Environment & Gene Expression (DP IB Biology)
Revision Note
Epigenesis & Differentiation in Cells
Epigenesis is the development of differentiation patterns in the cells of multicellular organisms as it develops from a zygote
This is determined by the genome and patterns of gene expression in an organism
Epigenetics is the genetic control by factors other than an individual’s DNA sequence
It involves heritable changes in gene function, without changes to the DNA sequence
In eukaryotic cells, nuclear DNA is wrapped around proteins called histones to form chromatin
Chromatin can be chemically modified in different ways to alter gene expression
Methylation of DNA (chemical addition of a -CH3 group)
Histone modification of of amino acid tails via
Acetylation: Acetyl groups are added to histones which allows transcription as it leads to the DNA becoming more loosely packed
Methylation: The addition of a -CH3 group
Phosphorylation: the addition of phosphate to an organic compound
Such modifications are called epigenetic tags and collectively, all the epigenetic tags in an organism are called the epigenome
Like the genome, the epigenome is heritable
Mounting evidence demonstrates that modifications to the epigenome in one generation can be passed on to the next generation at cellular or whole organism level
The phenotype of an organism is determined by its genotype
Since the DNA sequence is not changed by epigenetic changes, the genotype of an organism will remain the same while the phenotype changes
Examiner Tips and Tricks
Epigenetics can be distinguished from mutations, both of which lead to changes in the expressed characteristics of genes. Whilst mutations affect the genetic code itself e.g. by altered nucleotide sequences, epigenetics affect the way the code is read.
Think about an identical passage of text being read by two different people, one with perfect Queen's English and the other with a very strong regional dialect. Despite the text being the same (no mutations), the effect of the dialect (epigenetics) might alter the meaning of the piece drastically to a listener.
Pattern of Gene Expression in Cells
Differences between the genome, transcriptome and proteome of cells
The proteome of an organism includes all the proteins synthesised within their cells and is determined by the genome
Each organism will have a unique proteome due to its unique set of genetic material
Different proteins are needed in different cell types, so only the genes responsible for expressing the correct proteins will be "switched on" at any particular time in a cell
This avoids energy wastage that would be caused by expressing all the genes in every cell
Therefore, the genome of each cell in an organism is the same while the proteome varies
The range of mRNA transcripts produced within a cell or tissue type is known as its transcriptome
This in turn will be determined by the pattern of gene expression in the cell
The transcriptome will therefore result in certain proteins being synthesised
Proteome Diagram
The relationship between the genome, transcriptome and proteome in cells
Epigenetic Tags: Methylation
Nucleosomes are the structural unit of DNA packaging in eukaryotes that facilitate supercoiling
Within a nucleosome, DNA is wrapped around proteins called histones
The tails of histones can be chemically modified which can influence whether a gene will be expressed or not
One way in which histones may be modified is by adding a methyl group to the amino acids of the protein
This can either activate or deactivate genes by making the gene more or less accessible to transcription factors
Chemicals (such as methyl or acetyl groups) that regulate gene expression are called epigenetic tags
Methyl groups can also be directly added to DNA to change the activity of a gene
Methylation of DNA
DNA methylation commonly involves the direct addition of a methyl group (-CH3) to cytosine bases of the promoter region which can influence gene expression
Methylation of DNA suppresses the transcription of the affected gene by inhibiting the binding of transcription factors
Cells use this mechanism to lock genes in the ‘off’ position
DNA methylation can be affected by many environmental, lifestyle or age-related factors
Methylation of DNA at the promoter region is an example of how epigenetic tags may regulate gene expression
Epigenetic Inheritance
When epigenetic tags (such as the methylation of DNA or histone tails) remain in place during mitosis or meiosis, then those modifications are passed on
In the case of mitosis, this results in daughter cells containing the same epigenetic modifications as the parent cells
Meiosis will form gametes containing these epigenetic tags which will then be passed on to the offspring that develop when these cells are fertilised
The inheritance of these epigenetic tags is known as epigenetic inheritance
This means that phenotypic changes resulting from epigenetic modifications can be inherited without changes in the nucleotide sequence of DNA occurring
If epigenetic tags are removed during mitosis or meiosis, then epigenetic inheritance cannot take place
Examiner Tips and Tricks
Remember that epigenetic tags (such as DNA methylation) will change the pattern of gene expression in a cell. This will determine which proteins are synthesised which will ultimately affect the phenotype of the cell or organism.
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