What is the Difference Between Glyoxylate and TCA Cycle?
🆚 Go to Comparative Table 🆚The glyoxylate cycle and the TCA (tricarboxylic acid) cycle, also known as the citric acid cycle, are both metabolic pathways involved in energy production and biosynthesis. However, they have distinct functions and occur in different organisms.
The main differences between the glyoxylate and TCA cycles are:
- Function: The TCA cycle is a major catabolic pathway responsible for producing a considerable amount of energy for cells, while the glyoxylate cycle's main function is anabolic, allowing the production of glucose from fatty acids in plants and bacteria.
- Organisms: The TCA cycle is present in all living organisms, including animals, while the glyoxylate cycle is found only in plants, bacteria, fungi, and protists.
- Enzymes: The glyoxylate cycle bypasses the two oxidative decarboxylation reactions of the TCA cycle and uses five of the eight enzymes associated with the TCA cycle: citrate synthase, aconitase, succinate dehydrogenase, fumarase, and malate dehydrogenase.
- Substrates: Both cycles involve acetyl-CoA, but the glyoxylate cycle specifically utilizes two-carbon compounds in the absence of glucose.
- Location: The glyoxylate cycle occurs in specialized plant peroxisomes called glyoxysomes, while the TCA cycle takes place in the mitochondria of eukaryotic cells.
In summary, the glyoxylate cycle is an anabolic pathway found in plants, bacteria, fungi, and protists that allows for the production of glucose from fatty acids, while the TCA cycle is a catabolic pathway present in all living organisms responsible for energy production. Both cycles share some common enzymes and substrates but differ in their overall functions and the organisms in which they occur.
Comparative Table: Glyoxylate vs TCA Cycle
The Glyoxylate and TCA cycles are both anabolic and catabolic pathways in living organisms. However, they have distinct functions and characteristics. Here is a table summarizing the differences between the Glyoxylate and TCA cycles:
| Feature | Glyoxylate Cycle | TCA Cycle |
|---|---|---|
| Definition | A special variant of the TCA cycle, utilizing two-carbon compounds in the absence of glucose. | A metabolic pathway connecting carbohydrate, fat, and protein metabolism. |
| Occurrence | Found in plants, bacteria, fungi, and protists. | Occurs in all living organisms. |
| Process | Converts 2-carbon compounds to a 4-carbon molecule, succinate, which can be metabolized to sugar, amino acids, or used for other purposes. | Produces carbohydrates, fats, and proteins from acetyl CoA. |
| Enzyme-based Reaction Steps | Consists of eight enzyme-based reaction steps. | Consists of five enzyme-based reaction steps. |
| Relation to Acetyl CoA | Both cycles combine with acetyl CoA to produce malate, which is catalyzed by malate synthase. | Both cycles use acetyl CoA produced by β-oxidation. |
In summary, the Glyoxylate cycle is a special variant of the TCA cycle that utilizes two-carbon compounds in the absence of glucose and is found only in plants, bacteria, fungi, and protists. In contrast, the TCA cycle is a metabolic pathway that occurs in all living organisms and connects carbohydrate, fat, and protein metabolism.
- Glycolysis vs TCA Cycle
- Krebs Cycle vs Glycolysis
- Krebs vs Calvin Cycle
- Glycolysis Krebs Cycle vs Electron Transport Chain
- Glycolysis vs Glycogenolysis
- Acetyl CoA vs Acyl CoA
- Glycol vs Glyoxal
- Glycolysis vs Gluconeogenesis
- Cytosolic vs Chloroplastic Glycolysis
- Glyceraldehyde vs Glycerate
- Aerobic vs Anaerobic Glycolysis
- Fermentation vs Glycolysis
- Glyoxysomes vs Peroxisomes
- Glyceraldehyde vs Dihydroxyacetone
- Pentose Phosphate Pathway vs Glycolysis
- Glycogenolysis vs Gluconeogenesis
- Glycosylation vs Glycosidation
- Oxalate vs Oxalic Acid
- Oxalic Acid vs Citric Acid