Nucleic Acids - Transcription, Translation and Targeting

Question 1

What is the template (antisense) strand?

Answer 1

The strand which is transcribed

Question 2

What are the 3 mammalian RNA polymerases?

Answer 2

• Polymerase I transcribes ribosomal RNA
• Polymerase 2 transcribes mRNA, microRNAs and a variety of non-coding RNAs
• Polymerase 3 transcribes tRNA (transfer RNA)

Question 3

What is not needed in transcription compared to DNA replication and why?

Answer 3

An RNA primer is not needed as it is single stranded

Question 4

What is a promotor element?

Answer 4

region of DNA upstream of a gene where proteins e.g. RNA polymerase, transcription factors bind to initiate gene transcription

Question 5

What is a TATA box?

Answer 5

A promotor element - a short run of T and A bases that can vary slightly from gene to gene .
It may be that Ts and As are used because they form the lowest energy base-pairs and so are the easiest to unwind.

Question 6

How does the Tata box act as a promotor?

Answer 6

• The gene has a TATA box upstream and then 25 base pairs until transcription start site (very close)
• Transcription factors bind (several proteins form a complex)
• RNA polymerase bind II binds to the transcription factors
• Some transcription factors disassociate and transcription factors

Question 7

What are characteristics of promotor elements situated further away?

Answer 7

• several kilobases away from transcription start site
• 1 to 3 kb stretch of proximal enhancers/silencers (some may be involved in tissue-specific and regulated transcription)
• Followed by minimal core promotor sometimes including a TATA box
• 25 base pairs
• transcription start site

Question 8

Which group does methylation of cytosine add? What is produced?

Answer 8

CH3 is added to form 5-methyl cytosine in DNA

Question 9

What does 5-methyl cytosine pair with in DNA and when does it most commonly occur?

Answer 9

Still pairs with G and most commonly occurs to the C when it is followed by a G in the DNA sequence = CpG (C phosphodiester link G)

Question 10

What are CpG islands?

Answer 10

• sequences of a few hundred bp of DNA which have a particularly high density of CpG dinucleotides
• CpG islands are present about 1 kilobase upstream of the transcription site of mammalian genes

Question 11

Methylation of C in active genes?

Answer 11

Active genes (genes that are being transcribed) = CpG island dinucleotides unmethylated whereas Cpgs elsewhere in the gene are methylated

Question 12

Methylation of C in inactive genes?

Answer 12

CpG island dinucleotides are methylated and CpGs present elsewhere in the gene are methylated

Question 13

What are the two steps needed to generate mature mRNA from pre-mRNA?

Answer 13

1) Cleavage and polyadenylation
2) Splicing out of introns

Question 14

How does cleavage and addition of a polyA tail occur?

Answer 14

1) Pol II generates a pre-mRNA. In the region of DNA encoding the 3’ UTR there will be one or more polyadenylation sequences. One of these likely to be used more.
2) In eukaryotes, transcription continues past the point where polyadenylation sequences are present. Transcription termination in eukaryotes is poorly understood but many kilobases of extra sequence may be copied from DNA in to RNA
3) The mRNA is cut a short way downstream (-30 nucleotides) of the polyadenylation sequence (AAUAAA in RNA)
4) A polyA tail is added

Question 15

Describe the 5’ cap and poyA tail on eukaryotic mRNA

Answer 15

Capping nucleotide found on the 5’ end (stabilises mRNA) connected to the 5’ UTR (untranslated region) which is connected to the coding sequence followed by the 3’ UTR and a polyA tail added at the end (except histone mRNAs).

Question 16

What type of RNAs can bacteria produce that eukaryotes cannot?

Answer 16

Polycistronic mRNAs (encodes two or more proteins)

Question 17

What does the lac operon produced by E.coli do?

Answer 17

Three coding sequences within the mRNA
- lacZ sequence produces an enzyme which breaks down lactose to monosaccharides
- lacY seq produces an transporter necessary for the uptake of lactose
- lacA seq produces an acetylation enzyme whose biological function is not completely understood

Question 18

What is splicing?

Answer 18

The removal of intronic sequences from the pre-mRNA

Question 19

How many nucleotide pairs and exons are there in the human B-globin gene?

Answer 19

2000 nucleotide pairs, 3 exons

Question 20

How many nucleotide pairs and exons are there in the human Factor VIII gene?

Answer 20

200,000 nucleotide pairs, 26 exons

Question 21

How does splicing occur?

Answer 21

• Introns are removed by the spliceosome
• A lariat is formed from the intron and cut out
• Alternative splicing (including different exons in different mRNAs) can give subtly different mRNAs in related tissues

Question 22

What is the difference between prokaryotic mRNA and eukaryotic mRNA?

Answer 22

Prokaryotic mRNA does not have a polyA tail or a 5’cap, it can also be polycistronic.

Question 23

How can you test whether all of the control elements in DNA necessary for the proper regulation of transcription are present? (e.g. B-globin gene)

Answer 23

• make DNA constructs covering globin gene and flanking sequences
• inject into mouse oocytes, some DNA will integrate at random sites into the mouse genome within the oocytes.
• Allow the recombinant oocytes to develop into transgenic mice
• If all of the regulatory info is correct, the construct will always work where it is integrated (expresses at the right level, right stage of development and in the right tissues)

Question 24

How many natural amino acids are there in the body?

Answer 24

20

Question 25

What is a codon?

Answer 25

3 bases that code for an amino acid

*more than one codon can code for an amino acid

Question 26

What are the three stop codons?

Answer 26

• UAA
• UAG
• UGA

Question 27

What is the universal go codon (Methionine)?

Answer 27

AUG

Question 28

How is protein synthesis initiated (translation)?

Answer 28

• Initiator tRNA carries the amino acid methionine (or in bacteria N-formyl methionine) to AUG codon
• Initiator Met-tRNA differs from the normal tRNA that carries methionine
• initiator Met-tRNA is recognised by eukaryotic initiation factors that bind to the small subunit of the ribosome.

Question 29

How does the small subunit of the ribosome initiate translation?

Answer 29

• Small subunit binds to the mRNA and moves along the 5’ UTR (scanning) until it reaches the initiating AUG
• The large subunit binds and translation starts

*often the initiating AUG is the first AUG in the mRNA reading from the 5’ end
*In some mRNAs, one or more of AUG codons in the 5’ UTR are overlooked before initiating AUG is reached. The initiating AUG will be in good context to initiate translation

Question 30

What happens once the large ribosome subunit binds and translation is initiated?

Answer 30

• The ribosome moves along the coding sequence of the mRNA and the protein is synthesised.
• Additional ribosomes can engage with the mRNA before the first ribosome has completed translation

Question 31

What is a polysome?

Answer 31

An mRNA with multiple ribosomes attached

Question 32

What happens once the ribosome reaches the stop codon?

Answer 32

• Release factor binds to the A site, polypeptide chain is released from the ribosome.
• The ribosome dissociates and the protein is released
• If a premature stop codon is generated by mutation, the coding mRNA downstream of the premature stop codon will no longer be covered with ribosomes.
• The exposed region of the mRNA that isn’t covered with ribosomes may be chopped up by RNAses
• The mRNA degradation that occurs is called ‘nonsense mediated decay’

Question 33

How are amino acids attached to tRNA before they can be incorporated into proteins?

Answer 33

They are esterified to tRNA

Question 34

How are amino acids attached to tRNA before they can be incorporated into proteins?

Answer 34

They are esterified to tRNA

Question 35

What is the structure of tRNA?

Answer 35

• Clover leaf structure
• The anticodon which hydrogen bonds with the codon in the mRNA is at the end of one loop
• At the 3’ end of the molecule the amino acid is attached

Question 36

If anticodon 5’ GAA 3’ is present on tRNA what is the codon of RNA that will bind?

Answer 36

3’ UUC 5’ as it binds in an antiparallel fashion

Question 37

If anticodon 5’ GAA 3’ is present on tRNA what is the codon of RNA that will bind? (Phenylalanine)

Answer 37

3’ UUC 5’ as it binds in an antiparallel fashion

Question 38

What do aminoacyl tRNA synthetases do?

Answer 38

Esterify the correct amino acid onto each tRNA. There is a specific enzyme for each tRNA so the correct amino acid is added to the correct tRNA.

Question 39

What does the yeast tRNA anticodon for phenylalanine 5’-GAA-3’ recognise as a codon which is unexpected? How is this beneficial?

Answer 39

• 3’-UUU-5’ (a non-Watson-Crick base pairing)
• Reduces the number of tRNA molecules and synthetases that the cell needs to produce

Question 40

What are the three sites on an assembled ribosome?

Answer 40

• E (exit) site
• P (peptidyl) site
• A (aminoacyl tRNA) site

Question 41

What is the difference in structure between prokaryotes and eukaryotes?

Answer 41

• Prokaryotic ribosomes are 70s which have a 50s large subunit and a 30s small subunit
• Eukaryotic ribosomes are 80s which have a 60s large subunit and a 40s small subunit

Question 42

Why is having a different ribosomal structure in prokaryotes and eukaryotes important clinically?

Answer 42

Different antibiotics bind to bacterial ribosomes and inhibit protein translation

Question 43

What are the S units in ribosomal structure?

Answer 43

Svedberg units - measure of the rate of sedimentation under centrifugal force

Question 44

Apart from the cytosol and the ER where else are ribosomes found in the cell?

Answer 44

In the mitochondrial matrix on the cristae

Question 45

What are certain antibiotics that target the small ribosomal unit in prokaryotes?

Answer 45

• tetracycline
• spectinomycin
• hygromycin B
• streptomycin

Question 46

What are certain antibiotics that target the large ribosomal unit in prokaryotes?

Answer 46

• chloramphenicol
• erythromycin
• streptogramin B

Question 47

Where is pre-mRNA processed into mature mRNA?

Answer 47

In the nucleoplasm and then it travels through nuclear pores which span the two nuclear membranes and is translated in the cytosol

Question 48

what is the cytosol?

Answer 48

The thick liquid or gel surrounding the organelles

Question 49

What is the cytoplasm?

Answer 49

the cytosol and the organelles but not the nucleus

Question 50

What is the function of the ER and Golgi apparatus?

Answer 50

packaging and secretion of proteins that are due to be released from cells and the assembly of proteins embedded in membranes such as the plasma membrane.

Question 51

what is the role of lysosomes?

Answer 51

They are full of degradative enzymes, they degrade certain molecules imported into the cell and damaged cell components.

• The degradative enzymes are delivered to the site via the ER and golgi apparatus

Question 52

How are most mitochondrial proteins produced and transported ?

Answer 52

Encoded by nuclear genes then imported into the mitochondria afterwards.

*There are ribosomes present in the mitochondria for translation

Question 53

How do cytosolic ribosomes become membrane bound ribosomes?

Answer 53

• Attach to an mRNA that happens to encode a secretory protein
• translate mRNA and the first bit of protein produced is a stretch of hydrophobic amino acids called the signal sequence
• Signal recognition particle (SRP) binds to the signal sequence causing the ribosome to dock to the SRP receptor on ER
• protein fed into a translocation pore on the ER
• From now the newly synthesised protein is fed through the pore into the ER as it is translated
• Usually the amino acid terminal signal sequence is cut off as a translocation of the bulk of the protein occurs

Question 54

How is a secretory protein synthesised in the ER?

Answer 54

Translation through translocation channel and signal sequence is cut off. Once translocation is complete, the secretory protein is inside the ER and the translocation pore closes.

Question 55

How are transmembrane proteins produced by the ER?

Answer 55

• Translation/ translocation begin as a secretory protein until a stretch of approximately 20 consecutive hydrophobic amino acids (a transmembrane domain) is made.
• The reminder of the protein is synthesised by the ribosome but is not fed into the ER
• The hydrophobic stretch of amino acids leaves the translocation pore and embeds itself into the membrane.
• The ribosome finishes translation of the protein, releasing the C terminus into the cytosol.

Question 56

What are modifications made to the secretory pathway?

Answer 56

• ER proteins are folded, disulphide bridges are formed if present
• sugar side chains added if appropriate signals are present on proteins
• Some ER sugars are trimmed back from the trees and replaced with sugars added in the golgi apparatus

Question 57

How are disulphide linkages made between cysteine residues?

Answer 57

Cysteine residues contain a HS group, these lose their H+ group to form a link between the sulphides.

Question 58

What are examples of modifications that can happen when a transmembrane protein (e.g. insulin/LDL receptor) reaches the plasma membrane?

Answer 58

• Protein is anchored in the plasma membrane by the transmembrane domain
• Outside of the cell, trees of sugar units may have been added (‘glycosylation’)
• Disulphide bridges may have been formed

Question 59

What is prenylation?

Answer 59

Addition of hydrophobic compounds to proteins or chemical compounds

Question 60

What is the process of prenylation?

Answer 60

• The protein is made in cytosol with a particular amino acid sequence at the carboxyl terminus
• The presence of this sequence results in part of the carboxyl terminus being cleaved off and a fatty acid chain being transferred to the sulphur atom of a cysteine residue
• The fatty acid tail is believed to bury into the lipid bilayer

Question 61

What is an example of the sequence construct made to express human proteins in the mammary gland?

Answer 61

1) locus control of the B globin gene to insulate the transgene from the influence of other DNA sequences
2) 3kb of promoter sequences from the goat casein gene to ensure expression in the mammary gland
3) exons from the goat casein gene that contain untranslated regions
4) cDNA coding the protein to be expressed in and harvested from the milk
5) exons from the goat casein gene that contain untranslated regions
6) polyadenylation sequences from goat casein gene

Question 62

What is an example of a product producing human therapeutic proteins in cows and goats?

Answer 62

ATryn (Antithrombin Recombinant)

Question 63

What is a popular way of generating insulin for patients with diabetes?

Answer 63

Yeast can make human insulin