Sunday, 4 September y
Genetics, Variation & Interdependence
DNA, Genes & Chromosomes
DNA
Similar Differences Eukaryotic Prokaryotic
Nucleotide structure is Length Long Short
the same (phosphate,
deoxyribose and base)
Nucleotides joined by a Shape Linear Circular
phosphodiester bond
Contain the same 4 Proteins Associated with histones Not associated
bases - A, T, C, U
Both made of triplet Non coding regions Introns and multiple re- None
codons peats
Both helical amount of DNA many DNA one molecule
Both double stranded
Both code for the same
amino acids
Non-coding regions
- introns (within genes)
- Multiple repeats (between genes)
Introns change at a slower rate than exons
- Introns do not code for amino acids
- no selection pressure
Histones
- proteins that DNA molecules wrap around
mRNA will be the same as DNA coding strand but with U instead of T
Bases
Ratio of (C+A):(G+T) is constant but (A+T):(C+G) can vary
- purines (A and G) always pair with pyrimidines (T+C)
- A + T and C+G will always pair
- so the number of A will always be the same as the number of T
1
, Sunday, 4 September y
Bonds between bases
- in a dinucleotide - phosphodiester bond between nucleotides
- hydrogen bonds between DNA strands (A + T = 2 H bonds) (C and G = 3 H bonds)
How can animals have the same percentages of bases but yet be different
- sequence of bases will be different - different codons
- different primary structure / amino acid sequence
- different bonds form in tertiary structure due to differently charged R groups
- Proteins produced by organism affect their appearance / phenotype
Why do organisms have many different mRNA molecules but only 64 different
tRNA molecules
- There are different mRNAs for every protein
- tRNA are specific to one type of amino acid (only 64 codons)
- The code is degenerate - some amino acids can be coded for by multiple codons
Genes
code for
- amino acid sequence of a polypeptide
- or a functional RNA
Genetic code features
Universal
- same bases used and same codons code for the same amino acids in all organisms
Degenerate
- there is more than one codon that will code for an amino acid
- 64 codons for 20 amino acids
- start codon always Met - only one codon
Non-overlapping
- the sequence is read so that each base is only part of one codon
Triplets
- 3 bases are needed to code for one amino acid
Mutations
2
, Sunday, 4 September y
Enzyme mutations
- will only effect the enzyme function if the mutation occurs in the area of the primary
structure that makes up the active site
Silent mutation
- substitution for a base that forms a codon that will code for the same amino acid - de-
generate genetic code
- Or substitution for a amino acid with a similar charged R group
- so the same bonds formed between R groups in the tertiary structure
Chromosomes
Homologous chromosomes
- pairs of chromosomes
Telomeres
- At the end of chromosomes
- to protect DNA from damage
Fungi
- they are eukaryotic so they are made of DNA and histones
Eukaryotic Prokaryotic
Size Larger Smaller
Shape Linear Circular
Structure Complex - DNA, some RNA, his- Simple composition - DNA and
tones some RNA
Non coding regions Non coding regions - introns and None
multiple repeats
Mitochondrial and chloroplast
chromosomes have similar struc-
tures to prokaryotic
DNA & Protein Synthesis
Genome = complete set of genes in an organism
Proteome = full set of proteins a cell can produce
All cells with a nucleus have the same genome - expression of proteome varies between
tissue
3
Genetics, Variation & Interdependence
DNA, Genes & Chromosomes
DNA
Similar Differences Eukaryotic Prokaryotic
Nucleotide structure is Length Long Short
the same (phosphate,
deoxyribose and base)
Nucleotides joined by a Shape Linear Circular
phosphodiester bond
Contain the same 4 Proteins Associated with histones Not associated
bases - A, T, C, U
Both made of triplet Non coding regions Introns and multiple re- None
codons peats
Both helical amount of DNA many DNA one molecule
Both double stranded
Both code for the same
amino acids
Non-coding regions
- introns (within genes)
- Multiple repeats (between genes)
Introns change at a slower rate than exons
- Introns do not code for amino acids
- no selection pressure
Histones
- proteins that DNA molecules wrap around
mRNA will be the same as DNA coding strand but with U instead of T
Bases
Ratio of (C+A):(G+T) is constant but (A+T):(C+G) can vary
- purines (A and G) always pair with pyrimidines (T+C)
- A + T and C+G will always pair
- so the number of A will always be the same as the number of T
1
, Sunday, 4 September y
Bonds between bases
- in a dinucleotide - phosphodiester bond between nucleotides
- hydrogen bonds between DNA strands (A + T = 2 H bonds) (C and G = 3 H bonds)
How can animals have the same percentages of bases but yet be different
- sequence of bases will be different - different codons
- different primary structure / amino acid sequence
- different bonds form in tertiary structure due to differently charged R groups
- Proteins produced by organism affect their appearance / phenotype
Why do organisms have many different mRNA molecules but only 64 different
tRNA molecules
- There are different mRNAs for every protein
- tRNA are specific to one type of amino acid (only 64 codons)
- The code is degenerate - some amino acids can be coded for by multiple codons
Genes
code for
- amino acid sequence of a polypeptide
- or a functional RNA
Genetic code features
Universal
- same bases used and same codons code for the same amino acids in all organisms
Degenerate
- there is more than one codon that will code for an amino acid
- 64 codons for 20 amino acids
- start codon always Met - only one codon
Non-overlapping
- the sequence is read so that each base is only part of one codon
Triplets
- 3 bases are needed to code for one amino acid
Mutations
2
, Sunday, 4 September y
Enzyme mutations
- will only effect the enzyme function if the mutation occurs in the area of the primary
structure that makes up the active site
Silent mutation
- substitution for a base that forms a codon that will code for the same amino acid - de-
generate genetic code
- Or substitution for a amino acid with a similar charged R group
- so the same bonds formed between R groups in the tertiary structure
Chromosomes
Homologous chromosomes
- pairs of chromosomes
Telomeres
- At the end of chromosomes
- to protect DNA from damage
Fungi
- they are eukaryotic so they are made of DNA and histones
Eukaryotic Prokaryotic
Size Larger Smaller
Shape Linear Circular
Structure Complex - DNA, some RNA, his- Simple composition - DNA and
tones some RNA
Non coding regions Non coding regions - introns and None
multiple repeats
Mitochondrial and chloroplast
chromosomes have similar struc-
tures to prokaryotic
DNA & Protein Synthesis
Genome = complete set of genes in an organism
Proteome = full set of proteins a cell can produce
All cells with a nucleus have the same genome - expression of proteome varies between
tissue
3
