Examples of calvin cycle in the following topics:
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- The Calvin cycle is a process that ensures carbon dioxide fixation in plants.
- The Calvin cycle is a process utilized to ensure carbon dioxide fixation.
- During the first phase of the Calvin cycle, carbon fixation occurs.
- During the second phase of the Calvin cycle, reduction occurs.
- An overview of the Calvin cycle and the three major phases.
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- The Calvin Cycle involves the process of carbon fixation to produce organic compounds necessary for metabolic processes.
- The Calvin Cycle is characterized as a carbon fixation pathway.
- The Calvin Cycle is also referred to as the reductive pentose phosphate cycle or the Calvin-Benson-Bassham cycle.
- The following is a brief overview of the intermediates created during the Calvin cycle.
- Outline the function of the intermediates produced in the major phases of the Calvin Cycle
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- The major pathways utilized to ensure fixation of carbon dioxide include: the Calvin cycle, the reductive TCA cycle, and the acetyl-CoA pathway.
- The Calvin cycle involves utilizing carbon dioxide and water to form organic compounds.
- The reductive TCA cycle, commonly referred to as the reverse Krebs cycle, also produces carbon compounds from carbon dioxide and water.
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- These compartments are thought to concentrate carbon dioxide to overcome the inefficiency of RuBisCo (ribulose bisphosphate carboxylase/oxygenase) - the predominant enzyme in carbon fixation and the rate limiting enzyme in the Calvin cycle.
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- For example, archaea use a modified form of glycolysis (the Entner–Doudoroff pathway) and either a complete or partial citric acid cycle.
- This process involves either a highly modified form of the Calvin cycle or a recently discovered metabolic pathway called the 3-hydroxypropionate/4-hydroxybutyrate cycle.
- In addition, the Crenarchaeota use the reverse Krebs cycle while the Euryarchaeota use the reductive acetyl-CoA pathway.
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- Nitrobacter plays an important role in the nitrogen cycle by oxidizing nitrite into nitrate in soil.
- Nitrification is an important step in the nitrogen cycle in soil.
- Electron and proton cycling are very complex, but as a net result only one proton is translocated across the membrane per molecule of ammonium oxidized.
- As in sulfur and iron oxidation, NADH for carbon dioxide fixation using the Calvin cycle is generated by reverse electron flow, thereby placing a further metabolic burden on an already energy-poor process.
- The importance of bacteria in the cycle is immediately recognized as being a key element in the cycle, providing different forms of nitrogen compounds assimilable by higher organisms.
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- Like sulfur oxidation, reverse electron flow must be used to form the NADH used for carbon dioxide fixation via the Calvin cycle.
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- Many basic metabolic pathways are shared between all forms of life; for example, archaea use a modified form of glycolysis (the Entner–Doudoroff pathway) and either a complete or partial citric acid cycle.
- This process involves either a highly modified form of the Calvin cycle or a recently discovered metabolic pathway called the 3-hydroxypropionate/4-hydroxybutyrate cycle.
- The Crenarchaeota also use the reverse Krebs cycle while the Euryarchaeota also use the reductive acetyl-CoA pathway.
- Some marine Crenarchaeota are capable of nitrification, suggesting these organisms may affect the oceanic nitrogen cycle, although these oceanic Crenarchaeota may also use other sources of energy.
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- Carbon dioxide is reduced to form carbohydrates via the Calvin cycle.
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- In many organisms, a second cytoplasmic hydrogenase is used to generate reducing power in the form of NADH, which is subsequently used to fix carbon dioxide via the Calvin cycle.