Transcription in Protein Synthesis (DP IB Biology)
Revision Note
Synthesis of RNA
This process of protein synthesis occurs in two stages:
Transcription – DNA is transcribed and an mRNA molecule is produced
mRNA is a single stranded RNA molecule that transfers the information in DNA from the nucleus into the cytoplasm
mRNA production requires the enzyme RNA polymerase
Translation – mRNA (messenger RNA) is translated and an amino acid sequence is produced
The process of transcription
This stage of protein synthesis occurs in the nucleus of the cell
Part of a DNA molecule unwinds (the hydrogen bonds between the complementary base pairs break)
This exposes the gene to be transcribed (the gene from which a particular polypeptide will be produced)
A complementary copy of the code from the gene is made by building a single-stranded nucleic acid molecule known as mRNA (messenger RNA)
Free RNA nucleotides pair up (via hydrogen bonds) with their complementary (now exposed) bases on one strand (the template strand) of the ‘unzipped’ DNA molecule
The sugar-phosphate groups of these RNA nucleotides are then bonded together by the enzyme RNA polymerase to form the sugar-phosphate backbone of the mRNA molecule
When the gene has been transcribed (when the mRNA molecule is complete), the hydrogen bonds between the mRNA and DNA strands break and the double-stranded DNA molecule re-forms
The mRNA molecule then leaves the nucleus via a pore in the nuclear envelope
This is where the term messenger comes from - the mRNA is despatched, carrying a message, to another part of the cell
DNA can't make this journey; it's too big to fit through the pores in the nuclear envelope
Transcription in the nucleus diagram
DNA is transcribed and an mRNA molecule is produced
Examiner Tips and Tricks
Be careful – DNA polymerase is the enzyme involved in DNA replication; RNA polymerase is the enzyme involved in transcription – don’t get these confused.
Hydrogen bonding & Complementary Base Pairing
In the transcription stage of protein synthesis, free RNA nucleotides pair up with the exposed bases on the DNA molecule but only with those bases on one strand of the DNA molecule
The RNA will have a complementary base sequence to the DNA strand and will bind to the DNA using hydrogen bonds
The adenine of the DNA is complementary to uracil on the new RNA strand, because a thymine RNA nucleotide does not exist
Complementary base pairing between the DNA and the RNA transcript table
DNA template strand code | TAC | GGA | AGA | CTT | GGG |
|---|---|---|---|---|---|
RNA transcript | AUG | CCU | UCU | GAA | CCC |
The strand of the DNA molecule that carries the genetic code is called the coding strand
The opposite DNA strand is called the template strand
To get an RNA transcript of the coding strand, the template strand is the one that is transcribed to form the mRNA molecule
This mRNA molecule will later be translated into an amino acid chain
DNA coding and template strand during transcription diagram
The template strand of the DNA molecule is the one that is transcribed
DNA Templates
DNA is a very stable molecule due to the hydrogen bonding between the DNA bases of the two strands and the strong phosphodiester bonds between adjacent nucleotides in each strand
This means that the genetic code is not prone to spontaneously breaking or changing
This feature allows single DNA strands to act as reliable templates for transcription over several generations of cell replication
In certain types of somatic cells that do not divide during their lifetimes, such as neurones and some types of muscle cells, the genetic sequence is conserved due to this stability and does not degrade over time
Transcription & Gene Expression
There are approximately 20,000 protein-coding genes in the human genome
Not every protein is needed in every cell
For example, the insulin protein is not needed in cardiac muscles of the heart
As a result, our specialised cells have a way of switching certain genes off or on to match the requirements of the cell. This is called gene expression
Genes that are expressed are 'switched on' and undergo the process of transcription and translation
Genes that are not expressed are 'switched off' or silenced, and do not go through the process of transcription and/or translation
There are various different mechanisms in the cell involved in controlling gene expression
Transcription is the first stage of gene expression and so this is a key stage at which gene expression can be switched on or off
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