In which condition does serum appear milky white?
Which of the following is a non-essential amino acid?
Hydrolysis occurs at which step of urea cycle ?
Which technique is used for the separation of proteins based on their mass?
Which amino acid among the following has significant UV absorption at 280 nm used in protein quantification?
In starvation, nitrogen is primarily carried from muscle to liver and kidney by which amino acid?
Which of the following processes does not occur in mitochondria?
Chemiosmotic coupling of oxidative phosphorylation is related to which of the following?
What is the coenzyme form of pyridoxine?
What is the role of adenine phosphoribosyl transferase (APRT) in purine metabolism?
NEET-PG 2012 - Biochemistry NEET-PG Practice Questions and MCQs
Question 81: In which condition does serum appear milky white?
- A. Increased LDL
- B. Increased HDL
- C. Increased VLDL
- D. Increased Chylomicrons (Correct Answer)
Explanation: ***Increased Chylomicrons*** - **Chylomicrons** are the largest lipoprotein particles (75-1200 nm) with the highest **triglyceride content (85-95%)**, giving serum a characteristic **milky white** or "creamy" appearance - This intense milky appearance occurs after **fatty meals** (postprandial lipemia) or in **Type I and V hyperlipidemias** (familial chylomicronemia syndrome) - The **light scattering** by these large particles makes the serum completely opaque, distinguishing it from other lipid abnormalities - Classic clinical finding: **"cream layer" forms on top** when lipemic serum stands overnight in refrigerator *Increased LDL* - Elevated **Low-Density Lipoprotein (LDL)** produces **clear to slightly hazy** serum, never milky white - LDL particles are much smaller (18-25 nm) than chylomicrons and contain primarily **cholesterol**, not triglycerides - High LDL is a cardiovascular risk factor but does not cause visible lipemia *Increased HDL* - **High-Density Lipoprotein (HDL)** elevation results in **clear serum** - HDL particles are the smallest (5-12 nm) and densest lipoproteins - High HDL is protective and causes no turbidity *Increased VLDL* - **Very Low-Density Lipoprotein (VLDL)** elevation can cause **turbid or hazy** serum in severe hypertriglyceridemia, but typically less intensely milky than chylomicrons - VLDL particles are smaller (30-80 nm) than chylomicrons with lower triglyceride content (50-65%) - In Type IV hyperlipidemia (isolated VLDL elevation), serum appears uniformly turbid without cream layer formation - The most dramatic "milky white" appearance is specifically associated with **chylomicronemia**
Question 82: Which of the following is a non-essential amino acid?
- A. Tyrosine (Correct Answer)
- B. Phenylalanine
- C. Lysine
- D. Threonine
Explanation: ***Tyrosine*** - **Tyrosine** is considered a **non-essential amino acid** because the human body can synthesize it from the essential amino acid **phenylalanine**. - This synthesis occurs via the enzyme **phenylalanine hydroxylase**, making its dietary intake not strictly necessary if phenylalanine is available. *Phenylalanine* - **Phenylalanine** is an **essential amino acid**, meaning the human body **cannot synthesize it** and it must be obtained through the diet. - It serves as a precursor for various important molecules, including tyrosine, contributing to neurotransmitter synthesis. *Lysine* - **Lysine** is an **essential amino acid** that the human body **cannot synthesize** and must be acquired from dietary sources. - It plays a crucial role in **protein synthesis**, calcium absorption, and the production of hormones and enzymes. *Threonine* - **Threonine** is another example of an **essential amino acid** that the human body is **unable to produce** on its own. - It is important for the formation of **collagen** and elastin, and contributes to immune function.
Question 83: Hydrolysis occurs at which step of urea cycle ?
- A. Formation of ornithine
- B. Formation of argininosuccinate
- C. Formation of citrulline
- D. Cleavage of arginine (Correct Answer)
Explanation: ***Cleavage of arginine*** - The final step in the urea cycle, where **arginine** is hydrolyzed by the enzyme **arginase** to form **urea** and **ornithine**. - This reaction involves the addition of a **water molecule** across the guanidino group to release urea. *Formation of argininosuccinate* - This step involves the condensation of **citrulline** and **aspartate**, catalyzed by **argininosuccinate synthetase**. - It is an **ATP-dependent** reaction, not a hydrolysis. *Formation of citrulline* - Occurs when **carbamoyl phosphate** condenses with **ornithine**, catalyzed by **ornithine transcarbamylase**. - This reaction involves the removal of a phosphate group, not the addition of water. *Formation of ornithine* - **Ornithine** is a substrate for the formation of citrulline and is also regenerated at the end of the cycle from arginine. - Its formation from arginine is a **hydrolysis** reaction, but simply stating "formation of ornithine" is less specific than "cleavage of arginine," which directly describes the hydrolytic event.
Question 84: Which technique is used for the separation of proteins based on their mass?
- A. Electrophoresis
- B. Salting out
- C. SDS-PAGE (Correct Answer)
- D. Ion exchange chromatography
Explanation: ***Correct Option: SDS-PAGE*** - **SDS-PAGE (Sodium Dodecyl Sulfate Polyacrylamide Gel Electrophoresis)** separates **denatured proteins** almost exclusively by their **molecular mass**. - **SDS** binds to proteins, imparting a uniform negative charge-to-mass ratio, ensuring that separation is primarily based on their size as they migrate through a **polyacrylamide gel**. - This is the gold standard technique for analyzing proteins by molecular weight. *Incorrect Option: Electrophoresis* - This is a general technique that uses an **electric field** to separate molecules based on their **charge** and **size**. - While it can separate proteins, it doesn't exclusively rely on **mass** without additional modifications (like SDS). - Native electrophoresis separates by charge-to-mass ratio, not mass alone. *Incorrect Option: Salting out* - This technique separates proteins based on their **solubility** in high salt concentrations. - Proteins "salt out" or precipitate at different salt concentrations, which is not directly related to their **mass**. - Based on protein surface properties and hydrophobicity. *Incorrect Option: Ion exchange chromatography* - This method separates proteins based on their **net charge** at a particular pH. - Proteins bind to a charged resin and are eluted by changing the **ionic strength** or **pH** of the buffer. - Two types: cation exchange (negative resin) and anion exchange (positive resin).
Question 85: Which amino acid among the following has significant UV absorption at 280 nm used in protein quantification?
- A. Tyrosine (Correct Answer)
- B. Alanine
- C. Histidine
- D. Arginine
Explanation: ***Correct Option: Tyrosine*** - Tyrosine contains a **phenol functional group** (aromatic ring with hydroxyl group), giving it **significant UV absorption at 280 nm** (specifically ~274 nm) - Along with **tryptophan** and **phenylalanine**, tyrosine is one of the three aromatic amino acids used for **protein quantification via UV spectroscopy** - The aromatic side chain with conjugated double bonds enables strong UV light absorption *Incorrect Option: Alanine* - Alanine has a **methyl group** as its side chain (non-polar, aliphatic) - **Lacks aromatic rings** or conjugated systems - Does **not absorb UV light** at 280 nm *Incorrect Option: Histidine* - Histidine has an **imidazole ring** (heterocyclic aromatic) in its side chain - While technically aromatic, it has **minimal UV absorption at 280 nm** (weak absorption around 210-230 nm) - **Not used for protein quantification** at 280 nm due to insignificant absorption at this wavelength *Incorrect Option: Arginine* - Arginine contains a **guanidinium group** (highly basic, polar) - **Non-aromatic structure** without conjugated double bonds - Does **not exhibit UV absorption** at wavelengths used for protein analysis
Question 86: In starvation, nitrogen is primarily carried from muscle to liver and kidney by which amino acid?
- A. Alanine (Correct Answer)
- B. Glycine
- C. Aspartic acid
- D. Asparagine
Explanation: ***Alanine*** - During starvation, muscles break down proteins, and the amino groups from these proteins are transferred to **pyruvate** to form **alanine** via the **glucose-alanine cycle (Cahill cycle)**. - **Alanine** is then released into the bloodstream and transported primarily to the **liver**, where its carbon skeleton can be used for **gluconeogenesis** and the amino group enters the urea cycle. - Note: While alanine is the primary carrier to the liver, **glutamine** is the main nitrogen carrier to the kidney. However, among the given options, alanine is unequivocally the correct answer. *Aspartic acid* - While aspartate is involved in amino group transfer and is a crucial component of the **urea cycle**, it is not the primary carrier for inter-organ nitrogen transport from muscle to liver during starvation. - Its role is more localized within the liver for the urea cycle rather than as a transport amino acid. *Glycine* - Glycine plays roles in various metabolic pathways, including synthesis of heme, purines, and conjugation reactions, but it is not the primary amino acid for carrying nitrogen from muscle to liver during starvation. - Its small size and simple structure make it less suitable for efficient nitrogen transport compared to alanine. *Asparagine* - Asparagine has a minor role in nitrogen transport but is not the primary carrier during starvation. - It is synthesized from **aspartate** and ammonia and is typically involved in protein synthesis and nitrogen storage in some tissues.
Question 87: Which of the following processes does not occur in mitochondria?
- A. Fatty acid oxidation
- B. Electron transport chain
- C. Glycogenolysis (Correct Answer)
- D. Citric acid cycle (Kreb's cycle)
Explanation: ***Glycogenolysis*** - **Glycogenolysis** is the breakdown of **glycogen** into glucose, which primarily occurs in the **cytosol** of cells, mainly in the liver and muscles. - This process is crucial for maintaining blood glucose levels and providing energy during periods of fasting or increased demand, and it does not take place within the mitochondria. *Fatty acid oxidation* - **Fatty acid oxidation**, also known as beta-oxidation, is a mitochondrial process that breaks down fatty acids into **acetyl-CoA** for energy production. - This occurs extensively within the mitochondrial matrix, producing ATP. *Electron transport chain* - The **electron transport chain** is located in the **inner mitochondrial membrane** and is the final stage of aerobic respiration, producing the majority of ATP. - It involves a series of protein complexes that transfer electrons to oxygen, creating a proton gradient for ATP synthesis. *Citric acid cycle (Kreb's cycle)* - The **citric acid cycle**, or **Krebs cycle**, is a central metabolic pathway that occurs in the **mitochondrial matrix**. - It oxidizes acetyl-CoA, derived from carbohydrates, fats, and proteins, to produce ATP, NADH, and FADH2.
Question 88: Chemiosmotic coupling of oxidative phosphorylation is related to which of the following?
- A. ATP generation by pumping of neutrons
- B. Formation of ATP at substrate level
- C. ATP generation by pumping of protons (Correct Answer)
- D. ATP formation by transport of electrons
Explanation: ***ATP generation by pumping of protons*** - **Chemiosmotic coupling** links the electron transport chain's activity to ATP synthesis through the generation of a **proton gradient** across the inner mitochondrial membrane. - The energy released from the flow of electrons through complexes I, III, and IV is used to pump protons from the mitochondrial matrix to the intermembrane space, creating a **proton motive force** that drives ATP synthase. *Formation of ATP at substrate level* - **Substrate-level phosphorylation** involves the direct transfer of a phosphate group from a high-energy substrate to ADP to form ATP, independently of a proton gradient. - This process occurs in reactions like those in **glycolysis** and the **Krebs cycle**, not in oxidative phosphorylation via chemiosmosis. *ATP generation by pumping of neutrons* - **Neutrons** are subatomic particles with no electric charge and are not involved in biological processes like ATP generation or membrane transport. - Pumping of neutrons has no physiological relevance in cellular energy metabolism. *ATP formation by transport of electrons* - While **electron transport** is an integral part of oxidative phosphorylation, it does not directly form ATP. - The energy released during electron transport is used to create the **proton gradient** (chemiosmotic coupling), which then drives ATP synthesis, rather than ATP being formed directly by electron movement.
Question 89: What is the coenzyme form of pyridoxine?
- A. ADP
- B. NAD
- C. PLP (Correct Answer)
- D. FAD
Explanation: ***PLP*** - **Pyridoxal phosphate (PLP)** is the active coenzyme form of **pyridoxine (vitamin B6)**. - It plays a crucial role in numerous metabolic reactions, particularly those involving **amino acid metabolism**. *ADP* - **Adenosine diphosphate (ADP)** is an important molecule in energy transfer, particularly in the formation of **ATP (adenosine triphosphate)**. - It is not a coenzyme form of any vitamin, but rather a **nucleotide**. *NAD* - **Nicotinamide adenine dinucleotide (NAD)** is a coenzyme derived from **niacin (vitamin B3)**. - It functions as an electron carrier in **redox reactions** and is vital for cellular respiration. *FAD* - **Flavin adenine dinucleotide (FAD)** is a coenzyme derived from **riboflavin (vitamin B2)**. - It also serves as an electron carrier in **redox reactions**, particularly in the electron transport chain.
Question 90: What is the role of adenine phosphoribosyl transferase (APRT) in purine metabolism?
- A. Breakdown of purines
- B. Salvage pathway of purine nucleotide synthesis (Correct Answer)
- C. Not involved in purine metabolism
- D. De novo synthesis of purines
Explanation: ***Salvage pathway of purine nucleotide synthesis*** - **Adenine phosphoribosyl transferase (APRT)** catalyzes the reaction of **adenine** with **5-phosphoribosyl-1-pyrophosphate (PRPP)** to form **adenosine monophosphate (AMP)**. - This reaction is a crucial step in the **purine salvage pathway**, which reclaims pre-formed purine bases and converts them back into nucleotides, conserving energy. *Breakdown of purines* - The breakdown of purines (catabolism) typically involves enzymes like **adenosine deaminase** and **xanthine oxidase**, leading to the formation of **uric acid**. - APRT is involved in synthesizing nucleotides, not their degradation. *Not involved in purine metabolism* - APRT is an enzyme specifically involved in the **anabolic processes** of purine metabolism, as it contributes to the formation of purine nucleotides. - Its role is well-established within the **salvage pathway**. *De novo synthesis of purines* - The **de novo synthesis pathway** builds purine nucleotides from simpler precursors like **amino acids**, **CO2**, and **THF derivatives**. - While both pathways produce purine nucleotides, APRT is exclusively part of the **salvage pathway**, which recycles existing purine bases.