- In Language, the process of matching the sounds of human speech to written symbols using a set of standard rules, so that these sounds can be reproduced later. Usually these rules are organized on a phonetic? basis and are specifically constructed in order to be maximally simple. Standard transcription schemes include the International Phonetic Alphabet (IPA), and its ASCII equivalent, SAMPA. One can see numerous examples of transcription on the Common phrases in different languages page (in this particular case, using the standard English spelling rules).
- In genetics, the process of copying DNA to mRNA by an enzyme called [RNA polymerase]?. Transcription is the first step of protein biosynthesis.
A (simple) model for a bacterial
gene to be transcribed looks like this :
upstream ~17 bp The gene to transcribe downstream
5'----------|-35|---------|-10|----------------------|T|------------3'
3'----------|-35|---------|-10|----------------------|T|------------5'
|
|--------------------->
mRNA
where the region between -35 and -10 base pairs is called
promoter, and |T| stands for
terminator. The DNA between promoter and terminator is copied to mRNA, which is then
translated into
protein.
Promoters can differ in strength, that is, how attractive they are for RNAP. The more similar they are to a [consensus sequence]?, the stronger they are. The "ideal" promoter in [E. coli]? looks like this:
5'----TTGACA---|17 bp|----TATAAT---|7bp|---|[[purine]]s|----3'
Initiation
The RNA polymerase (or RNAP) holoenzyme
? consists of a
core, made of four subunits (ααββ'), and the σ-factor
?. The followings steps occur upon initiation:
- The RNAP recognizes the pomoter region of the gene and binds to the DNA at that specific location. At this stage, the DNA is still double-stranded and called closed complex.
- The DNA is unwound and becomes single-stranded at the initiation site (the -10 promoter region). This is called open complex.
- The DNA is melted (the strands are locally separated), the σ-factor leaves the holoenzyme, and the transcription process begins. This is the elongation phase.
Elongation
The RNAP runs along the DNA, synthesizing mRNA in the process. In bacteria, the nascending mRNA is processed right away by
ribosomes.
Termination
The elongation stops if:
- The terminator is reached. The terminator is usually a palindromic DNA sequence that forms a hairpin.
- A [ρ factor]? (a protein) binds and runs along the mRNA towards the RNAP. When ρ-factor reaches the RNAP, is causes RNAP to dissociate from the DNA, terminating transcription.
- The RNAP comes along a region with repetitious base pairs (for example, TTTTTT). This will terminate transcription.
[Gene expression]
? in eukaryotes is largely controlled by transcription via [transcription factor]
?s. As eukaryotes are much more complex than prokaryotes, and have their genetic material stored in the
nucleus, the transcription mechanisms are more complicated here. For example, eukaryotes have three RNA polymerases, in contrast to prokaryotes, which only have one.
- RNA Polymerase I is located in the nucleolus and transcribes only rRNAs.
- RNA Polymerase II is the "standard" RNAP.
- RNA Polymerase III transcribes tRNAs and other small RNAs.
Also, eukrayotic RNAPs need specific
accessory proteins to become active. The C-terminus of all RNAPs is highly conserved and contains the actual transctiptional mechanism.
Initiation
The
core promoter of eukaryoric genes stretches from position -45 to 0. Additionally, there can be an
upstream control element present at the -180 to -107 region, which can amplify the RNAP binding by a factor of up to 100. This UCE usually contains a [TATA box]
?, a highly conserved DNA sequence that reads
T A T A T/A A
A similar sequence, thus not that highly conserved, is found in the INR element (
initiator element, part of the complex core promoter).
Elongation
Termination
A major difference between prokaryotic and eukaryotic transcription is that the latter have
splicing of the
primary transcript, modifying the mRNA created during transcription.
- See also : signal transduction