Process of Cellular Respiration

Types of Cellular Respiration 

The process of cellular respiration is of two types: aerobic respiration and anaerobic respiration. When it takes place with the presence of oxygen, it is called aerobic cellular respiration. When it occurs in the absence of oxygen, it is called anaerobic cellular respiration.

Aerobic Respiration 

In almost all prokaryotes and eukaryotes, aerobic respiration occurs in the cells. The end products of this type of respiration are water, CO₂ and energy. Aerobic respiration can only take place with the help of oxygen. It occurs in three stages: glycolysis, citric acid cycle, Krebs cycle and electron transport chain. 

1. Glycolysis: Splitting glucose (sugar, six carbon molecules) into two molecules of pyruvate (three-carbon molecules) is known as glycolysis, which releases energy. Prior to the initiation of glycolysis, the transportation of glucose into the cell takes place, where it is phosphorylated. It occurs in the cytosol in most organisms. 
2. Citric acid cycle: The Krebs cycle or citric acid cycle was discovered by Hans Adolf Krebs in 1937. The pyruvate produced after glycolysis enters into the mitochondrial matrix. The end products of this step are three molecules of NADH, two molecules of carbon dioxide (CO₂), one molecule of FADH₂ and one molecule of GTP. They are formed through each molecule of pyruvate. The end products of the citric acid cycle are responsible for carrying out the electron transport chain along with oxidative phosphorylation. 
3. Electron transport chain: This stage is also called oxidative phosphorylation, where electrons travel through an electron transport system located in the mitochondria’s inner membrane. This travelling of electrons helps in maintaining a gradient of hydrogen ions. Electrons move from NADH to FADH₂ and then to molecular oxygen when protons are pumped from the mitochondrial matrix to the space between the two membranes called the intermembrane matrix. This movement causes a reduction of O₂ into H₂

Therefore, in aerobic respiration, oxygen is used as the final acceptor of electrons, and this is the major role of oxygen in the entire cellular respiratory process. When the electron transport chain in the case of prokaryotes does not need oxygen for this stage, we call it anaerobic respiration. 

In aerobic respiration, cells use the protein gradient’s energy to generate significant ATP. 

Anaerobic Respiration

While studying the alcoholic fermentation of glucose by yeast, Pasteur (1860) discovered that it can respire without molecular oxygen. This process was termed anaerobic respiration.

Anaerobic respiration is an enzyme-controlled partial breakdown of organic compounds (floods) without oxygen and releasing only a fraction of energy. Therefore, end products are never completely inorganic. It occurs in the roots of some waterlogged plants, certain parasitic worms, animal muscles and some microorganisms (e.g. moulds, bacteria). The term anaerobic respiration is often used in connection with higher organisms. In microorganisms, anaerobic respiration is often called fermentation. Fermentation is named after products like alcoholic fermentation and lactic acid fermentation. Buchner (1897) found that fermentation could be caused by mixing sugar solution with yeast extract instead of living yeast cells. The enzyme complex present in the extract was named zymase. Because of the latter, fermentation is also called zymosis.

In anaerobic respiration, electrons are removed from the substrate during oxidation but are not finally transferred to molecular oxygen. The final electron acceptors are frequently compounds such as pyruvic acid or acetaldehyde, which form a part of the anaerobic respiratory pathway. The end products are lactic acid or ethyl alcohol and not water.

The mechanism of anaerobic respiration or fermentation resembles that of respiration up to glycolysis. Pyruvate formed at the end of glycolysis is anaerobically broken down to yield various products depending upon the organism and the type of tissue. The two common products are ethyl alcohol and lactic acid.

Conclusion 

Different types of organisms have evolved different biological processes for their cellular respiration. The processes can be aerobic or anaerobic. In all organisms, the process begins with glycolysis in the cell’s cytoplasm. Then, it continues in the mitochondria in aerobic respiration, where the Krebs cycle and electron transport chain occur, or it stays in the cytoplasm in anaerobic respiration, where fermentation ensues. The cellular respiration process, whether aerobic or anaerobic, produces energy for the sustenance of the organisms.