4A - DNA, RNA And Protein Synthesis

Question 1

Is the structure of DNA the same in all organisms?

Answer 1

Yes, but eukaryotic and prokaryotic cells store DNA in different ways.

Question 2

Describe (nuclear) eukaryotic DNA.

Answer 2

• DNA molecules are LONG and LINEAR
• Wound around proteins called HISTONES
• The DNA and proteins are then coiled up tightly to make a compact chromosome
• Chromosomes exist in the nucleus

(See diagram pg 82 of revision guide)

Question 3

Describe prokaryotic DNA.

Answer 3

• DNA molecules are SHORT and CIRCULAR
• Not wound around histones, but do form chromosomes
• Chromosomes fit in cell by supercoiling

(See diagram pg 82 of revision guide)

Question 4

Compare nuclear eukaryotic DNA and prokaryotic DNA.

Answer 4

EUKARYOTIC:
• Linear
• Long
• Associated with histones 
PROKARYOTIC:
• Circular
• Short
• Not associated with histones

Question 5

What are histones?

Answer 5

Proteins around which nuclear eukaryotic DNA is wound.

Question 6

What is the purpose of histones?

Answer 6

• Winding of eukaryotic DNA around the histones makes it more compact
• Histones support the DNA

Question 7

Describe the process by which nuclear eukaryotic DNA is stored.

Answer 7

1) DNA is in a double helix with a linear shape.
2) DNA is wound around histone proteins.
3) DNA with the histones is coiled up repeatedly -> Makes a single chromosome.

Question 8

What are the two types of DNA in eukaryotic cells?

Answer 8

• Nuclear DNA

* Mitochondrial / Chloroplast DNA

Question 9

Compare nuclear and mitochondrial/chloroplast DNA in eukaryotes.

Answer 9

• Nuclear -> Linear, long + associated with histones
• Mitochondrial/Chloroplast -> Circular, short + not associated with histones

(i.e. The DNA in mitochondria and chloroplasts is like prokaryotic DNA.)

Question 10

By what process is prokaryotic DNA made to fit in the cell?

Answer 10

Supercoiling

Question 11

Describe the process by which prokaryotic DNA is stored.

Answer 11

1) DNA is in a double-helix.
2) The double helix is in a circular chromosome shape.
3) Chromosome is coiled.
4) The DNA is then supercoiled to fit in the cell.

Question 12

What is a gene?

Answer 12

A sequence of DNA bases that codes for either a polypeptide or functional RNA.

Question 13

What are the two things a gene can code for?

Answer 13

• Polypeptide

* Functional RNA

Question 14

What is the primary structure of a protein?

Answer 14

The order of amino acids in its polypeptide chains.

Question 15

How does the order of DNA bases in a gene code for the polypeptide produced?

Answer 15

• 3 bases in the DNA code for one amino acid in the chain

* The order of bases in a gene determines determines the order of amino acids in a polypeptide

Question 16

What is a triplet?

Answer 16

The three DNA bases in a gene that code for a single amino acid.

Question 17

What is functional RNA?

Answer 17

• RNA molecules other than mRNA (!), which perform special tasks during protein synthesis.
• e.g. tRNA and rRNA

Question 18

Is mRNA a type of functional RNA?

Answer 18

No

Question 19

Give two examples of functional RNA.

Answer 19

• tRNA

* rRNA

Question 20

What is a cell’s genome?

Answer 20

The complete set of genes in the cell.

Question 21

What is a cell’s proteome?

Answer 21

The full range of proteins that the cell is able to produce.

Question 22

Do all parts of eukaryotic genes code for amino acids?

Answer 22

No, some parts are non-coding (introns).

NOTE: Some genes as a whole don’t code for polypeptides, but functional RNA.

Question 23

What are introns and exons?

Answer 23

• Introns -> Sections of genes that don’t code for amino acids
• Exons -> Sections of genes that do code for amino acids

Question 24

How can you remember the difference between introns and exons?

Answer 24

EXons - EXpressed

INtrons - stay IN

Question 25

Does prokaryotic DNA have introns?

Answer 25

No

Question 26

What happens to introns in DNA?

Answer 26

• They are removed from pre-mRNA in a process called splicing -> After transcription.
• This leaves only the exons.

Question 27

Apart from genes, what does a DNA sequence contain?

Answer 27

Non-coding repeats

Question 28

What are non-coding repeats?

Answer 28

• DNA sequences outside of genes that don’t code for amino acids (similar to introns, but outside of genes)
• e.g. CCTTCCTTCCTT

Question 29

Describe all the different parts of a DNA sequence.

Answer 29

DNA sequence is split into genes and non-coding repeats.

NON-CODING REPEATS:
• Outside of genes -> Don’t code for amino acids

GENES:
• Genes code for either a polypeptide OR functional RNA
• If they code for a polypeptide, they are split into coding parts (exons) and non-coding parts (introns)
• If they code for functional DNA, they can code for tRNA, rRNA, etc. -> Needed in protein synthesis

Question 30

What are alleles?

Answer 30

• Different types of the same gene
• Code for slightly different versions of the same polypeptide
• e.g. The allele for blue eyes and the allele for brown eyes

Question 31

How many chromosomes do humans have?

Answer 31

23 pairs (or 46 in total)

Question 32

What is a homologous pair?

Answer 32

• A pair of matching chromosomes of the same side and containing the same genes (although they oils have different alleles).
• e.g. The 21st pair of chromosomes in humans

Question 33

What structure does “homologous pair” refer to?

Answer 33

Chromosomes (not genes or alleles!)

Question 34

Give an example of a homologous pair.

Answer 34

The 21st pair of chromosomes in humans.

Question 35

Do homologous pairs have to have the same alleles?

Answer 35

No, but they need to have the same genes and be the same size.

Question 36

What is the position of a gene on a chromosome called?

Answer 36

The locus.

Question 37

What can be said about the position of alleles coding for a certain characteristic in a chromosome?

Answer 37

They will be found at the same locus.

Question 38

Remember to revise the diagram of homologous chromosomes on pg 83.

Answer 38

Do it.

Question 39

What does uracil pair with in protein synthesis?

Answer 39

Adenine

Question 40

What is the difference between DNA and RNA?

Answer 40

• DNA is a double-helix, while RNA is a single polynucleotide strand
• DNA contains thymine, while RNA contains uracil as a base

Question 41

What are the two types of RNA involved in protein synthesis?

Answer 41

• Messenger RNA (mRNA)

* Transfer RNA (tRNA)

Question 42

What does the m in “mRNA” stand for?

Answer 42

Messenger

Question 43

What does the t in “tRNA” stand for?

Answer 43

Transfer

Question 44

What are the two stages of protein synthesis?

Answer 44

• Transcription

* Translation

Question 45

What is the function of mRNA?

Answer 45

• Made during transcription

* Carries the genetic code from the DNA to the ribosomes, ready for translation

Question 46

Describe the structure of mRNA.

Answer 46

• Single polynucleotide strand -> Ribose sugar - phosphate backbone with bases attached
• Appears linear

(See diagram pg 84 of revision guide)

Question 47

What are 3 adjacent bases on mRNA called?

Answer 47

Codons (sometimes triplets or base triplets)

Question 48

What is the function of tRNA?

Answer 48

• Involved in translation

* Carries amino acids (used to make proteins) to the ribosomes

Question 49

Describe the structure of tRNA.

Answer 49

• Single polynucleotide strand -> Folded into a clover shape
• Hydrogen bonds between specific base pairs hold the molecule in this shape
• Specific sequence of three bases at one end (anticodon)
• Amino acid binding site at other end

(See diagram pg 84 of revision guide)

Question 50

What is the specific set of 3 bases at the bottom of a tRNA molecule called?

Answer 50

An anticodon.

Question 51

Remember to practise drawing out the structure of mRNA and tRNA.

Answer 51

Pg 84 of revision guide.

Question 52

What holds a tRNA molecule in its clover shape?

Answer 52

Hydrogen bonds between specific bases pairs.

Question 53

In brief, what is transcription?

Answer 53

The process by which an mRNA copy of a gene is made from DNA, so it can be taken to ribosomes.

Question 54

Where do transcription and translation happen?

Answer 54

• Transcription -> In the nucleus (except in prokaryotes)

* Translation -> Ribosomes in the cytoplasm

Question 55

Where does transcription take place in prokaryotes?

Answer 55

In the cytoplasm, because they have no nucleus.

Question 56

Describe transcription.

Answer 56

1) RNA polymerase attaches to the DNA double-helix at the beginning of a gene.
2) Hydrogen bonds between the two DNA strands break, separating the strands -> DNA uncoils partly -> Bases exposed
3) One strand is used as a template to make an mRNA copy.
4) Free RNA nucleotides move in and pair with exposed complementary bases on the DNA strand -> NOTE: Each nucleotide has only one base on it.
5) RNA polymerase moves along the strand joining the sugar-phosphate backbone to create a pre-mRNA molecule.
6) DNA is separated from the pre-mRNA strand.
7) DNA strands rejoin after RNA polymerase has passed.
8) When RNA polymerase reaches a stop signal, it detaches from the DNA.

Question 57

Is an mRNA nucleotide a chain?

Answer 57

• No, a NUCLEOTIDE is just a SINGLE structure of ribose, phosphate and 1 vase.
• An mRNA MOLECULE is a log chain of RNA nucleotides.

Question 58

What enzyme is involved in transcription?

Answer 58

RNA polymerase

Question 59

Describe the pre-mRNA molecule produced by transcription.

Answer 59

It is complementary copy to the original DNA strand.

Question 60

What are 3 adjacent bases called on:
• DNA
• mRNA
• tRNA

Answer 60

• DNA - Triplet
• mRNA - Codon
• tRNA - Anticodon

Question 61

In transcription, what do these bases become:
• A
• C
• G
• T

Answer 61

• A -> U
• C -> G
• G -> C
• T -> A

Question 62

What does RNA polymerase do?

Answer 62

• Unwinds the DNA double-helix + exposes bases

* Joins the free RNA nucleotides to together by their sugar-phosphate backbone

Question 63

What happens to pre-mRNA after transcription is finished in eukaryotes and prokaryotes?

Answer 63

• Eukaryotes -> It is spliced and then moves out of the nucleus through a nuclear pore.
• Prokaryotes -> None of this.

Question 64

Compare the products of transcription in eukaryotes and prokaryotes.

Answer 64

• Eukaryotes -> Both introns and exons are copied -> Splicing must happen
• Prokaryotes -> No introns in prokaryotic DNA -> No need to splice

Question 65

When does splicing happen?

Answer 65

After transcription.

Question 66

How much DNA codes for a single polypeptide?

Answer 66

A gene.

Question 67

Does splicing happen in prokaryotes?

Answer 67

No, because the DNA has no introns.

Question 68

What is the difference between pre-mRNA and mRNA?

Answer 68

• Pre-mRNA has both introns and exons.

* mRNA has only exons.

Question 69

Where does splicing take place?

Answer 69

In the nucleus, before the mRNA leaves it.

Question 70

What is splicing?

Answer 70

Removing introns from pre-mRNA to form mRNA that has just exons.

Question 71

Describe the entire process to remove introns.

Answer 71

• DNA strand has introns and exons
• Pre-mRNA made that has introns and exons (transcription)
• Introns removed (splicing)
• Mature RNA is made that has only exons

Question 72

In brief, what is translation?

Answer 72

When ribosomes join amino acids together to make a polypeptide chain following the sequence of codons carried by the mRNA.

Question 73

Describe translation.

Answer 73

1) Ribosome attaches to the first codon of a ribosome and free tRNA molecules move towards it, carrying amino acids. (ATP provides energy for bond between amino acid and tRNA molecule to form.)
2) tRNA molecule with an anticodon that’s complementary to the first codon on the mRNA attaches itself to the mRNA by specific base pairing.
3) A second tRNA attaches itself to the next codon in the same way.
4) The two amino acids carried by the two tRNA molecules are joined by a peptide bond -> Using an enzyme and ATP.
5) This repeats over the next codons.
6) As ribosome moves onto the third codon, joining the second and third amino acids, the first tRNA molecule is released and moves away.
7) This repeats, creating a polypeptide chain, until there’s a stop signal on the mRNA molecule.
8) The polypeptide chain moves away from the ribosome.
9) Several ribosomes can pass over the mRNA in succession.

Question 74

Describe the corresponding mRNA codon and tRNA anticodon for this DNA triplet: ATC.

Answer 74

• DNA = ATC
• mRNA = UAG
• tRNA = AUC

Question 75

What allows translation to happen?

Answer 75

A ribosome.

Question 76

What does a ribosome do in translation?

Answer 76

Join adjacent amino acids carried by tRNA together with peptide bonds.

Question 77

What is needed for the peptide bonds to be formed between amino acids in translation?

Answer 77

• Enzyme

* ATP

Question 78

Remember to practise drawing and writing out the transcription and translation process.

Answer 78

Pg 84 and 85 of the revision guide.

Question 79

What is the genetic code?

Answer 79

The sequence of base triplets (codons) in mRNA which code for specific amino acids.

Question 80

What are the important characteristics of genetic code?

Answer 80

• Non-overlapping
• Degenerate
• Universal

Question 81

What does non-overlapping mean in terms of genetic code?

Answer 81

• Each triplet is read in sequence, separate from the triplet before and after it.
• Triplets don’t share their bases.

Question 82

What does degenerate mean in terms of genetic code?

Answer 82

• There are more possible combinations of triplets than there are amino acids.
• So some amino acids are coded for by more than one triplet.

Question 83

How many amino acids and possible base triplets are there?

Answer 83

• Amino acids - 20
• Triplets - 60

This means that genetic code is degenerate.

Question 84

What does universal mean in terms of genetic code?

Answer 84

• The same specific base triplets code for the same amino acids in all living things.
• e.g. UAU codes for tyrosine in all organisms.

Question 85

Do all base triplets code for an amino acid?

Answer 85

No, some are start or stop signals.

Question 86

What are start or stop codons?

Answer 86

Triplets in mRNA that are used to tell the cell where to start and stop the production of the protein.

Question 87

Given a table of mRNA codons with their corresponding amino acid, what questions could you be asked?

Answer 87

• Give the corresponding DNA sequence for each amino acid
• Give the tRNA anticodons from mRNA codons
• Write the amino acid sequence for a section of mRNA

Question 88

Given these mRNA codons, give the corresponding DNA triplets.
• UCU
• CUA
• UAU
• GUG
• GCA
• CGC

Answer 88

• UCU -> AGA
• CUA -> GAT
• UAU -> ATA
• GUG -> CAC
• GCA -> CGT
• CGC -> GCG

Question 89

Given these mRNA codons, give the corresponding tRNA anticodons.

Answer 89

• UCU -> AGA
• CUA -> GAU
• UAU -> AUA
• GUG -> CAC
• GCA -> CGU
• CGC -> GCG

Question 90

Given this table of mRNA codons and corresponding amino acids...
• UCU - Serine
• CUA - Leucine
• UAU - Tyrosine
• GUG - Valine
• GCA - Alanine
• CGC - Arginine
...work out the amino acid sequence for this section of mRNA:
CUAGUGCGCUAUUCU

Answer 90

Leucine, Valine, Arginine, Tyrosine, Serine

Question 91

In an investigation of a drug that prevents protein synthesis, the concentration of proteins and mRNA was measured. The concentration of both proteins and mRNA was decreased compared to a control. Suggest what the drug does.

Answer 91

• Inhibits the production of mRNA (transcription) which in turn stops proteins being produced (translation).
• e.g. Could be an enzyme that digests mRNA

Question 92

In an investigation of a drug that prevents protein synthesis, the concentration of proteins and mRNA was measured. The concentration of both proteins was decreased compared to a control, but protein concentration was the same. Suggest what the drug does.

Answer 92

• Inhibits translation, but leaves mRNA untouched -> So no protein can be produced
• e.g. Could be something that binds to the ribosome, blocking tRNAs from binding to it, preventing translation.

Question 93

Remember to practise interpreting data about the role of nucleus acids.

Answer 93

Pg 87 of revision guide