Lecture 16 - Basal transcription

Question 1

What is the central dogma of gene expression?

Answer 1

DNA is transcribed into RNA and translated into protein

Question 2

Where does most regulation occur in gene expression?

Answer 2

at the transcription level

-exceoption is viruses

Question 3

What ar a few examples of where transcription control is used?

Answer 3

• during cellular differentiation
• in response to stress
• in response to hormonal stimulation
• changes in nutirent status or in response to growht factor signals

Question 4

Give examples of what can happen when transcription regiulation goes wrong?

Answer 4

Cancer

• retinoblastoma caused by a Rb loss fo funtion mutation
• recessive gene
• loss of sight amogst other things

antp mutant drosophila
-legs growing out of where antenna should be

Question 5

What are the three stages of transcription?

Answer 5

Initation
Elongation
Termination

Question 6

What is the structure of the E.coli RNA pol (prokaryotic)?

Answer 6

• very simple
• only one form of RNA pol
• 4 subunits: β, β’, 2Xα
• σ factor binding confers DNA specifiicty (holoenzyme)
• core RNA poly has no ability to specifically bind DNA

Question 7

How were the 3 eukaryotic DNA pol identified

Answer 7

• took sea urchin nuclear extract and manipulated so that the RNA contains radioactive UMP(instead of uracil)
• did purification step [used, DEAD sephadex column followed by an ion exchange column for negative charge (to isolate the factor that binds DNA)
• took fractions as increased the salt (ammonium sulfate)
• added phosphor and collected fractions and tested for the inclusion of radioactive UMP

Would have expected one peak of activity like the E.coli polymerases
-however actually got 3; RNA pol I, RNA pol II and RNA pol III

Question 8

What are the genes transcribed by the three RNA polymerases?

Answer 8

RNA pol I: Large mRNA
RNA pol II: mRNA, U1-U5 snRNA
RNA pol III: small rRNA, tRNA, U6 snRNA, VA1 RNA and other small RNAs of unknown function

Question 9

Which RNA pol is involved in transcription of RNA polymerase III?

Answer 9

RNA pol II

Question 10

What are the yeast RNA pol subunits?

Answer 10

Core subunits
Common subunits
Specific subunits (uniquie to RNApol but not part if the core subunits)

Question 11

What are the features of RNA pol II?

Answer 11

-large, multi-subunit complex of proteins
-14 subunits in yeast
[3 largest are similar to bacterial RNA pol subunits, 2 largest carry the catalytic site]
-largest subunit has a carboxyl-terminal domain (CTD) that consists of a repeated sequence of 7 amino acids, phosphorylation of this domain is important for transcription initiation and downstream processing

Question 12

What is the sequence of amino acids in RNA pol II CTD?

Answer 12

YSPTSPS

contains tyrosine, threonine and serine - sites for phosphorylation

Question 13

Compare the euakryotic to the prokaryotic mode of transcription

Answer 13

Pro
-E.coli genome is circular, super coiled DNA molecule lacking any higher order chromatin structure
-Therefore the first step in gene expression (promoter recognition and DNA binding) faces less obstables
-repression is more necessary
= Non-restrictive transcription
Eu
-DNA is packaged into higher order chromatin structure
-keeps genes inactive by preventing RNA pol from accessing the promoter
-acitivation more necessary
=restrictive transcription

Question 14

What are the regions of the RNA pol II promoter?

Answer 14

A core promoter region
-located proximal to, potentially overlapping with, the start site of transcription and is suffient for low level of transcription in vitro
A regulatory region
-usually distal to the start site for activator or repressor binding

Question 15

What does the promoter determine?

Answer 15

When RNA pol will bind

Question 16

What are the properties of the RNA pol II core promoter?

Answer 16

Start point (start of transcription not translation)
-first base of mRNA (+1 position) to be A and flanked on either side by pyrimidines (C and D)
-hard to determine position
TATA box
-~25-30 bases upstream of the start point
-found in most genes in eukaryotes
-equivilent of the -10 seq in bacterial promoters (Pribnow box)
-AT rich consensus sequence often surrounded by GC rich sequence
-TATA box is the initial DNA target site for the assembly of the basal transcription complex in most promoters

Question 17

What is an initiator element?

Answer 17

instead of a TATA box, some RNA pol II promoters contain an alternative promoter element
e.g. lymphocytes in TET gene

Question 18

What RNA pol II require to initiate rtanscription?

Answer 18

-auxillary factors (transcription factors)

Question 19

What is TFIID?

Answer 19

• binds to theTATA box
• compoased of TBP and TAFs
• TBP(TATA box binding protein) recognises the TATA box
• TAFs (TBP-associated factors)
• TBP bends DNA ~80* and forces open the minor groove
• melts DNA
• also provides a saddle structure for the loading of other GTFs

Question 20

How was TFIID identified?

Answer 20

-ran a negatively charged column
-took different concentrations of salt to elucidate DNA/DNApol binding proteins; A - 100nm, B - 350nm, C - 500nm, D - 1mole
-isolated the binding proteins and named
e.g.
TFIID isolated in the D fraction

Question 21

What is the process of assembly of the basal transcription process?

Answer 21

1. TFIID binds to the TATA box, facilitated by TFIIA
2. TFIID-DNA complex is recognised by TFIIB
3. TFIIB binding recruits RNA polymerase II along with its assocaited factor TFIIF
4. when RNA pol II joins, the CTD binds to TBP
5. subsequently, TFIIE and TFIIH (multisubunit complexes join the complex, leading to promoter clearance and melting
6. TFIIH has helicase and kinase activity, phosphorylation of CTD caused RNA pol II to no longer be tethered to the TBP and RNA pol II can now move off
7. the phosphorylation of CTD also induces a conformational change that releases TFIIE from polII and TFIIH
8. once TFIIE is displaced, the TFIIH helicase acts to unwind the DNA template
9. PolII and TFIIF move off down the gene leaving TFIIA and TFIID bound at the promotor

Question 22

What is the process of promoter clearance and melting?

Answer 22

TFIIE and TFIIH involved

• TFIIH has helicase and kinase activity, phosphorylation of CTD caused RNA pol II to no longer be tethered to the TBP and RNA pol II can now move off
• the phosphorylation of CTD also induces a conformational change that releases TFIIE from polII and TFIIH
• once TFIIE is displaced, the TFIIH helicase acts to unwind the DNA template

Question 23

Can the basal transcriptional complex produce any expression of genes without the help of stimulatory transcription factros?

Answer 23

Yes. The basal transcriptional complex can produce only a low rate of transcription

Question 24

What is required for significant levels of expression?

Answer 24

Basal transcriptional complex, and stimulatory transcription factors that bind to DNA sites distinct from where basal transcriptional complexes assemble

Question 25

What are the features of the stimulatory transcription factors that bind DNA to produce significant levels of expression>?

Answer 25

• bind to DNA distinct from when the basal factors assemble
• DNA sites can be short elements located within or adjaceent to the gene promoter, or can act at a distance
• efficiency and specificity depends on the particular combination of sequence elements to which regulatory sequences bind
• sequences may be common and found in a wide variety of promoters or they may be specific, to allow for tissue specific expression or inducability under certain condiditons