yes, it willm, because, celluar respiration is critical for a cell to continue to live
True. Cellular respiration is a critical process that generates energy in the form of ATP for the cell. Without this energy, the cell will not be able to carry out its essential functions and will eventually die.
Yes, cellular respiration can occur without photosynthesis. Cellular respiration is the process by which cells break down glucose to produce energy, while photosynthesis is the process by which plants convert sunlight into energy. While photosynthesis provides the initial energy source for most living organisms, some organisms (like animals) rely on consuming other organisms for energy through cellular respiration.
Cyanide is a poison that stops an important reaction in respiration by inhibiting cytochrome c oxidase, which is an enzyme involved in the electron transport chain. This disruption prevents cells from utilizing oxygen, leading to cellular asphyxiation and potentially fatal consequences.
When photosynthesis stops, the supply of glucose decreases, causing a decrease in the amount of available energy for cellular respiration. As a result, cellular respiration slows down since there is less glucose to break down in the mitochondria to produce ATP. This can lead to a decrease in energy production and possibly impact the overall functionality of the cell.
Cellular respiration in muscle cells produces ATP, which is essential for muscle contraction. After death (rigor mortis), ATP production stops, leading to a lack of energy for muscle relaxation. This causes muscles to stiffen due to an inability to break the cross-bridges between actin and myosin filaments.
yea
True. Cellular respiration is a critical process that generates energy in the form of ATP for the cell. Without this energy, the cell will not be able to carry out its essential functions and will eventually die.
the entire process of cellular respiration stops
No, respiration is continuous. Photosynthesis stops at night, as it is light dependent.
Yes, cellular respiration can occur without photosynthesis. Cellular respiration is the process by which cells break down glucose to produce energy, while photosynthesis is the process by which plants convert sunlight into energy. While photosynthesis provides the initial energy source for most living organisms, some organisms (like animals) rely on consuming other organisms for energy through cellular respiration.
Cyanide is a poison that stops an important reaction in respiration by inhibiting cytochrome c oxidase, which is an enzyme involved in the electron transport chain. This disruption prevents cells from utilizing oxygen, leading to cellular asphyxiation and potentially fatal consequences.
Always. Your cell constantly needs energy in the form of ATP generated by cellular respiration to conduct vital activities such as transcription, translation, and sometimes replication. If cellular respiration stops, the cell will most likely die from necrosis or apoptosis in short order.
Arsenic can inhibit enzymes involved in cellular respiration, such as cytochrome c oxidase, leading to a disruption in the electron transport chain and ATP production. This can result in decreased energy production, oxidative stress, and ultimately cell damage or death.
When photosynthesis stops, the supply of glucose decreases, causing a decrease in the amount of available energy for cellular respiration. As a result, cellular respiration slows down since there is less glucose to break down in the mitochondria to produce ATP. This can lead to a decrease in energy production and possibly impact the overall functionality of the cell.
Cyanide inhibits cellular respiration by binding to cytochrome c oxidase in the mitochondria, disrupting the electron transport chain. In amoebas, this prevents the production of ATP, which is essential for energy production and survival. Without ATP, essential cellular functions cannot be carried out, leading to cellular death.
Cellular respiration in muscle cells produces ATP, which is essential for muscle contraction. After death (rigor mortis), ATP production stops, leading to a lack of energy for muscle relaxation. This causes muscles to stiffen due to an inability to break the cross-bridges between actin and myosin filaments.
The rate of any reaction depends on the active masses of the reactants, the pH and the temperature. This applies to the biological reactions involving enzymes like cellular respiration The enzymes in general get more and more active as the temperature increases. This would be true till the temperature reaches up to 45 degree Celsius (in general for humans). Above which some enzymes denature and their activity completely drops off. This temperature is variable and is dependent on the enzyme. (A few enzymes are active even at high temperatures). But at 65 degree Celsius most of the intracellular enzymes are denatured. So as the temperature increases, the cellular respiration increases up to a certain point and then there is a sharp decline so at or after 65 degree Celsius cellular respiration is virtually impossible.