FINALLY!!!

This week in AP Biology we reran our cellular respiration lab. We had tried to run it last week but unfortunately the lab went wrong. To begin the lab again we put the peas in water so they would germinate. Then, to prevent our lab going wrong from last time we hot glued the respirameters to the rubber cork they were supposed to be attached to. The next day in AP Biology we prepared for the lab even more. In the bottom of each test tube we placed a cotton ball and then put 1 mL of KOH solution on them. After that we placed a rayon ball which is considered a nonabsorbent cotton ball on top of them. The KOH solution attaches to the CO₂ released in cellular respiration that way in the experiment you are only measuring the amount of oxygen consumed. We finally ran our lab the next day after putting 10 germinating peas in test tubes 1 and 4 and then putting dry peas and beads of equal volume in test tubes 2 and 5 and glass beads of equal volume in test tubes 3 and 6. We placed the repirameters on top of the test tubes and put them in water baths of 10 and 25 degrees Celsius. After a five minute resting period we began to take measure on the respirameters of the amount of data consumed. Unfortunately our data was very irregular and did not make sense. We attributed this to the fact that we moved the test tubes while they were in the water baths which caused the red dye at the top of the respirameters to leak out. In the end though the germinating peas consumed the most oxygen in the 25 degree Celsius water bath. The colder temperatures affected the peas because it slowed down the process of cellular respiration. 

Oops!!!

This week in AP Biology we attempted to do two labs. Our first lab involved enzymes. In this lab we used hydrogen peroxide as a substrate and the enzyme in this lab would be peroxidase, an enzyme that is found in potatoes. In this lab we would dilute the hydrogen peroxide with water and add blended potato and water. When putting the two substances together the peroxidase in the potato would catalyze hydrogen peroxide into water and oxygen. We were going to see the rate of reaction of this catabolic reaction in different pHs, but unfortunately we prepared our different pH solutions too early and they began to mold. We now have to make more solutions of different pH and then we will be able to perform the lab. Our second lab dealt with cellular respiration. In this lab we were going to compare the amount of air produced by germinating peas, non-germinating peas and glass beads, and glass beads. We had six vials that we numbered one through six. In vial one we placed ten germinating peas. In vial two we put 10 non-germinating peas and a certain number of glass beads that made the volume of the germinating peas and non-germinating equal. In vial three we put only glass beads that equaled the volume of the germinating peas. We repeated this in vials four through six. After this was finished we placed vials one through three in a room temperature water bath and four through six in cool (10⁰C) water bath. The lab was not successful because the vials had repirometers on top of them and when the vials fell into the water the repirometers did also which screwed up the lab. This upcoming week in AP Biology we will restart the cellular respiration lab and will soon restart the enzyme lab.

                                      

The Rehash of Cellular Respiration

This week in AP Biology we expanded even more on the catabolic process that is cellular respiration. Cellular respiration can be broken down into three smaller processes. These processes are glycolysis, Citric Acid or Krebs’s Cycle, and Oxidative phosphorylation which is made up of the electron transport chain and chemiosmosis.

The first reaction that occurs is glycolysis in the cytoplasm in this reaction glucose is broken down from a six carbon molecule into two three carbon molecules called pyruvate if oxygen is present. The result of this is four molecules of ATP although we had to use two molecules of ATP to start giving us a net profit of two ATPs and two molecules NADH or FADH₂. If the process has to occur anaerobically rather than aerobically the glucose molecule is still broken down and the ATP is till produced, but lactic acid fermentation and alcohol fermentation may occur. In muscle cells when the muscle needs more energy than cellular respiration is giving out it performs lactic acid fermentation. When the glucose is broken down into pyruvate the pyruvate is then reduced by NADH and lactate is formed as a waste product.  The lactic acid builds up and can only be removed by exposure to oxygen. In certain prokaryotes and other anaerobic organisms alcohol fermentation is the source of energy. The pyruvate produced by glycolysis is changed into ethanol in alcohol fermentation.

After the glucose is broken down into two pyruvates the pyruvates must then be converted to acetyl CoA and diffuse across the mitochondria membrane before it can enter the Citric Acid Cycle. After the pyruvates are changed into acetyl CoA they enter the Citric Acid Cycle. The Citric Acid Cycle ends up reeasing the original six carbon atoms that were part of glycolysis at the begging as well as 3 NADH, 1 FADH₂, and 1 ATP for every turn. Since there are 2 acetyl CoAs the cycle has two turns giving it at the end 4NADH, 2 FADH₂, and 2 ATPs.

The energy held in the NADH and FADH₂ electron carriers is then used by the electron transport system. Unlike glycolysis and the Citric Acid Cycle which produces ATP through substrate level phosphorylation the electron transport chain and chemiosmosis produce ATP through oxidative phosphorylation. The electron carriers then deposit electrons to the electron transport chain. The loss of energy from the electrons is used to pump protons across the mitochondria’s inner membrane. Once the electrons are done they then combine with two hydrogen ions and oxygen to form water. The large concentration of protons or H⁺ ions then power the enzyme ATP synthase which starts pumping out ATP. This part of the process is called chemiosmosis. The end result of this can produce up to 26 or 28 ATPs.

Cellular Respiration

This week in AP Biology we learned about Cellular Respiration. Cellular Respiration is the process of taking food with 0₂ and creating ATP. Cellular Respiration takes place in and outside of the mitochondria. It can be performed both aerobically and anaerobically although, it is more productive aerobically. The equation for cellular respiration is C₆H₁₂O₆+6O₆ à 6CO₂+6H₂O.

There are three steps in cellular respiration they are glycolysis, The Krebs’s Cycle, and the electron transport chain. Glycolysis is taking glucose and breaking it down into two pyruvates. It occurs outside of the mitochondria in the cytoplasm. This produces two ATPs. After glycolysis the pyruvates are diffused across the mitochondria’s membrane where it is changed to acetyl CoA. From there the acetyl CoA enters the Krebs’s or citric acid cycle. This process produces 6 NADH, 2 FADH₂, and 2 ATPs. After the Krebs’s Cycle the NADH and FADH₂ go to the electron transport chain. There the NADH and FADH₂ release hydrogen atoms across the mitochondria’s membrane. When the outside of the mitochondria is saturated with hydrogen atoms it propels the enzyme ATP synthase to start producing ATP and it can produce up to thirty-four ATPs.

If cellular respiration occurs anaerobically it does not produce as much ATPs. Anaerobic respiration only has one step which is glycolysis. Lactic Acid Fermentation happens when muscle cells are placed under extreme pressure. The muscles cannot get enough oxygen so they start to perform cellular respiration anaerobically. This builds lactic acid in the cells and it can only go away by getting oxygen to the cells. When cellular respiration is performed anaerobically it is not as successful as when performed aerobically.