AP Biology : Cellular Respiration

Study concepts, example questions & explanations for AP Biology

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Example Questions

Example Question #101 : Cellular Respiration

How many  do  and  produce respectively?

Possible Answers:

3 and 2

2 and 1

2 and 3

1 and 2

1.5 each

Correct answer:

3 and 2

Explanation:

Each  produces 3  molecules in the electron transport chain while each  produces 2  molecules. Each glucose molecule results in the formation of 10  molecules, which go on to produce 30 . Each glucose molecule results in the formation of 2  molecules, which go on to produce 4 . Note that some references may indicate that each  produces 2.5 , while each  produces 1.5 . These are theoretical maximums and depend on the organism, cell type, and cellular environment.

Example Question #23 : Understanding The Electron Transport Chain

Ideally, how many ATP molecules are produced from one glucose molecule in cellular respiration?

Possible Answers:

40

30

20

38

25

Correct answer:

38

Explanation:

A total of 38 ATP molecules are produced from one molecule of glucose. 2 ATP from glycolysis, 2 ATP from the Krebs cycle, and about 34 ATP from the electron transport chain. Note that this is a theoretical maximum and is rarely seen in nature.

Example Question #21 : Understanding The Electron Transport Chain

The movement of electrons down a potential energy gradient during electron transport is coupled to the movement of what?

Possible Answers:

Protons down their concentration gradient

ATP down its concentration gradient

Protons against their concentration gradient

Electrons against their concentration gradient

Water down its concentration gradient.

Correct answer:

Protons against their concentration gradient

Explanation:

In electron transport, the energy that is released as electrons flow down a potential energy gradient is coupled to the movement of protons from the mitochondrial matrix across the inner mitochondrial membrane into the intermembrane space. This direction of flow is against the protons' concentration gradient and thus requires energy, which is provided by the spontaneous passage of electron down a potential energy gradient of enzyme complexes.

Example Question #271 : Ap Biology

In the Krebs cycle what are the two electron carriers that accept the hydrogen ions and then are used in the electron transport chain?

Possible Answers:

Carbon dioxide and nitrogen

Hydrogen and oxygen

ATP and ADP

Correct answer:

Explanation:

 are the two electron carriers in the Krebs cycle. ATP is the energy compound that is created in respiration. Carbon dioxide is a waste product from the Krebs cycle.  Nitrogen is not involved in the Krebs cycle. Oxygen is an electron acceptor, and hydrogen is added to the electron carriers.

Example Question #272 : Ap Biology

What is the primary reason that ATP synthesis occurs with the electron transport chain?

Possible Answers:

ATP is created by breaking down water as the water passes through the pumps in the membranes.

ADP accepts a protons ion and a phosphate to create ATP.

NADH pass through ATP synthase, which creates ATP

A concentration gradient of protons is created across the membranes of the mitochondria and then the protons feed into ATP synthase, creating ATP.

Correct answer:

A concentration gradient of protons is created across the membranes of the mitochondria and then the protons feed into ATP synthase, creating ATP.

Explanation:

The concentration gradient of protons feeds into ATP synthase structure, which creates ATP. Water does not feed into ATP synthase. ADP does not accept the hydrogen to create ATP, rather it is the substrate onto which a phosphate group is added to create ATP. NADH gives up a hydrogen in the electron transport chain to create the concentration gradient. It does not pass through ATP synthase.

Example Question #271 : Ap Biology

While looking under her microscope, Dr. Smith noticed the cell was packed with mitochondria. While thinking back to the basics of the cell, she remembered on of the unique properties of this organelle is its ability to produce large amounts of energy in the form of ATP. Where do we find the major components of the electron transport chain?

Possible Answers:

Outer membrane

Intermembrane space

Matrix

Inner membrane 

The electron transport chain is not found in the mitochondria

Correct answer:

Inner membrane 

Explanation:

The mitochondrion is composed of an outer membrane, matrix, inner membrane and inner membrane space. The components of the electron transport chain, namely the cytochrome proteins and ATP synthase, are arranged on the inner membrane to allow for the movement of protons between the inner membrane space and matrix in order to create ATP.

Example Question #272 : Ap Biology

Hows does the act of breathing relate to cellular respiration in humans and other mammals. 

Possible Answers:

With each breath, carbon dioxide is taken in and used for cellular respiration while oxygen is exhaled as a waste product.

With each breath, oxygen is taken in and used for cellular respiration while carbon dioxide is exhaled as a waste product.

With each breath, nitrogen is taken in and used for cellular respiration while carbon dioxide is exhaled as a waste product.

There is no relationship between breathing an cellular respiration.

With each breath, oxygen is taken in and used for cellular respiration while nitrogen is exhaled as a waste product.

Correct answer:

With each breath, oxygen is taken in and used for cellular respiration while carbon dioxide is exhaled as a waste product.

Explanation:

The final electron acceptor of the electron transport chain in cellular respiration is oxygen. Additionally carbon dioxide is produced as a waste product during the citric acid cycle phase of cellular respiration.

Example Question #21 : Understanding The Electron Transport Chain

How does a reducing agent function in cellular respiration?

Possible Answers:

Giving electrons as an electron receptor

Taking electrons as an electron receptor

Giving electrons as an electron donor

Taking electrons as an electron donor

None, reducing agents are not used in the cellular respiration pathway

Correct answer:

Giving electrons as an electron donor

Explanation:

A reducing agent works as an electron donor, so it is ultimately giving away electrons to another molecule and ultimately making that other molecule more negative in charge, or reduced in charge. Note that a reducing agent is itself oxidized. Also recall the mnemonic OIL RIG (Oxidation Is Loss of electrons, Reduction Is Gain of electrons).

Example Question #31 : Understanding The Electron Transport Chain

What are the finally products of cellular respiration at the end of the electron transport chain?

Possible Answers:

Correct answer:

Explanation:

Cellular respiration begins with the process of breathing in oxygen and consuming glucose. Through a series of reactions they eventually produce energy in the form of  and heat, as well as byproducts such as , which is exhaled, and water molecules.

Example Question #101 : Cellular Respiration

On a cellular level, why do heterotrophs need to eat food?

Possible Answers:

They need the electron carriers made from the breakdown of proteins, along with oxygen, to produce ATP in the process of fermentation. 

They need the electron carriers made from the breakdown of proteins, along with oxygen, to produce ATP in the process of cellular respiration.

They need the electron carriers made from the breakdown of glucose, along with oxygen, to produce ATP in the process of cellular respiration.

They need the electron carriers made from the breakdown of glucose, along with oxygen, to produce ATP in the process of fermentation. 

Heterotrophs do not need to eat food.

Correct answer:

They need the electron carriers made from the breakdown of glucose, along with oxygen, to produce ATP in the process of cellular respiration.

Explanation:

Glucose is the primary molecule that heterotrophs use to make energy at a cellular level. Heterotrophs use glucose for a starting material in both fermentation and cellular respiration. However fermentation is performed without oxygen (anaerobic), while cellular respiration requires oxygen as a final electron receptor at the end of the electron transport chain.

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