of polynucleotides
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Determining the structure of DNA
The double-stranded structure of DNA was determined in 1953 by the American biologist James Watson and the British physicist Francis Crick.
X-ray diffraction studies by British biophysicist Rosalind Franklin strongly suggested that DNA was a helical structure.
The Austrian chemist Erwin Chargraff had earlier showed that DNA contained a 1:1 ratio of pyrimidine:purine bases.
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Structure of DNA
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How is DNA packaged?
In eukaryotic cells, DNA is packaged as chromosomes in the nucleus.
In prokaryotic cells, DNA is loose in the cytoplasm – there are no histones or chromosomes.
There is around 2 m of DNA in a cell, so to fit it needs to be tightly coiled and folded.
Eukaryotic DNA is associated with proteins called histones. Together, these form chromatin – the substance from which chromosomes are made.
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Structure of eukaryotic chromosomes
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DNA replication
The discovery of DNA’s structure by Watson and Crick provided evidence that complementary base pairing was key to DNA’s ability to replicate.
New polynucleotide strands could then be synthesized using the originals as a template.
Several hypotheses were proposed as to the specific mechanism by which new strands are created.
Scientists proposed that DNA ‘unzipped’ as hydrogen bonds between base pairs were broken.
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Mechanisms of DNA replication
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Meselson–Stahl DNA experiment
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DNA replication
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DNA replication enzymes
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DNA replication
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Errors in replication: gene mutations
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The genetic code: timeline
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What is the genetic code?
The genetic code of an organism is the sequence of bases along its DNA. It contains thousands of sections called genes or cistrons. Each gene codes for a specific polypeptide.
All polypeptides are made from amino acids, so the sequence of bases in a gene must code for amino acids.
The genetic code is almost universal – the same sequence of bases codes for the same amino acids in all organisms.
one gene/cistron
thousands more bases in gene (not shown)
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The triplet code
Given that there are four bases in DNA, and these code for 20 amino acids, what is the basis for the genetic code?
If one base = one amino acid, possible amino acids = 4
If two bases = one amino acid, possible amino acids = 16 (4×4)
If three bases = one amino acid, possible amino acids = 64 (4×4×4)
The existence of a three-base (triplet) code was confirmed by experiments by Francis Crick and his colleagues in 1961. The triplet code is degenerate, which means that each amino acid is coded for by more than one triplet.
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What is mRNA?
When a polypeptide is required, the triplet code of its gene is converted into a molecule of messenger RNA (mRNA).
This process is called transcription and is the first stage of protein synthesis.
Like DNA, mRNA is a nucleic acid, but it differs in that:
it is single stranded, not double stranded
it contains ribose instead of deoxyribose
it contains uracil instead of thymine.
mRNA strand during
transcription
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Transcription and codons
During transcription, the mRNA is built up by complementary base pairing, using the DNA as a template. The DNA’s base triplets are converted into mRNA codons.
What are the codons in the mRNA transcribed from this sequence of DNA base triplets?
DNA
mRNA
T A C
G C A G A T T A C
A U G C G U C U A A U G
The genetic code is non-overlapping: each base is only part of one triplet/codon, and each triplet/codon codes just one amino acid.
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The genetic code
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What is translation?
Once a molecule of mRNA has been transcribed, it moves out of the nucleus via a nuclear pore.
In the cytoplasm, the mRNA combines with a ribosome – the cellular structure on which the polypeptide chain will be built in a process called translation.
How are the correct amino acids transported to the ribosome, and how are they linked together in the correct order?
mRNA strand
ribosome
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What is tRNA?
nucleotides
amino acidattachment site
anticodon
In the cytoplasm, amino acids become attached to transfer RNA (tRNA) molecules. Each tRNA is specific for one amino acid.
Each tRNA molecule has a sequence of three bases called an anticodon. These are complementary to codons on the mRNA molecule.
3’ end
5’ end
hydrogen bond
What is the anticodon for the codon A U G?
U A C
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What happens during translation?
tRNA molecules attach to the ribosome, and their anticodons pair up with the appropriate codons on the mRNA.
The amino acids transported by the tRNA link together, and the tRNA molecules then return to the cytoplasm.
The ribosome moves along the mRNA, and amino acids continue to join together until all the codons have been translated and the polypeptide is complete.
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Stages of protein synthesis
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From DNA to amino acids
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Glossary
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What’s the keyword?
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Multiple-choice quiz