Acetyl CoA can be used in cellular metabolism to produce energy through the citric acid cycle or to synthesize fatty acids. It can also be converted into ketone bodies in times of fasting or low carbohydrate intake.
It can become lactic acid or alcohol. I don't know the other one
Pyruvate is converted into acetyl-CoA in the mitochondrial matrix through the process of pyruvate oxidation. Acetyl-CoA then enters the citric acid cycle to produce reducing equivalents (NADH and FADH2) and ATP through oxidative phosphorylation.
Sea stars exhibit radial cleavage, resulting in indeterminate cell fate and a regeneration potential, while humans display spiral cleavage leading to determinate cell fate and limited regenerative abilities. Additionally, sea stars have a more simple body plan with decentralized nerve cells, whereas humans possess a centralized nervous system and complex organ systems.
Examples of fate include meeting someone important at the right place and time, having a life-changing opportunity unexpectedly come your way, or experiencing a significant event that alters the course of your life in a predetermined manner.
when we talk about (fate) we mean thoes thngs that when photosynthesis occur happes. They are: Glucose is converted to starch and temporaly stored in the day. The triose phosphate of the Calvin cycle can be synthesised into hexose sugars eg,glucose and fructose.The glucose may be polymerised to give starch for storage or maybe made into cellulose which makes up over 50% of the cell wall.
Yes, stem cells have mitochondria, which are essential for energy production and cellular metabolism. The function and dynamics of mitochondria in stem cells can influence their ability to differentiate and self-renew. Additionally, mitochondrial activity plays a crucial role in the regulation of stem cell fate and overall cellular health.
Excreted as urea. this was the answer for my test
it is used in the Kreb's cycle and becomes CO2
Pyruvic acid is further metabolized in the Krebs cycle to generate energy in the form of ATP. It can also be converted into other molecules like acetyl-CoA for entry into other metabolic pathways. Alternatively, pyruvic acid can be converted into lactic acid in the absence of oxygen during anaerobic metabolism.
Fate is a possible option for the antagonist.
Acetyl Coa is very important in the process of metabolism. It is used in many biochemical reactions. Its primary function is to provide carbon atoms in the acetyl group to the citric acid cycle.
The molecule responsible for determining the fate of each cell is DNA. Gene expression patterns within the DNA of a cell dictate its specific fate and function through the production of different proteins and cellular processes.
It can enter into the urea cycle
One of the three carbon atoms that make up pyruvate is cleaved off by the rather large enzyme pyruvate dehydrogenase. This carbon atom attached to oxygen and becomes carbon dioxide(what you exhale). This reaction is known as a decarboxylation reaction. Then the other two remaining carbon atoms make up an acetyl group. Along with the acetyl group is hydrogen which will reduce NAD+ to NADH. The acetyl group is added to coenzyme a, and is called acetyl coenzyme a, or acetyl CoA for short. This is the ultimate creation of the oxidation of pyruvate. If there is a high concentration of ATP then the acetyl-CoA is used for fatty acid biosynthesis. If not than it will be used for oxidative metabolism. That's the basics of it for it is very complex.
Oxidation to pyruvate via gluconeogenesis
It can become lactic acid or alcohol. I don't know the other one
it is used in the Kreb's cycle and becomes CO2