ok first: cellular respiration is when MITOCHONDRIA (((PLANT OR ANIMAL CELL ORGANISM))) gets from us carbon dioxide and turn it to oxygen so we can inhale it. second : mitochondria only works on daylight it uses SUNLIGHT to do this photosynthesis or as some say carbon dioxide filtering. NOTE:MITOCHONDRIA ON PLANTS DOES MORE THAN 1 THING IT ALSO USES SUNLIGHT TO MAKE SUGAR FOR FOOD
High energy sugars, such as glucose, are typically used in a reaction known as cellular respiration. This process occurs in cells to generate ATP, which is the main energy source for cellular activities. During cellular respiration, glucose is broken down in the presence of oxygen to produce carbon dioxide, water, and ATP.
Light is essential for photosynthesis to occur because it is the source of energy, so it doesnt occur during the night. However, CAM plants have the capability to run the light reactions during the day (when there is light) and the Calvin cycle at night. They do this by only opening their stomata at night and allowing the gas exchange then. This is done as a way to reduce the effects of transpiration in dry climates.
During high intensity exercises your cells become unable to perform aerobic respiration causing them to perform anaerobic respiration. This causes a build up of lactic acid in the muscles.
Yes, photosynthesis is the primary process responsible for producing oxygen in the atmosphere. During photosynthesis, plants, algae, and some bacteria use sunlight to convert carbon dioxide and water into oxygen and glucose. This oxygen is released into the atmosphere as a byproduct, contributing to the high levels of oxygen present today.
The adrenal gland is responsible for increasing heartbeat and respiration during periods of high emotion. It releases the hormone adrenaline (epinephrine), which activates the fight-or-flight response in the body, leading to increased heart rate and breathing.
High energy sugars, such as glucose, are typically used in a reaction known as cellular respiration. This process occurs in cells to generate ATP, which is the main energy source for cellular activities. During cellular respiration, glucose is broken down in the presence of oxygen to produce carbon dioxide, water, and ATP.
Energy is stored in glucose. It is the fuel for respiration
Light is essential for photosynthesis to occur because it is the source of energy, so it doesnt occur during the night. However, CAM plants have the capability to run the light reactions during the day (when there is light) and the Calvin cycle at night. They do this by only opening their stomata at night and allowing the gas exchange then. This is done as a way to reduce the effects of transpiration in dry climates.
Two high energy electron carriers used in cellular respiration that are not used in photosynthesis are NADH (Nicotinamide Adenine Dinucleotide) and FADH2 (Flavin Adenine Dinucleotide). These molecules play a crucial role in transferring electrons from the breakdown of glucose to the electron transport chain in cellular respiration, ultimately leading to the production of ATP. In photosynthesis, the electron carriers NADH and FADH2 are not involved as the process uses different electron carriers such as NADPH (Nicotinamide Adenine Dinucleotide Phosphate) and ATP.
High altitude affects respiration because there is less oxygen in the air. Because of this, more and stronger breathing is needed to supply oxygen to the bloodstream.
In most green plants the stomata are only open during the day. They allow carbon dioxide to reach the cells where the majority of photosynthesis takes place. As they also allow transpiration (water loss) the stomata of most plants close during the night when photosynthesis is not possible. There is a group of mainly desert plants known as CAM plants. These carry out a process called Crassulacean acid metabolism, which effectively allows them to store carbon dioxide in their leaves. In these plants the stomata are normally closed during the day to prevent water loss when temperatures are high, and open during the night when temperatures are lower.
NADH is produced during glycolysis, the citric acid cycle, and the electron transport chain in cellular respiration. It is a reducing agent that carries high-energy electrons to the electron transport chain to produce ATP.
In essence, respiration uses glucose and oxygen to produce high energy molecules known as ATP.
Photosynthesis [The opposite of it is cellular respiration, I believe... (I'm only in high school...)]
They produce glucose which is then used for cellular respiration. (Glucose is chemical energy, it has high energy bonds, which when broken in cellular respiration produce a net of 38 ATP (adenosine triphophate))
All aerobic organisms, including plants, animals, and many microorganisms, use cellular respiration to convert glucose and oxygen into energy in the form of ATP. In animals, cells such as muscle cells and neurons are particularly active in respiration due to their high energy demands. Plant cells also perform respiration, especially in the absence of sunlight, alongside photosynthesis during the day. Even anaerobic organisms, like certain bacteria and yeast, utilize respiration, albeit through different pathways that do not require oxygen.
The coenzyme that carries high-energy hydrogens during respiration is called nicotinamide adenine dinucleotide (NAD+). NAD+ accepts hydrogen atoms and becomes reduced to NADH, carrying the high-energy electrons to the electron transport chain for ATP production.