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Jetzt kostenlos anmeldenRespiration is a series of metabolic reactions by which living organisms produce energy from glucose.
On the surface, it is the inverse of photosynthesis. As we have learned in our article on Photosynthesis, cells cannot directly use glucose as a source of energy. Instead, energy is stored as adenosine triphosphate (ATP) molecule and used as an immediate energy source. The breakdown of glucose to form ATP defines the process of cellular respiration.
At A-level, we are only concerned with the processes that make up cellular respiration. There are two types of cellular respiration: aerobic respiration and anaerobic respiration.
Let’s explore aerobic and anaerobic respiration to understand their differences.
Aerobic respiration requires oxygen to take place and occurs in the cytoplasm of a cell and the mitochondria. It produces carbon dioxide, water, and a lot of ATP. There are four stages of aerobic respiration:
The overall equation for aerobic respiration is the following:
Anaerobic respiration does not require oxygen. It will only take place when oxygen is absent. Anaerobic respiration occurs in the cytoplasm. The products of anaerobic respiration differ in both animals and plants. Anaerobic respiration in animals produces lactate, or ethanol; and carbon dioxide in plants or fungi. Only a small amount of ATP is produced during anaerobic respiration.
Unlike aerobic respiration, anaerobic respiration only has two stages:
The overall equation for anaerobic respiration in animals is the following:
The overall equation for anaerobic respiration in plants or fungi is:
There are a few different ways in which you can measure the rate of respiration.
There are many methods that scientists use to determine the rate of respiration; however, we must discuss redox indicators.
A redox indicator is a substance that changes colour when reduced or oxidised.
Examples of redox indicators include DCPIP and methylene blue. We use redox indicators to investigate the effects of temperature and substrate concentration on the rate of anaerobic respiration in yeast, as they can be added to a suspension of living yeast cells without damaging them.
To investigate the effect of temperature on the rate of respiration, you will need to do the following:
During aerobic respiration, dehydrogenation occurs regularly, particularly in both decarboxylation and the Krebs cycle.
Hydrogen atoms are constantly being removed from substrate molecules and are carried by NAD and FAD to the final stage of aerobic respiration. The enzyme dehydrogenase catalyses the conversion of NAD to reduced NAD in glycolysis.
When DCPIP or methylene blue are added to the solution, they act similarly to NAD and FAD molecules, picking up hydrogen atoms and becoming reduced. When reduced, both redox indicators turn from blue to colourless.
If the rate of respiration increases, so does the rate of dehydrogenation, and so the solution will turn colourless within a shorter amount of time. We can draw a link between the rate of colour change and the rate of respiration occurring within the yeast solution. Therefore, the rate of respiration is inversely proportional to the time taken for the solution to turn colourless. We can use the following equation to calculate the rate:
Another way to measure the rate of respiration is by using a respirometer, a type of equipment that can help measure the rate of oxygen consumption during aerobic respiration. Usually, we use respirometers by taking a living organism, such as invertebrates or germinating seeds.
You will need the following equipment to measure the rate of respiration:
Figure 6. A respirometer containing germinating seeds. Note that this is set up in a temperature-controlled water bath.
To measure the rate of respiration, you will need to do the following:
r = the diameter of the capillary tube
h = the distance moved by the manometer fluid in a minute.
The rate of oxygen consumption will be calculated as, and this value will be taken as the rate of respiration.
You should find that, as the temperature increases, so does the rate of respiration. For temperatures above 40°C, the rate of respiration should drop dramatically because respiration is an enzyme controlled reaction. When there is more heat energy available, enzymes in the organism have more kinetic energy and move around at a higher rate. There will be a higher chance of enzyme-substrate complexes forming, so the rate of reaction for respiration will increase overall. Beyond 40°C, these enzymes will denature, and their active site will change shape, meaning that there will be fewer enzyme-substrate complexes forming, and the rate of respiration will decrease.
It is important to know the process used to measure the rate of respiration in yeast. Yeast respires anaerobically, meaning that it does not need oxygen for respiration to occur. Yeast produces ethanol and carbon dioxide when it respires.
Carbon dioxide can be measured using the following equipment below:
To investigate the rate of respiration in yeast, you will need to do the following:
As with the above experiment using the respirometer, you should find that the respiration rate increases up to the optimum temperature of 40°C. When the temperature increases past 40°C, the respiration rate should drop dramatically.
Aerobic and anaerobic.
Aerobic respiration occurs in both the cytoplasm of the cell and the mitochondria. It requires oxygen and glucose to take place, and produces carbon dioxide, water, and a lot of ATP.
Anaerobic respiration occurs exclusively in the cytoplasm, and does not require oxygen to occur. During anaerobic respiration, glucose is converted into two lactate molecules (or ethanol and carbon dioxide in plants or fungi) and a small amount of ATP is produced.
Glycolysis, the first stage of respiration, takes place in the cytoplasm of the cell. If respiration is anaerobic, fermentation also occurs in the cytoplasm. If respiration is anaerobic, the remaining stages of respiration take place in the mitochondria of the cell.
C6H12O6 + 6O2 6H2O + 6CO2
Respiration refers to the metabolic process in which cells use glucose and turn it into ATP. Respiration can involve oxygen ( which is aerobic respiration) but can occur in the absence of oxygen ( which is anaerobic respiration).
What are the names of the four stages of aerobic respiration?
Glycolysis, the link reaction, the Krebs cycle, oxidative phosphorylation.
What is the name of the 3-carbon molecule produced in glycolysis?
Pyruvate.
What is the name of the 2-carbon molecule produced in the link reaction?
acetyl Co-enzyme A
What three molecules are produced during the Krebs cycle?
ATP, reduced NAD, and reduced FAD.
What two molecules are produced during oxidative phosphorylation?
ATP and water.
What are two examples of redox indicators?
Methylene blue and DCPIP.
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