Eukaryotic Transcription and the Genetic Code Flashcards
Which RNA polymerase codes for what?
I : rRNA
II : mRNA
III: rRNA and tRNA
What is TBP and what does it do?
TATA box binding protein which is part of a large protein complex called transcription factor II D. TBP consists of two similar domains that bind to DNA and cause it to bend.
What are general transcription factors?
The proteins that bind to upstream control elements and recruit further proteins to help bind RNA polymerase II for transcription. These proteins are able to bind to DNA following TBPs recruitment to the TATA box as the bending of the DNA exposes the sequences allowing them to recruit the general transcription factors.
How do cis acting proteins have an effect on transcription?
These regulator proteins have an effect on the promoter region. As they they are far from the start site the DNA bends bringing them closer and there effect is acted out through a mediator complex
‘strand’
‘bend’ ‘mediator’
‘strand’
How can chromatin structure affect transcription?
If the DNA to be transcribed is wrapped around a nucleosome then the TBP cant bind to the TATA box and therefore the general transcription factors cant either. Chromatin remodeling is required to expose the promoter regions.
How are DNA strands separated for transcription in eukaryotes?
Eukaryotic DNA strands are split via the activity of transcription factor II H (a big complex), which requires ATP hydrolysis. This transcription factor also mediates the initaion of transcription
How does RNA polymerase II escape the promoter region?
Two kinases that are part of the TFIIH complex phosphorylate amino acids that are part of the C terminal of the same complex. This allows RNA polymerase to disengage and from the general transcription factors and begin to elongate the RNA transcript. After this, all the other transcription factors will dissociate from DNA but most of TFIID will remain bound to the RNA polymerase.
Why must eukaryotic RNA be modified before translation and how?
RNA is transcribed in the nucleus and therefore must undergo modifications to keep it stable while it is exported to the cytoplasm and translated. The phosphorylated C terminal of TFIID allows for the binding of enzymes that will facillitate the three necessary modifications which are
- Capping
- Splicing
- Polyadenylation
How is the mRNA transcript capped and why?
The 5’ end of the RNA strand is capped in order to protect it from being degraded. Capping: the terminal phosphate group is removed and a guanine is added forming a 5’ - 5’ triphosphate bridge and the guanine is methylated at the N7 position creating 7-methylgaunosine which blocks enzymes from degrading the transcript. Capping can occur anytime after 25 nucleotides have been added.
Why are mRNA transcripts spliced?
Pre-mRNA transcripts are ‘spliced’ to remove introns as they do not code for amino acids and would disrupt translation. Splicing can also involve the removal of exons. Splicing can occur during transcription once the 5’ end has been capped. (Because of introns eukaryotic transcription takes much longer than prokaryotic).
How does splicing add genetic diversity?
Splicing can include exons or exclude others allowing for different forms of a protein called isoforms to be made as and when they’re needed.
How are specific sequences targeted for splicing?
Each intron is bordered by a sequence that indicates the splice site. Each intron starts with a GU on its 5’ side and an AG on the 3’ end. In addition somewhere in the intron there is an A that is part of a branching site, which is important for excision
How are introns removed?
The branch site is a bent region of the transcript. The 2’ OH group on the transcript is therefore bought into close proximity to the GU 5’ end border. The OH performs a nucleophilic attach on the G cutting the 5’ end. The newly exposed OH group on the exon then performs a nucleophilic attack on the on the last the last G on the 3’ end of the intron cutting that end. This forms an intron lariat which is removed and the ends of the exons are joined together.
Where does splicing occur?
In the spliceosome - a protein complex containing small nuclear RNAs. the spliceosome acts an enzyme for the process.
How is transcription terminated?
RNA polymerase will reach a terminator sequence where it will stop transcribing. Before DNA polymerase dissociates it will transcribe the polyadenylation signal which codes the enzymes that will cleave off the mRNA transcript.
What does the polyadenylation signal do?
Cleaves the RNA exposing the 3’ polyadenylation site. Poly-A-polymerase (PAP) will then bind to the 3’ end of the transcript and add around 200 adenines without a template. This poly A tail provides stability for the mRNA (for export from the nucleus) and promote translation. mRNAs are the only RNAs with poly A tails.
How can only 4 nucleotides code for 20 different amino acids and why are codons only three bases long?
If one amino acid was coded by one base that means there would only be 4 amino acid, 1 amino acid per 2 bases would be 16. But 1 amino acid per 3 bases = 64 amino acids (4^3). This is why a codon is three bases and how multiple codons can code for the same amino acid.
What is the most common type of non coding RNA and how do they work?
tRNA’s recognise codons via their anticodons (a complementary sequence to the mRNA) and the amino acids.
What is the rough structure of a tRNA?
Cloverleaf: 3x hair pin structures (the leaves) with a double stranded ‘stem’ with a protruding 3’ end that attaches the amino acid. The hairpin directly below the ‘stem’ contains the anticodon sequence that is essentially exactly the same as the DNA sequence the mRNA transcribes from
Why would exact tRNA sequences be inefficient what is natures alternative?
If tRNA’s anticodons where matched exactly, 64 tRNAs would be required. Most amino acids can be coded for by multiple different codons, that often have the same first two bases. The third base of the anticodon can “wobble” (the first 2 bases always match) allowing it to bind to a base thats not its normal partner. This is called non-Watson-Crick base pairing.
- G can bind to C or U
-U can bind to A or G
This can can occur because either
- there is extra space at the third nucleotide which allows the bit of RNA to move away from the complementary strand meaning the third base pair doesn’t bind.
- or there can be a 6th nucleotide included: inosine
What is inosine?
A form of adenosine that has been modified by a specific tRNA deaminase. It can bind to A, C or U allowing for wobble to occur.
How does having amino acids that are coded for by more than one codon help?
It creates a high level of redundancy in the system to account for any issues with tRNA availability
