All AP Biology Resources
Example Questions
Example Question #212 : Cellular Biology
Cellular respiration primarily takes place in which organelle?
Nucleus
Mitochondria
Cytoplasm
Peroxisome
Cytosol
Mitochondria
Cellular respiration divided into three steps: glycolysis, citric acid cycle (also known as the Krebs or TCA cycle), and the electron transport chain (also known as oxidative phosphorylation). While glycolysis takes place in the cytosol, the other two steps occur in the mitochondria.
Example Question #111 : Cellular Respiration
Which of these statements best explains the major process that occurs in mitochondria.
Energy from the bonds of glucose molecules is transferred to the phosphate bonds in ATP and lactic acid is produced.
Energy from the bonds of glucose molecules is transferred to the phosphate bonds in ATP and water is produced.
Energy from oxygen molecules are released during combustion.
Energy from sunlight is used to convert carbon dioxide into six-carbon sugars.
Energy from sunlight is used to from DNA from nucleic acid molecules.
Energy from the bonds of glucose molecules is transferred to the phosphate bonds in ATP and water is produced.
The major processes that occur in mitochondria are the citric acid cycle and the electron transport chain. The citric acid cycle forms electron carries that are used in the electron transport chain to reduce oxygen to water and produce ATP.
Example Question #112 : Cellular Respiration
During the reaction catalyzed by ATP synthase, protons flow from __________.
the cytosol to the mitochondrial matrix
the mitochondrial matrix to the mitochondrial intermembrance space
the cytosol to the mitochondrial intermembrance space
the chloroplast intermembrance space to the chloroplast stroma
the mitochondrial intermembrance space to the mitochondrial matrix
the mitochondrial intermembrance space to the mitochondrial matrix
ATP Synthase work by converting the energy in the protons electrochemical gradient into production of ATP. This gradient is oriented across in the inner mitochondrial membrane so that protons is at a higher concentration in the intermembrane space than the matrix, and thus will flow from the intermembrane space to the matrix. This gradient is produced by the electron transport chain pumping protons from the matrix across the inner membrane to the intermembrane space.
Example Question #216 : Cellular Biology
What is a negative aspect of oxidative phosphorylation?
Production of reactive oxygen species
Oxidative phosphorylation does not produce as much energy as glycolysis and fermentation
The is no negative aspect
Production of excessive ATP
Production of carbon dioxide
Production of reactive oxygen species
During the reduction of oxygen to water, reactive oxygen species such as superoxide or hydrogen peroxide can be produced. These molecules are highly reactive and such can react with proteins or DNA to cause cellular damage or mutations.
Example Question #111 : Cellular Respiration
Which molecule(s) bring electrons to be used in the electron transport chain?
produced by glycolysis and the citric acid cycle and produced by the citric acid cycle as electron carries. These molecules "drop off" electrons to the complexes in the electron transport chain. is also an electron carrier, however is main role is during the Calvin cycle of photosynthesis.
Example Question #113 : Cellular Respiration
A culture of cells is grown on a special medium containing substance "Y". Substance "Y" is a poison that blocks the electron transport chain. The addition of substance "Y" to the culture of cells will likely result in which of the following?
ATP production that will decrease
ATP production will remain the same
ATP production that will increase
Oxygen consumption that will increase
Lactic acid will be converted to ethanol
ATP production that will decrease
The electron transport chain (ETC) is responsible for oxidative phosphorylation, resulting in the production of ATP. The ATP is produced by a proton gradient made as electrons are transported throughout the chain. Inhibition of this process by "Substance Y" will block the formation of a proton gradient. Blocking the proton gradient will not allow for oxidative phosphorylation to occur, thus greatly decreasing the amount of ATP produced.
Example Question #114 : Cellular Respiration
What is the final electron acceptor in the electron transport chain?
Water
Oxygen
Hydrogen
Oxygen
The correct answer to this question is oxygen.
Oxygen is the final electron acceptor of electrons as they are passed down the electron chain. The electrons move and combine with oxygen to produce . Water and hydrogen are just byproducts of the acceptance of the electron, not the acceptor. The electrons are actually brought to the electron transport chain by carries like and .
Example Question #113 : Cell Functions
Which of the following molecules give rise to the most net ATP?
FADH2
sucrose
NADH
pyruvate
glucose
glucose
This is because glucose can net 36 ATP, NADH actually nets 3, FADH2 can net 2, and pyruvate can net 15. This answer involves a careful examination of respiration processes.
Example Question #41 : Understanding The Electron Transport Chain
Why does FADH2 produce less ATP then NADH?
FADH2 produces less ATP then NADH because FADH2 is reduced more.
FADH2 produces less ATP then NADH because the electrons for FADH2 are dropped off at the second protein of the electron transport chain.
FADH2 produces less ATP then NADH because NADH has more energetic electrons.
FADH2 produces less ATP then NADH because NADH is reduced more.
FADH2 produces less ATP then NADH because FADH2 produces a larger proton gradient.
FADH2 produces less ATP then NADH because the electrons for FADH2 are dropped off at the second protein of the electron transport chain.
FADH2 is directly attached onto the second protein of the electron transport chain and therefore the electrons of FADH2 (electron carrier) are dropped off at the second protein not the first. As a result, the electrons from FADH2 do not pump as much electrons across the membrane as NADH. This results in a lower proton gradient created from FADH2 then NADH and therefore less ATP production from FADH2.
Example Question #41 : Understanding The Electron Transport Chain
What driving force creates most of the ATP in cellular respiration?
the movement of sodium down its concentration gradient
the movement of protons down its concentration gradient
the movement of FADH2 down its concentration gradient
the movement of NADH down its concentration gradient
the movement of electrons through the electron transport chain
the movement of protons down its concentration gradient
Remember that NADH and FADH2 are electron carriers and do not directly create any energy. The movement of the electrons through the electron transport chain also does not create energy directly, but does create a proton gradient that is later used to create energy. The movement of protons down its proton gradient through ATP synthase does, however, generate energy. It actually generates around 30 ATP molecules per one glucose.