9700_m23_qp_22
A paper of Biology, 9700
Questions:
6
Year:
2023
Paper:
2
Variant:
2
Login to start this paper & get access to powerful tools
1
Table 1.1 lists cell structures that can be found in eukaryotic cells or prokaryotic cells. Some of these cell structures can be found in both types of cell. Complete the table using a tick (3) to show that the cell structure can be present in a particular type of cell and a cross (✗) to show that the cell structure cannot be present. Put a tick or a cross in every box. The top row has been completed for you. Table 1.1 cell structure eukaryotic cells prokaryotic cells nucleus ✗ Golgi body circular DNA 70S ribosome All cells have a cell surface membrane. shows a transmission electron micrograph of part of two adjacent animal cells, cell 1 and cell 2. R cell 1 cell 2 ×300 000 In the space provided, draw a diagram of the region in the box labelled R on . Your diagram should show the four dark lines. Label the diagram to identify what is shown by the dark lines and each of the three spaces between them. space for diagram: Mitogens are short chains of amino acids that function as cell-signalling molecules. Mitogens are released from secretory cells and travel in the blood to target cells, where the mitogens bind to cell surface receptors. The target cells respond by progressing from the G1 phase to the S phase of the mitotic cell cycle. Outline what happens in the G1 phase and S phase of the mitotic cell cycle. G1 phase S phase As a result of mutation, the production and release of mitogens into the blood can be greatly increased. Suggest a possible consequence for target cells of increased concentrations of mitogens in the blood.
1. Cell structure  →  1.2. Cells as the basic units of living organisms
5. The mitotic cell cycle  →  5.1. Replication and division of nuclei and cells
5. The mitotic cell cycle  →  5.2. Chromosome behaviour in mitosis
Open
2
Cysteine is an amino acid containing sulfur. shows the structure of the molecule formed by joining two cysteine molecules together. C C CH2 N C O O O H C CH2 SH H H H SH N H H Draw a circle around an R-group in the molecule shown in . Goblet cells in the human gas exchange system produce proteins called mucins. The ends of mucin molecules contain many cysteine residues. Mucin strands are formed by joining the ends of mucin molecules together through covalent bonds between R-groups. State the name of these covalent bonds. Mucin strands are transported out of the goblet cells and then absorb water to form mucus. Suggest and explain how mucin strands are transported out of the goblet cells. Cystic fibrosis is a genetic disease caused by a mutation in the human CFTR gene. This results in mucus that is thicker than normal. Suggest how thicker mucus interferes with the maintenance of healthy gas exchange surfaces in the lungs. Row 1 and row 2 of Table 2.1 show the DNA base sequences of part of the normal CFTR allele and the same part of a mutated CFTR allele. The base sequences shown are for the DNA strands used in the synthesis of RNA. When Table 2.1 is completed, row 3 will show the base sequence of the RNA synthesised from the same part of the mutated CFTR allele. Table 2.1 DNA base sequence of part of the normal CFTR allele T A G T A G A A A C C A DNA base sequence of part of the mutated CFTR allele T A G T A A C C A C A A RNA base sequence synthesised from the mutated CFTR allele The difference between the DNA base sequence in row 1 and the DNA base sequence in row 2 of Table 2.1 is caused by a single gene mutation. State the name of this type of gene mutation. Row 1 and row 2 in Table 2.1 show the DNA strands used in the synthesis of RNA. State the term used to describe the DNA strand that is used in the synthesis of RNA. Complete Table 2.1 to show the missing bases in row 3. The normal CFTR allele is approximately 189 000 base pairs in length. The CFTR polypeptide consists of only 1480 amino acids. Explain the reasons for this difference between the number of base pairs and the number of amino acids.
6. Nucleic acids and protein synthesis  →  6.1. Structure of nucleic acids and replication of DNA
6. Nucleic acids and protein synthesis  →  6.2. Protein synthesis
Open
3
is a diagram of an area of phloem tissue from a transverse section through the stem of a squash plant, Cucurbita pepo. X Y companion cell Cell X and cell Y in are sieve tube elements. Explain why cell X and cell Y have very different appearances in this transverse section. Sucrose is formed from the glucose synthesised by mesophyll cells in the leaves of C. pepo. Explain how companion cells are involved in the transfer of sucrose into phloem sieve tubes. Hydrogen bonding is important in the movement of water in xylem. Explain how hydrogen bonding occurs between two water molecules. Outline how hydrogen bonding is involved in water transport in the xylem of a plant stem. Hydrogen bonding between water molecules gives water a relatively high latent heat of vaporisation. Suggest why it is important to plants that water has a high latent heat of vaporisation.
7. Transport in plants  →  7.2. Transport mechanisms
4. Cell membranes and transport  →  4.2. Movement into and out of cells
Open
4
Tuberculosis (TB), influenza and polio are examples of infectious diseases. Explain what is meant by an infectious disease. Name a species of organism that causes TB. Immunity can be described as artificial or natural and passive or active. Name the type of immunity that a mother gives to her baby through breast milk. The influenza virus can mutate frequently to produce different strains of the virus. A new vaccine is often necessary to stimulate the production of new antibodies to these new strains. Explain why different antibodies need to be produced to give immunity to these new strains. Polio is a serious viral disease affecting young children. In 1996, polio caused paralysis in more than 75 000 children across Africa. A long-term vaccination programme allowed the World Health Organization (WHO) to declare that Africa was largely free of polio in 2020. Explain how vaccination programmes can help to control the spread of infectious diseases, such as polio. Antibiotics, such as penicillin, do not help to prevent the spread of viral diseases, such as polio. Explain why penicillin is not effective against viruses.
11. Immunity  →  11.2. Antibodies and vaccination
10. Infectious diseases  →  10.1. Infectious diseases
Open
5
Pneumonia is a severe lung disease that can interfere with gas exchange. A person with pneumonia can be connected to an ECMO machine. This machine performs the gas exchange functions of the lungs. A cannula is inserted into the right atrium and this takes blood to the ECMO machine. In the ECMO machine, blood is passed firstly to an artificial pump and then to an oxygenator, where gas exchange occurs. The blood is then warmed and returns by another cannula to the vena cava. Complete to show how the ECMO machine is connected to the right atrium and to the vena cava. Use a single line to represent each cannula. artificial pump oxygenator heater ECMO machine In the oxygenator, a partially permeable membrane separates the blood from air that has been enriched with extra oxygen. State the name of a structure in the gas exchange system that has the same function as the partially permeable membrane of the oxygenator. In the oxygenator, blood and oxygen-enriched air flow in opposite directions. Suggest and explain how the oxygenator carries out the functions of gas exchange that normally occur in the lungs. is a photomicrograph showing a transverse section of part of the human aorta. tunica media tunica externa ×16 Explain how the structure of the tunica media in is different from the structure of the tunica media in a muscular artery and relate the difference to the function of the aorta. Some biologists investigated the transport of carbon dioxide in the blood of Caiman latirostris, a type of reptile. The biologists found that when C. latirostris respires: • most of the carbon dioxide is converted into hydrogencarbonate ions in red blood cells • the hydrogencarbonate ions combine with haemoglobin inside the red blood cells • the hydrogencarbonate ions remain combined with haemoglobin until the blood reaches the lungs. Explain why the physiology of C. latirostris requires carbonic anhydrase. Explain why the physiology of C. latirostris does not require the chloride shift.
9. Gas exchange  →  9.1. The gas exchange system
Open
6
Collagen is the most common structural protein in vertebrates. Collagen provides the skin with flexibility and strength. Explain how the structure of a collagen fibre provides the skin with strength. The enzyme collagenase breaks down collagen. Collagenase has several important medical uses, such as in the treatment of burnt skin. Scientists investigated the effect of pH on the activity of collagenase at 37 °C. The results of their investigation are shown in . 4.0 percentage of maximum activity 6.0 8.0 10.0 5.0 7.0 pH 9.0
2. Biological molecules  →  2.3. Proteins
3. Enzymes  →  3.2. Factors that affect enzyme action
Open