31 Years NEET Previous Year Questions: Respiration in Plants - 1 Free MCQ

• Complex II in the mitochondrial electron transport chain is succinate dehydrogenase, which is also an enzyme of the TCA cycle.
• It catalyses the oxidation of succinate to fumarate, reducing FAD to FADH₂ in the process.
• Electrons from FADH₂ are then passed to ubiquinone (Coenzyme Q).
• Unlike Complex I, Complex II does not pump protons across the inner mitochondrial membrane.

Other options:

• (a) Cytochrome c oxidase → Complex IV
• (b) NADH dehydrogenase → Complex I
• (c) Cytochrome bc → Complex III

The tricarboxylic acid cycle (TCA cycle), also known as the Krebs cycle or citric acid cycle, is a series of enzyme-catalyzed chemical reactions that form a key part of aerobic respiration in cells. This cycle is primarily used to generate high-energy electron carriers and carbon dioxide. Most of the steps in the TCA cycle involve the oxidation of the substrate, where electrons are transferred to NAD+ to form NADH or to FAD to form FADH2.

Each option provided corresponds to a step in the TCA cycle:

Option A: Malic acid → Oxaloacetic acid involves the enzyme malate dehydrogenase, where malate is oxidized to oxaloacetate. NAD+ is reduced to NADH in this process, indicating an oxidation reaction.
Option B: Succinic acid → Malic acid is not a direct step in the TCA cycle. Instead, succinic acid is first converted to fumarate by succinate dehydrogenase, involving the reduction of FAD to FADH2, then fumarate is hydrated to malate by fumarase. Both involve transformations but particularly the conversion of succinate to fumarate involves oxidation.
Option C: Succinyl-CoA → Succinic acid involves the conversion of Succinyl-CoA to Succinic acid catalyzed by succinyl-CoA synthetase. In this process, a high-energy thioester bond in Succinyl-CoA is broken to release a molecule of coenzyme A (CoA) and produce succinate. This step does not involve the transfer of electrons or the reduction of NAD+ or FAD; rather, it's coupled with the phosphorylation of GDP to GTP (or ADP to ATP in some organisms), which is a substrate-level phosphorylation.
Option D: Isocitrate →α-ketoglutaric acid involves the enzyme isocitrate dehydrogenase that catalyzes the oxidative decarboxylation of isocitrate into alpha-ketoglutarate. NAD+ is reduced to NADH, showing that this step involves oxidation.

Therefore, the correct answer is Option C (Succinyl-CoA → Succinic acid). This is the step in the TCA cycle that does not involve the oxidation of the substrate but instead involves substrate-level phosphorylation, which is associated with the energy conversion of GTP formation rather than an electron transfer process.

To correctly match the given processes in List I with their locations in List II, let's go through each item:

Citric Acid Cycle (A) occurs in the mitochondrial matrix. This process, also known as the Krebs cycle, takes place in the matrix of mitochondria where enzymes for the cycle are located.

Glycolysis (B) takes place in the cytoplasm of the cell. It is the process of breaking down glucose into pyruvate, generating small amounts of energy (ATP) and does not involve the mitochondria.

Electron Transport System (C) occurs at the inner mitochondrial membrane. This is where the electron transport chains are located and where ATP is produced by oxidative phosphorylation.

 Proton gradient (D) is formed across the inner mitochondrial membrane, with protons accumulating in the intermembrane space. Protons (H+ ions) are pumped from the mitochondrial matrix to the intermembrane space, creating a gradient that drives ATP synthesis.

Now using the above information, let's match these with the correct options:
A. Citric Acid Cycle - II. Mitochondrial Matrix
B. Glycolysis - I. Cytoplasm
C. Electron Transport System - IV. Inner Mitochondrial Membrane
D. Proton Gradient - III. Intermembrane Space of Mitochondria

Comparing these to the options provided:

Option A: A-I, B-II, C-III, D-IV - Incorrect
Option B: A-II, B-I, C-IV, D-III - Correct
Option C: A-III, B-IV, C-I, D-II - Incorrect
Option D: A-IV, B-III, C-II, D-I - Incorrect

Therefore, Option B is the correct match: A-II, B-I, C-IV, D-III

In glycolysis, the conversion of 1,3-bisphosphoglyceric acid (1,3-BPG) to 3-phosphoglyceric acid (3-PGA) is an energy-yielding process because it results in the production of ATP.
During this step, phosphoglycerate kinase catalyses the transfer of a phosphate group from 1,3-BPG to ADP, forming ATP and 3-PGA. This reaction is an example of substrate-level phosphorylation, where ATP is directly produced from the substrate (1,3-BPG).
Thus, this is an energy-yielding process as ATP is produced.

• A. Energy of oxidation-reduction is utilized for phosphorylation: This statement is correct. In cellular respiration, the energy released through oxidation-reduction reactions (such as in the electron transport chain) is used to drive the phosphorylation of ADP to ATP, a process known as oxidative phosphorylation.
• B. Oxygen acts as the final hydrogen acceptor: This statement is correct. In the electron transport chain (ETC), oxygen acts as the final electron acceptor, combining with electrons and protons (hydrogens) to form water. This is why oxygen is essential for aerobic respiration.
• C. The photo-oxidative energy is utilized for the production of proton gradient required for phosphorylation: This statement is incorrect. Photo-oxidative energy is involved in photosynthesis, not respiration. In respiration, the proton gradient is generated by the electron transport chain, not by photo-oxidation.
• D. The role of oxygen is limited to the terminal stage of the respiration process: This statement is correct. Oxygen is used at the final step of the electron transport chain, where it accepts electrons to form water.
• E. Protons cross the outer membrane of mitochondria through the channel formed by an integral membrane protein complex: This statement is incorrect. The outer mitochondrial membrane is permeable to small molecules and ions through porins, but proton pumping occurs across the inner mitochondrial membrane, not the outer membrane. The proton gradient is established across the inner membrane by complexes in the electron transport chain.

Thus, the correct statements are A, B, and D, making the correct answer (B).

• A. ETS Complex I: Complex I is known as NADH dehydrogenase, which catalyzes the transfer of electrons from NADH to the electron transport chain. Therefore, A corresponds to I (NADH Dehydrogenase).
• B. ETS Complex II: Complex II is known as succinate dehydrogenase, which is involved in the citric acid cycle and also feeds electrons into the electron transport chain. Therefore, B corresponds to IV (Succinate Dehydrogenase).
• C. ETS Complex III: Complex III is known as Cytochrome b-c1 complex, which transfers electrons from coenzyme Q to cytochrome c. Therefore, C corresponds to II (Cytochrome bC1).
• D. ETS Complex IV: Complex IV is known as cytochrome c oxidase, which catalyzes the final step in the electron transport chain, transferring electrons to oxygen to form water. Therefore, D corresponds to III (Cytochrome C oxidase).

Thus, the correct matching is:

• A-I: Complex I is NADH Dehydrogenase.
• B-IV: Complex II is Succinate Dehydrogenase.
• C-II: Complex III is Cytochrome bC1.
• D-III: Complex IV is Cytochrome C oxidase.

• A. Cellular respiration is the breaking of C-C bonds of complex organic molecules by oxidation: This statement is correct. In cellular respiration, complex organic molecules like glucose are broken down through oxidation to release energy.
• B. The entire cellular respiration takes place in mitochondria: This statement is incorrect. While most of cellular respiration (including the citric acid cycle and oxidative phosphorylation) occurs in the mitochondria, glycolysis occurs in the cytoplasm, not in the mitochondria.
• C. Fermentation takes place under anaerobic conditions in germinating seeds: This statement is correct. Fermentation occurs in the absence of oxygen (anaerobic conditions), such as in germinating seeds when oxygen is limited.
• D. The fate of pyruvate formed during glycolysis depends on the type of organism also: This statement is correct. The fate of pyruvate can vary depending on the organism and the presence of oxygen. Under aerobic conditions, pyruvate enters the mitochondria for the citric acid cycle, whereas under anaerobic conditions, it may be converted into lactic acid or ethanol, depending on the organism.
• E. Water is formed during respiration as a result of O₂ accepting electrons and getting reduced: This statement is correct. In the final step of the electron transport chain, oxygen (O₂) acts as the final electron acceptor, combining with electrons and protons to form water.

Thus, the correct answer is (a) A, C, D, E only.

Chemiosmosis is a process by which ATP (adenosine triphosphate) is produced in the cell. It relies on a concentration gradient of protons (H+ ions) across a membrane. The proton gradient is created by a proton pump. As protons flow back across the membrane, down their concentration gradient, they pass through a protein complex called ATP synthase, which uses the energy of the proton flow to produce ATP.

• Pyruvate, which is formed by the glycolytic catabolism of carbohydrates in the cytosol, after it enters mitochondrial matrix undergoes oxidative decarboxylation by a complex set of reactions catalyzed by pyruvate dehydrogenase.
• The scheme of glycolysis was given by Gustav Embden, Otto Meyrhof and J. Parnas, and is often referred to as the EMP pathway.
• In electron transport system, the energy of oxidation-reduction is utilized for the production of proton gradient required for phosphorylation, thus, this process is also called oxidative phosphorylation.
• The TCA (tricarboxylic acid cycle) starts with the condensation of acetyl group with oxaloacetic acid (OAA) and water to yield citric acid. The reaction is catalysed by the enzyme citrate synthase. Thus, option (C) is correct.

These carboxyl groups are removed with the release of a molecule in two different steps.
- The first oxidative decarboxylation takes place at the fourth step of the TCA cycle where isocitrate is converted to 5-carbon α-ketoglutarate, with the release of a pair of hydrogen atoms and a molecule of carbon dioxide.
- The second oxidative decarboxylation occurs at the fifth step of the Krebs’ cycle where a molecule of coenzyme-A reacts with the α-ketoglutarate to form a 4-carbon compound succinyl- coenzyme A and releasing carbon dioxide and a pair of hydrogen atoms.

Fatty acids are metabolized through β-oxidation, a process that occurs in the mitochondria, where fatty acids are broken down into two-carbon units. These two-carbon units are converted into acetyl-CoA, which then enters the TCA cycle (also known as the citric acid cycle or Krebs cycle) for further energy production.
Thus, fatty acids are connected with the respiratory pathway through acetyl-CoA, which is a key molecule that enters the TCA cycle and ultimately contributes to the production of ATP.

The number of times decarboxylation of isocitrate occurs during a single TCA cycle is two. During the TCA cycle, the decarboxylation of isocitrate occurs in two distinct steps: Isocitrate is first converted to α-ketoglutarate through a decarboxylation reaction, where one molecule of CO₂ is released.  Isocitrate → α-ketoglutarate + CO₂ . The α-ketoglutarate formed in the previous step is then decarboxylated again to succinyl CoA, resulting in the release of a second molecule of CO₂. α-ketoglutarate→ Succinyl-CoA + CO₂.

Less than seven percent of the energy in glucose is released during lactic acid fermentation and not all of it is trapped as high energy bonds of ATP.

During glycolysis, total 4 ATPs are produced from one glucose molecule with a net gain of 2 ATPs.

Oxidation of one molecule of NADH gives rise to 3 molecules of ATP, while that of one molecule of FADH₂ produces 2 molecules of ATP.

During Krebs' or citric acid cycle, succinyl-CoA is acted upon by enzyme succinyl-CoA synthetase to form succinate (a 4C compound). The reaction releases sufficient energy to form ATP (in plants) or GTP (in animals) by substrate-level phosphorylation. GTP can then be used to form ATP.

Glucose is phosphorylated to glucose-6- phosphate by ATP in presence of enzyme hexokinase and Mg²⁺.

 In a given diagram of aerobic respiration – pathway A is glycolysis, pathway B is kreb’s cycle and pathway C is ETS , thus  4, 8 & 12 are ATP. ATP act as energy currency. The energy trapped in form of ATP and it broken down whenever and wherever it needs to be utilised.

Carbohydrates are usually first converted into glucose before they are used for respiration. Fats are broken down into glycerol and fatty acids first. If fatty acids were to be respired they would first be degraded to acetyl CoA and enter the pathway. Glycerol would enter the pathway after being converted to 3-phosphoglyceraldehyde (PGAL). The proteins are degraded by proteases to individual amino acids (after deamination) and depending on their structure enter the pathway within the Krebs’ cycle or as pyruvate or acetyl CoA. Thus, acetyl CoA is the common metabolite of all the three (carbohydrates, proteins and fats).

Photophosphorylation refers to addition of phosphate in the presence of light.