Nucleotides and nucleic acids

Question 1

What is the name of the monomer that forms nucleic acids.

Answer 1

Monomer = Nucleotide

Question 2

DRAW the general structure of the monomer of nucleic acids and label it.

Answer 2

Check summary sheet 1.5

Question 3

Name the reaction and the bond formed between to monomers

Answer 3

Condensation reaction forms phosphodiester bonds between nucleotides.

Question 4

What does DNA stand for?

Answer 4

Deoxyribonucleic acid

Question 5

DRAW the general structure of DNA and label it

Answer 5

Check summary sheet 1.5

Question 6

Name the bonds present between the DNA nucleotides?

Answer 6

Phosphodiester bonds

Question 7

Name the bonds present between the complimentary base pairs?

Answer 7

Hydrogen bonds

Question 8

Explain how the structure of DNA is related to its functions (mark schemes can vary so write everything!)

Answer 8

Sugar-phosphate backbone –> Gives strength
Helix/Coiling –> Gives it a compact shape
Large Molecule –> Stores lots of information
Sequence of bases –> Allows information to be stored/codes for amino acids
Double helix with many hydrogen bonds –> Makes the DNA molecule stable
Double stranded/Two strands –> BOTH strands can act as templates during semi-conservative replication
Double helix –> Prevents the code being corrupted
Hydrogen bonds between the bases are weak and easily broken –> Allows the strands to be separated for replication and also for protein synthesis
Complementary base pairings –> Allows accurate replication

Question 9

What is meant by specific base pairing?

Answer 9

Each base is complementary to one other base – this is the one that it binds to.
Guanine and cytosine are complementary to each other and therefore ONLY bind to each other
Adenine and thymine are complementary to each other and therefore ONLY bind to each other

Question 10

What do we mean by ‘the strands are anti-parallel’?

Answer 10

The strands go in opposite directions. One strand goes in the 5’to 3’ direction the other goes in the 3’ to 5’ direction

Question 11

Describe the differences between DNA and RNA (5 marks)

Answer 11

DNA has A,T,C,G bases whereas RNA has A,U,C,G
DNA has a deoxyribose sugar whereas RNA has a ribose sugar
DNA is double stranded wheras RNA is single stranded
DNA is a large polymer RNA is a short polymer
DNA holds genetic information in the nucleus whereas RNA transports genetic information to the ribosome

Question 12

Describe the differences between DNA in prokaryotes and Eukaryotes

Answer 12

DNA in eukaryotes is coiled up around proteins called HISTONES whereas the DNA in prokaryotes is not
DNA in eukaryotes is linear whereas DNA in prokaryotes is circular
DNA in eukaryotes is found in a nucleus, whereas DNA in prokaryotes is in the cytoplasm

Question 13

A gene is a section of DNA located at a particular site on a DNA molecule, called its ______?

Answer 13

Locus

Question 14

What are genes?

Answer 14

Genes are a specific sequence of bases which can code for the amino acid sequence of a polypeptide or functional RNA (E.G. ribosomal RNA and tRNA)

Question 15

What is a triplet code?

Answer 15

3 bases on DNA are called a TRIPLET CODE 🡪 3 bases CODE for 1 amino acid. Each triplet codes for a SPECIFIC amino acid.

Question 16

What is the link between DNA bases, amino acids and a protein?

Answer 16

A sequence of bases codes for a sequence amino acids to form a polypeptide chain which can fold into a protein.

Question 17

What are introns?

Answer 17

non-coding DNA within a gene

Question 18

what are Non-coding multiple repeats?

Answer 18

non-coding DNA found between genes

Question 19

What are exons?

Answer 19

the coding section of a gene (i.e. the bit that codes for amino acids)

Question 20

Define universal

Answer 20

each triplet codes for the same amino acids in all organisms

Question 21

Define Non-overlapping

Answer 21

each base is only used in one triplet code

Question 22

Define Degenerate

Answer 22

Some amino acids are coded for by more than 1 triplet code/codon

Question 23

Define genome

Answer 23

the complete set of genes in a cell

Question 24

Why might changing the base sequence of a gene lead to a non-functional protein being formed?

Answer 24

Different base sequence 🡪 codes for a different sequence of amino acids (different primary structure) 🡪 Different hydrogen, ionic and disulphide bonding between R-groups 🡪 different tertiary structure 🡪 protein is a different shape so no longer functions

Question 25

Describe the process of DNA replication

Answer 25

DNA helicase causes H-bonds to break and strands to separate
Both strands act as templates
Free DNA nucleotides attach to each strand by
complementary base pairing (A binds with T and G binds with C)
H-bonds form between the complementary base pairs
DNA polymerase joins nucleotides on the new strand together (causes the covalent bond between the sugar and phosphate to form)

Question 26

Why is DNA replication described as being ‘semi-conservative’?

Answer 26

Because each new double helix is made of one old strand and one new strand of DNA

Question 27

Meselson and Stahl grew bacteria on a medium containing N15.. Why is this Nitrogen different to ‘normal’ nitrogen and why was it used? (What was the Nitrogen incorporated into in the bacteria?)

Answer 27

It is an isotope of nitrogen so it is more dense. This nitrogen was incorporated into the nitrogenous bases in the DNA

Question 28

They then moved the bacteria to a medium containing N14. When they took a sample of DNA from these bacteria after they had grown on the new medium for 1 generation, what did they notice about the density of the DNA compared with DNA from the original bacteria? Explain your answer.

Answer 28

The DNA from the bacteria which had grown on N14 for one generation was less dense than the DNA from bacteria that had only grown on N15.

Question 29

After a second generation on the N14 medium they found that they had DNA double helices of 2 different densities. Explain their finding:

Answer 29

Some of the DNA molecules were made of one strand of DNA that contained N15 and one strand of DNA that contained N14. Some of the DNA molecules were made of DNA in which both strands contained N14. These DNA molecules (with only N14 ) were less dense

Question 30

What chemical processes produces ATP?

Answer 30

Respiration

Question 31

What does ATP stand for?

Answer 31

Adenosine triphosphate

Question 32

Draw the molecule of ATP and label it

Answer 32

Check ss 1.6

Question 33

Write an equation to show how ATP releases energy

Answer 33

H2O + ATP –> <– ADP + Pi

Question 34

What is the name of the enzyme which catalyses the hydrolysis of ATP?

Answer 34

ATP hydrolase

Question 35

What does ADP stand for?

Answer 35

Adenosine diphosphate

Question 36

What is Pi? What happens to the ‘Pi’ that is released? What is its function in cells?

Answer 36

‘Pi’ is inorganic phosphate. It is the phosphate ion (which has the formula PO43-)
Phosphate can join onto molecules to make them more reactive
It has lots of uses in cells, e.g.
In the phosphate-sugar backbone of DNA and RNA
In phospholipids

Question 37

During which processes is ATP resynthesized? What sort of reaction is this? What is the name of the enzyme which catalyses the reaction?

Answer 37

ATP is synthesized primarily during respiration (also during photosynthesis)
This is a condensation reaction
The reaction is catalysed by ATPsynthase

Question 38

What are the key features of ATP which make it an excellent source of energy for cellular reactions? MEMORISE THIS!!!!!

Answer 38

It releases energy in small amounts
It is an immediate source of energy as it can release energy in just one step by breaking just one bond so it makes energy available rapidly
It can add a phosphate group (phosphorylates) other molecules to make them more reactive
It can be regenerated

Question 39

How is the structure of mRNA different to the structure of tRNA

Answer 39

1. mRNA does not have hydrogen bonds / base pairing, tRNA does;
   OR
   mRNA is linear / straight chain, tRNA is cloverleaf;
2. mRNA does not have an amino acid binding site, tRNA does;
3. mRNA has more nucleotides;
   accept mRNA is longer
4. (Different) mRNAs have different lengths, all tRNAs are similar / same length;
5. mRNA has codons, tRNA has an anticodon;

Question 40

Contrast the structures of DNA and mRNA

Answer 40

DNA double stranded/double helix and mRNA single-stranded;
DNA (very) long and RNA short;
Thymine/T in DNA and uracil/U in RNA;
Deoxyribose in DNA and ribose in RNA;
DNA has base pairing and mRNA doesn’t/ DNA has hydrogen bonding and mRNA doesn’t;
DNA has introns/non-coding sequences and mRNA doesn’t;

Question 41

Describe and explain how the structure of DNA results in accurate replication. [6]

Answer 41

1 two strands therefore semi-conservative replication (possible);
2 base pairing/hydrogen bonds holds strands together
3 hydrogen bonds weak/easily broken, allow strands to separate;
4 bases (sequence) (exposed so) act as template /can be copied;
5 A with T, C with G / complementary copy;
6 DNA one parent and one new strand;

Question 42

Describe the role of two named enzymes in the process of semi-conservative replication of DNA [3]

Answer 42

1. (DNA) helicase causes breaking of hydrogen/H bonds (between DNA strands);
   Reject ‘helicase hydrolyses hydrogen bonds’.
2. DNA polymerase joins the (DNA) nucleotides;

Reject if suggestion that DNA polymerase joins the complementary nucleotides or forms H bonds.
Reject if joining RNA nucleotides or forming RNA.

3. Forming phosphodiester bonds;

Question 43

explain why new nucleotides can only be added in a 5’ to 3’ direction.

Answer 43

DNA polymerase;
(Which is) specific;
Only complementary with/binds to 5’ end (of strand);
Shapes of 5’ end and 3’ end are different;

Question 44

Compare and contrast the DNA in eukaryotic cells with the DNA in prokaryotic cells. [5]

Answer 44

Comparisons
Nucleotide structure is identical;
Nucleotides joined by phosphodiester bond;
OR
Deoxyribose joined to phosphate (in sugar, phosphate backbone);
DNA in mitochondria / chloroplasts same / similar (structure) to DNA in prokaryotes;
Accept shorter than nuclear DNA/is circular not linear/is not associated with protein/histones unlike nuclear DNA;

Contrasts
Eukaryotic DNA is longer;
Eukaryotic DNA contain introns, prokaryotic DNA does not;
Eukaryotic DNA is linear, prokaryotic DNA is circular;
Eukaryotic DNA is associated with / bound to protein / histones, prokaryotic DNA is not;