UNIT FOUR Reading Guide

  1. Other than digested food molecules, what other substances are transported in the blood?
  1. What are the functions of the following components of blood:

Plasma

Platelets

Erythrocytes

Leukocytes

  1. Draw and label a simple diagram of the heart showing:

Right and left atria and ventricles, atrio-ventricular and semi-lunar valves, aorta, pulmonary artey, pulmonary vein, vena cava and cardiac muscle.

  1. Where is the cardiac muscle thickest? Why?
  1. Distinguish between oxygenated and deoxygenated blood.
  1. Outline the journey of a single red blood cell taking one full circuit of the transport system, starting and finishing at the liver. You could use a flow chart/cycle for this.
  1. Why is the flow of blood described as double circulation?
  1. What is a myocyte?
  1. Explain the myogenic origin of the heartbeat.
  1. Name and label the parts of the heart responsible for initiation and propagation of the heart beat.
  1. What is meant by the term indefatigable?
  1. Complete a flow chart to show how heart rate changes with exercise.

Include the roles of the blood, medulla oblongata, nerves, SA node and the Vagus nerve.

  1. What is the effect of the hormone adrenalin?
  1. Compare the structure and functions of these blood vessels:

Artery / Capillary / Vein
Diagram
(labeled, cross section)
Function
Travels… / From… / Through … / To …
How is structure related to function?

15. Define cell respiration.

16. What are the reactants of cell respiration?

17. What are the products of cell respiration?

18. In the space below, draw a simplified diagram of the structure of ATP.

Label the location of the high-energy bond.

19. Explain why ATP is a more useful store of energy within living organisms than glucose.

20. In which two parts of the cell does aerobic cell respiration take place?

21. Define aerobic.

22. Define anaerobic.

23. Label the diagram of aerobic cell respiration below.

24. Label the diagram of anaerobic cell respiration below.

25. Complete the table below, comparing aerobic and anaerobic respiration.

Aerobic / Anaerobic
Hexose sugar in
Oxygen in
2 ATP produced
Pyruvate as an intermediate
Animals / Yeast
Carbon dioxide produced
Water produced

26. Complete the table below summarizing the events of aerobic cell respiration.

Reaction / Location / Purpose / ATP yield
Glycolysis / 2
Matrix of the mitochondrion / Convert pyruvate (3C) to acetyl CoA (2C) / 0
Krebs Cycle
Inner mitochondrial membrane
Oxidative phosphorylation

27. Many reactions in living things can be classified as either oxidation or reduction reactions.

These are particularly important in cell respiration and photosynthesis.

Complete the table below to compare oxidation and reduction reactions.

OXIDATION / REDUCTION
Electrons are… / lost
Oxygen is…
Hydrogen is…

28. Define phosphorylation.

29. List two ways in which phosporylation is used in cell respiration.

30. In the space below, draw a diagram to show the process of glycolysis.

Include phosporylation, lysis, oxidation and ATP formation.

31. Draw and label a diagram showing the structure of the mitochondrion as seen in a TEM

image. Include the inner and outer mitochondrial membranes, matrix, christae, mitochondrial DNA and ribosomes and a scale bar.

32. Complete the table below with the functions of the structures of the mitochondrion.

How is each structure adapted to help maximize efficiency of respiration?

Structure: / Function: / Adapted to increase efficiency by:
Outer membrane
Inner membrane
(including christae)
Matrix
Mitochondrial DNA and ribosomes
Inter-membrane space

33. Explain the link reaction, including oxidative decarboxylation and conversion of pyruvate to

acetylCoA and CO2.

34. The link reaction produces Acetyl CoA (2C) from the input substrate (usually pyruvate). The

extra carbon is released as carbon dioxide. Acetyl CoA can also be produced from fatty acids. When the fatty acid chain contains an even number of carbons, no CO2 is released.

How many Acetyl CoA molecules can be produced with the following fatty acids?

  1. 23C
  2. 18C
  3. 31C

35. What is an electron carrier?

36. Name two electron carriers that are used in cell respiration.

37. Where do the electron carriers produced in the link reaction and the Krebs cycle go?

38. In the space below, draw a diagram of the Krebs cycle.

Include formation of citrate, oxidation, decarboxylation, substrate-level phosphorylation (ATP formation) and production of electron carriers.

39. Annotate the diagram below with the stages of the electron transport chain and oxidative

phosphorylation. Include generation of a H+ concentration gradient in the inter-membrane space, movement of electrons, oxidative phosphorylation by ATP synthase, use of O2 as the terminal electron acceptor.

40. In the space below, using the term ‘chemiosmosis’, describe how ATP synthase works.

41. Name compounds in cell respiration that contain:

  1. Six carbons
  1. Four carbons
  1. Three carbons
  1. Two carbons
  1. One carbon
  1. Zero carbons

42. Name (with reasons) three tissues in the body that contain high numbers of mitochondria.

43. A runner is tested and high levels of lactic acid are found. Can you explain why?

44. Explain why ATP yield in aerobic cell respiration is so much higher than in anaerobic

respiration. (Long answer question – think about knock-on effects of reduced O2).