5. Nucleic acids and their functions

Question 1

nucleotide

Answer 1

Question 2

A nucleoside

Answer 2

a pentose sugar joined to a nitrogenous base: adenosine is composed of ribose bonded to adenine. This nucleoside is a component of ATP (adenosine triphosphate).

Question 3

bases in DNA

Answer 3

adenine, thymine, guanine or cytosine.

Question 4

bases in RNA

Answer 4

adenine, uracil, guanine or cytosine.

Question 5

diagram of ATP

Answer 5

Question 6

Answer 6

Question 7

how is ATP formed

Answer 7

endergonic reaction (a reaction which uses energy).

ADP and phosphate (Pi) are combined to form ATP. The energy to form the bond comes from exergonic (energy releasing reactions) in cellular respiration. The reaction is a condensation reaction; water is eliminated when the bond is formed. An enzyme that catalyses this reaction is ATP synthetase.

ATP can be hydrolysed to ADP and Pi, this reaction releases energy. The enzyme that catalyses this reaction is ATPase. 30.6 kJmol-1 energy is released when ATP is converted to ADP and Pi.

Question 8

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ATP (adenosine triphosphate) is vital to organisms because

Answer 8

it acts as an energy carrier and releases energy efficiently

Question 9

Importance of ATP Hydrolysis

Answer 9

Single-step Energy Release:

The energy is made available almost immediately because only one reaction is required.
This makes ATP an efficient and rapid energy source for cellular processes.
Controlled Release:

The amount of energy released (~30.5 kJ/mol) is manageable for the cell, preventing wastage or damage that might occur with larger energy releases.
Catalysis by ATPase:

ATPase ensures that the hydrolysis is specific and occurs only when and where the energy is needed in the cell.
This enzymatic control helps direct energy to specific biological processes, like muscle contraction or active transport.
Universal Energy Currency:

ATP is used universally in all types of cells, making it a convenient molecule for transferring energy between different biochemical pathways.
By providing energy in a quick and controlled manner, ATP hydrolysis underpins many essential processes in living organisms, including metabolism, movement, and homeostasis.

Question 10

hydrolysis of ATP reaction

Answer 10

Question 11

when in ATP synthesized

Answer 11

when energy is avaliable

this has the advantage of converting the energy into a single useable form.

Cells use energy for active transport, protein synthesis, cell division and muscle contraction.

Question 12

Answer 12

Question 13

ATP characteristics

Answer 13

As ATP is relatively small and is soluble, it can easily be transported in cells to where it is required.

Question 14

ATP hydrolase vs ATPase

Answer 14

For A-level biology, it’s most accurate to refer to the enzyme specifically involved in the breakdown of ATP as ATP hydrolase in the context of simple ATP hydrolysis. However, ATPase is also commonly used when discussing processes where ATP hydrolysis is coupled to specific cellular functions.

Question 15

ATP AND ADP diagram

Answer 15

Question 16

two main categories of base in nucleic acids

Answer 16

purines and pyrimidines

Question 17

purine bases

Answer 17

guanine and adenine; these have a double ring in their structure.

Question 18

pyrimidines

Answer 18

thymine, cytosine and uracil. They have a single ring.

Question 19

Edwin Chargaff investigated the proportions of the bases in DNA. His results demonstrated that:

Answer 19

the percentage of purines was always equal to that of pyrimidines
the percentage of adenine was equal to that of thymine
the percentage of guanine was equal to that of cytosine.

Question 20

G and C bonds

Answer 20

Guanine (G) and cytosine (C) are linked by three hydrogen bonds.

Question 21

A and T bonds

Answer 21

Adenine (A) and thymine (T) are linked by two hydrogen bonds.

Question 22

Answer 22

Question 23

Answer 23

Question 24

Answer 24

Question 25

DNA has two functions in cells:

Answer 25

DNA contains a base sequence that codes for amino acids in protein synthesis.

replicating prior to cell division so that each daughter cell is genetically identical to the parent cell

Question 26

polynucleotide

Answer 26

polymer of nucleotides

Question 27

how are sugar phosphates linked in DNA

Answer 27

sugar-phosphate molecules are joined by condensation reactions, making a phosphodiester linkage.

The sugar-phosphate molecules form the two sugar-phosphate ‘backbones’ of the molecule. T

Question 28

how are the two strands of DNA joined

Answer 28

The two strands are joined by hydrogen bonds between the complementary base pairs (A-T and C-G).

Question 29

antiparallel meaning DNA

Answer 29

Question 30

RNA

Answer 30

is a single stranded polynucleotide. The pentose sugar is ribose, the base uracil is present instead of thymine. RNA is a relatively short-lived molecule and is also shorter than DNA.

Question 31

There are three types of RNA, each type is involved in protein synthesis:

Answer 31

Ribosomal RNA

Messenger RNA

Transfer RNA

Question 32

Ribosomal RNA

Answer 32

Question 33

Messenger RNA

Answer 33

Question 34

Transfer RNA (tRNA)

Answer 34

Question 35

Which of these are structural differences between RNA and DNA?

Answer 35

RNA has uracil and DNA has thymine.
RNA has ribose and DNA has deoxyribose.

Question 36

label

Answer 36

Question 37

What type of nucleic acid is shown in the image?

Answer 37

tRNA

Question 38

The main steps in extracting DNA from cells are:

Answer 38

Crush or blend the source cells in detergent, salt and water to release the DNA.
Filter the cell debris and collect the extract.
Pour ice-cold alcohol down the side of the tube containing the extract.
The DNA precipitates at the junction of the extract and alcohol.
DNA can be stained red using acetic orcein.

Question 39

Risk assessment:

Extracting DNA

Answer 39

**90% alcohol can be a skin irritant and is volatile, so it could affect the nose and throat. Use it in a well-ventilated area and wear safety goggles.

Acetic orcein contains ethanoic acid, and corrosion of skin or eyes is a risk. Transfer it using a dropper and wear safety goggles.**

Question 40

Meselson and Stahl: models of replication

They proposed three possible mechanisms for DNA replication and tested them out in the experiment. The three possible mechanisms were:

Answer 40

Conservative replication: the DNA molecule would be copied from the original, leaving the original DNA molecule as it was and having a new copy.
Dispersive replication: sections of the DNA molecule would be copied and spliced together, making each new DNA molecule a mix of original and new DNA.
Semi-conservative replication: the two polynucleotide chains would part, and new nucleotides attach to each of the chains, leading to each new molecule having one original chain and one new one.

Question 41

Meselson and Stahl

Diagram

Answer 41

Question 42

Meselson and Stahl

Experiment

Intro

Answer 42

used E.coli bacteria as the source of DNA. E.coli are easily grown in a flask of culture medium and replicate their cells (and DNA) every 20 minutes under optimal conditions.

‘New’ and ‘original’ nucleotides were distinguished by the isotope of nitrogen (N) in the nitrogenous bases. 15N is heavier in mass than 14N, so DNA molecules containing bases with 15N and DNA molecules containing 14N can be separated by mass in centrifugation.

Question 43

Meselson and Stahl

Experiment

First Step

Answer 43

First, the scientists grew E.coli in a culture medium with only 15N isotopes until, after many generations, all of the bases contained 15N. When a sample was centrifuged, the band of DNA molecules was near the bottom of the tube, as shown in the diagram below. This is because 15N is heavier, so it settles at the bottom of the tube.

Question 44

Meselson and Stahl

Experiment

Second Step

Answer 44

Question 45

Meselson and Stahl

Experiment

Last Step

Answer 45

Question 46

Meselson and Stahl

Experiment

Conclusion

Answer 46

This first generation showed that replication was not conservative but that each new DNA molecule produced by replication consisted of half new (14N) nucleotides and half original (15N) nucleotides.

Question 47

Answer 47

Question 48

Answer 48

Question 49

Eliminating the dispersive model

Answer 49

Question 50

Meselson and Stahl Relative Density of DNA

Answer 50

Question 51

As Meselson and Stahl demonstrated in their experiment, DNA replication happens by a semi-conservative mechanism.

Answer 51

DNA helicase breaks the hydrogen bonds holding the two polynucleotide chains together. The area where the helicase works is a ‘replication fork’.

DNA polymerase joins new nucleotides to their complementary bases by catalysing the formation of phosphodiester bonds between the deoxyribose and phosphate groups working from the 5’ to 3’ direction. The original polynucleotide chains act as a template for the aligning of new nucleotides.

Question 52

mechanism of DNA replications

Answer 52

Question 53

trascription

Answer 53

DNA holds the code for proteins in the base sequence. DNA is confined to the nucleus.

The code is transferred from the nucleus to the cytoplasm by means of messenger RNA (mRNA).

The gene is unwound and unzipped by DNA helicase; this means that the hydrogen bonds between the two polynucleotide chains are broken. The bases are exposed. One chain acts as a template for the formation of mRNA.

RNA nucleotides align opposite their complementary base pairs. G on DNA pairs to C RNA nucleotides, C on DNA to G, T on DNA to A and A on DNA to Uracil (U) nucleotides. RNA polymerase joins the nucleotides together, condensing the ribose phosphate backbone. A pre-mRNA molecule is formed. The pre-mRNA leaves the DNA when a stop sequence is reached.

Question 54

Post-transcriptional modification

Answer 54

involves the removal of introns (these remain inside the nucleus). The exons are spliced together.

In 1945, the ‘one gene one enzyme hypothesis’ was proposed; it was thought that genes coded only for enzymes which catalysed the production of other proteins. In the 1950s, work on haemoglobin demonstrated that genes also code for other proteins leading to a modification of the hypothesis. The one ‘gene one polypeptide hypothesis’ is that each gene is transcribed and then translated into single polypeptide. This is now thought to be too simplistic, as exons can be spliced in different orders forming different types of mRNA from one pre-mRNA. As the code is different, different proteins will be made, which refutes the one gene one polypeptide hypothesis. Once spliced, the mRNA is called functional mRNA. The exons joined into functional mRNA exit the nucleus through a nuclear pore and attach to ribosomes.

In the diagram below, the exons are represented by boxes.

Question 55

gene

Answer 55

a section of DNA that codes for a polypeptide

Question 56

eukaryotes genes vs prokaryotes genes

Answer 56

In eukaryotes, genes contain introns and exons. Exons are the coding parts and introns the non-coding parts. Prokaryotes do not have introns; their genes are continuous.

Question 57

Answer 57

Question 58

Answer 58

Question 59

Translation

Answer 59

Every three bases on mRNA is called a codon. The mRNA joins to a ribosome at the ‘start’ codon. The ribosome can accommodate two codons.

Transfer RNA (tRNA) in the cytoplasm is activated. The correct amino acid is attached to the amino acid binding site. Which amino acid is attached is determined by the anticodon; this is a sequence of three bases, represented by X on the diagram below. This process uses energy from ATP.

tRNA molecules carrying amino acids collide with the codons on mRNA. If the anti-codon and codon are complementary, a codon/anticodon complex can form, as the complementary bases form hydrogen bonds. When two tRNA molecules occupy both ribosome sites, the amino acids are brought close enough to form a peptide bond.

The ribosome moves along the mRNA by one codon. The first tRNA is released from the amino acid and ribosome and returns to the cytoplasm to be reactivated.

Another amino acid is attached, and the ribosome moves on to the next codon. This process happens until a ‘stop’ codon is reached. At the stop codon, the polypeptide chain leaves the ribosome to move to the Golgi body for modification.

In the Golgi body the polypeptide can be folded to make a protein. It may have non-protein (prosthetic) groups joined to it, like carbohydrate, lipid or phosphate. Some polypeptides may be combined to form quaternary structure proteins. Haemoglobin, for example, has four combined polypeptide chains and a prosthetic haem group. The diagram below illustrates transcription and translation.

Question 60

Answer 60

GCG

Question 61

Answer 61

Question 62

Answer 62

Question 63

triplet code

Answer 63

The genetic code is a triplet code, that means that three bases on DNA code for one amino acid. Codons are three bases on mRNA and anticodons are three bases on tRNA. The anticodon determines which specific amino acid is carried by the tRNA. The code is a triplet code, as three bases in the code give enough combinations to code for all 20 amino acids. Two bases would only give 42 = 16 different codes. Three bases give 43 = 64 codes.

Question 64

How do mutations alter the DNA sequence

Answer 64

Mutations alter the DNA sequence and therefore the codon sequence. Mutations may not have an effect on the amino acid sequence because the code is degenerate, the new code may code for the same amino acid. If the changed code changes the amino acid, the protein may fold differently and be non-functional.

Question 65

advantage of the genetic code being universal

Answer 65

The genetic code is universal and is the same in all living things, so each specific codon codes for the same amino acid in all species. It is a linear code with no overlaps, so it can be ‘read’ without any ambiguity.

Question 66

Answer 66

Question 67

Answer 67

Question 68

Answer 68

Question 69

EXTRACTING DNA whiteboard

Answer 69

Question 70

SEMI CONSERVATIVE REPLICATION whiteboard

Answer 70

Question 71

Meselson and Stahl 3 Models WHITEBOARD

Answer 71

Question 72

Meselson and Stahl Experiment

Answer 72