8.1: Genes and the triplet code Flashcards by Amy O'Rourke

Codons

Codons are triplets of base pairs

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Some of the roles of proteins in our bodies

Some of the roles of proteins in our bodies are as:

Enzymes
Channel proteins
Carrier proteins

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The genetic code is a triplet code.

What does this mean?

This means that 3 bases code for one amino acid

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Polypeptides make up proteins

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Polypeptides make up proteins and so genes determine the proteins of an organism

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If there is a mutation, that protein could become non-functional

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As enzymes control chemical reactions, they are responsible for an organism’s:

Development
Activities

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A gene is a section of DNA that contains the coded information for making polypeptides and functional RNA.
The coded information is in the form of a specific sequence of bases along the DNA molecule.
Polypeptides make up proteins and so genes determine the proteins of an organism.
If there is a mutation, that protein could become non-functional.
Enzymes are proteins.
As enzymes control chemical reactions, they are responsible for an organism’s development and activities.
Genes, along with environmental factors, determine the what of all organisms?

Genes, along with environmental factors, determine:
1. The nature
2. The development
of all organisms

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A gene is a section of DNA at a particular position, called a locus, on a DNA molecule

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Gene

A gene is a base sequence of DNA that codes for:
1. The amino acid sequence of a polypeptide
Or,
2. A functional RNA

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A gene is a base sequence of DNA that codes for the amino acid sequence of a polypeptide or a functional RNA, including what?

A gene is a base sequence of DNA that codes for:
1. The amino acid sequence of a polypeptide
Or,
2. A functional RNA, including ribosomal RNA and transfer RNA

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DNA codes for amino acids, but what is it made up of?

DNA:
1. Codes for amino acids
,but
2. It is made up of nucleotides

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What is the sequence of amino acids coded for by DNA?

The sequence of amino acids coded for by DNA is the primary structure of a protein

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The sequence of amino acids coded for by DNA is the primary structure of a protein.
It is the primary structure that gives rise to what?

It is the primary structure that gives rise to the tertiary structure

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The sequence of amino acids coded for by DNA is the primary structure of a protein.
It is the primary structure that gives rise to the tertiary structure and hence what?

It is the primary structure that gives rise to:

The tertiary structure
Hence the shape of the protein

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The sequence of amino acids coded for by DNA is the primary structure of a protein.
It is the primary structure that gives rise to the tertiary structure and hence the shape of the protein.
So what does DNA indirectly do?

So DNA indirectly codes for the shape of proteins

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So DNA indirectly codes for the shape of proteins, including enzymes

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Only 20 different amino acids occur regularly in proteins

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Each amino acid must have its own code of bases on the DNA

Only 4 different bases (adenine, guanine, cytosine and thymine) are present in DNA

If each base coded for a different amino acid, then only 4 different amino acids could be coded for

Using a pair of bases, (4²) 16 different codes are possible, which is still inadequate

In trying to discover how DNA bases coded for amino acids, scientists suggested that there must be a minimum of 3 bases that coded for each amino acid.
Their reasoning was as follows:
1. Only 20 different amino acids occur regularly in proteins.
2. Each amino acid must have its own code of bases on the DNA.
3. Only 4 different bases (adenine, guanine, cytosine and thymine) are present in DNA.
4. If each base coded for a different amino acid, then only 4 different amino acids could be coded for.
5. Using a pair of bases, (4²) 16 different codes are possible, which is still inadequate.
6. How many different codes do 3 bases produce?

3 bases produce (4³) 64 different codes

3 bases produce (4³) 64 different codes, more than enough to satisfy the requirements of 20 amino acids

In trying to discover how DNA bases coded for amino acids, scientists suggested that there must be a minimum of 3 bases that coded for each amino acid. Their reasoning was as follows: 1. Only 20 different amino acids occur regularly in proteins. 2. Each amino acid must have its own code of bases on the DNA. 3. Only 4 different bases (adenine, guanine, cytosine and thymine) are present in DNA. 4. If each base coded for a different amino acid, then only 4 different amino acids could be coded for. 5. Using a pair of bases, (4²) 16 different codes are possible, which is still inadequate. 6. 3 bases produce (4³) 64 different codes, more than enough to satisfy the requirements of 20 amino acids. As the code has 3 bases for each amino acid, what is each one called?

As the code has 3 bases for each amino acid, each one is called a triplet

In trying to discover how DNA bases coded for amino acids, scientists suggested that there must be a minimum of 3 bases that coded for each amino acid. Their reasoning was as follows: 1. Only 20 different amino acids occur regularly in proteins. 2. Each amino acid must have its own code of bases on the DNA. 3. Only 4 different bases (adenine, guanine, cytosine and thymine) are present in DNA. 4. If each base coded for a different amino acid, then only 4 different amino acids could be coded for. 5. Using a pair of bases, (4²) 16 different codes are possible, which is still inadequate. 6. 3 bases produce (4³) 64 different codes, more than enough to satisfy the requirements of 20 amino acids. As the code has 3 bases for each amino acid, each one is called a triplet. As there are 64 possible triplets and only 20 amino acids, what follows?

As there are 64 possible triplets and only 20 amino acids, it follows that some amino acids are coded for by more than one triplet

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only what?

A few amino acids are coded for by only a single triplet

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only a single triplet. 2. How are the remaining amino acids coded for?

The remaining amino acids are coded for by between: 1. 2 2. 6 triplets each

The genetic code is known as a 'degenerate code,' because most amino acids are coded for by more than one triplet

A triplet is always read in one particular direction along the DNA strand

The start of a DNA sequence that codes for a polypeptide is always the same triplet

This codes for the amino acid methionine

If this first methionine molecule does not form part of the final polypeptide, it is later removed

3 triplets do not code for any amino acid

These are called 'stop codes'

These are called 'stop codes' and they mark the end of a polypeptide chain

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only a single triplet. 2. The remaining amino acids are coded for by between 2 and 6 triplets each. 3. The genetic code is known as a 'degenerate code,' because most amino acids are coded for by more than one triplet. 4. A triplet is always read in one particular direction along the DNA strand. 5. The start of a DNA sequence that codes for a polypeptide is always the same triplet. This codes for the amino acid methionine. If this first methionine molecule does not form part of the final polypeptide, it is later removed. 6. 3 triplets do not code for any amino acid. These are called 'stop codes' and they mark the end of a polypeptide chain. 7. What does the genetic code being non-overlapping mean?

The genetic code being non-overlapping means that each base in the sequence is read only once

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only a single triplet. 2. The remaining amino acids are coded for by between 2 and 6 triplets each. 3. The genetic code is known as a 'degenerate code,' because most amino acids are coded for by more than one triplet. 4. A triplet is always read in one particular direction along the DNA strand. 5. The start of a DNA sequence that codes for a polypeptide is always the same triplet. This codes for the amino acid methionine. If this first methionine molecule does not form part of the final polypeptide, it is later removed. 6. 3 triplets do not code for any amino acid. These are called 'stop codes' and they mark the end of a polypeptide chain. 7. The genetic code being non-overlapping means that each base in the sequence is read only once. Therefore, 6 bases numbered 123456 are read how, rather than as triplets 123, 234, 345, 456?

Therefore, 6 bases numbered 123456 are read: 1. As triplets 123 and 456 ,rather than 2. As triplets 123, 234, 345, 456

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only a single triplet. 2. The remaining amino acids are coded for by between 2 and 6 triplets each. 3. The genetic code is known as a 'degenerate code,' because most amino acids are coded for by more than one triplet. 4. A triplet is always read in one particular direction along the DNA strand. 5. The start of a DNA sequence that codes for a polypeptide is always the same triplet. This codes for the amino acid methionine. If this first methionine molecule does not form part of the final polypeptide, it is later removed. 6. 3 triplets do not code for any amino acid. These are called 'stop codes' and they mark the end of a polypeptide chain. 7. The genetic code being non-overlapping means that each base in the sequence is read only once. Therefore, 6 bases numbered 123456 are read as triplets 123 and 456, rather than as triplets 123, 234, 345, 456. 8. Why is the genetic code universal?

The genetic code is universal, because, except for a few minor exceptions, each triplet codes for the same amino acid in all organisms

Features of the genetic code: Further experiments have revealed the following features of the genetic code: 1. A few amino acids are coded for by only a single triplet. 2. The remaining amino acids are coded for by between 2 and 6 triplets each. 3. The genetic code is known as a 'degenerate code,' because most amino acids are coded for by more than one triplet. 4. A triplet is always read in one particular direction along the DNA strand. 5. The start of a DNA sequence that codes for a polypeptide is always the same triplet. This codes for the amino acid methionine. If this first methionine molecule does not form part of the final polypeptide, it is later removed. 6. 3 triplets do not code for any amino acid. These are called 'stop codes' and they mark the end of a polypeptide chain. 7. The genetic code being non-overlapping means that each base in the sequence is read only once. Therefore, 6 bases numbered 123456 are read as triplets 123 and 456, rather than as triplets 123, 234, 345, 456. 8. The genetic code is universal, because, except for a few minor exceptions, each triplet codes for the same amino acid in all organisms. What is this indirect evidence for?

This is indirect evidence for evolution

Much of the DNA in eukaryotes does not code for what?

Much of the DNA in eukaryotes does not code for polypeptides

Much of the DNA in eukaryotes does not code for polypeptides. Example

For example, between genes there are non-coding sequences made up of multiple repeats of base sequences

Even within genes, only certain sequences code for amino acids

These coding sequences are called exons

Much of the DNA in eukaryotes does not code for polypeptides. For example, between genes there are non-coding sequences made up of multiple repeats of base sequences. Even within genes, only certain sequences code for amino acids. These coding sequences are called exons. Within the gene, what happens to these exons?

Within the gene, these exons are separated by further non-coding sequences called introns

Some genes code for: 1. Ribosomal RNA 2. Transfer RNA