Where does omega oxidation of fatty acids occur?
Which of the following is not affected in Abetalipoproteinemia ?
What is the metabolic abnormality associated with Zellweger syndrome?
Which of the following substances is not derived from tyrosine?
Which amino acid is used by the liver in the urea cycle?
Anaplerotic reaction is catalyzed by?
Which macronutrient has the highest thermogenic effect?
Pantothenic acid is needed for donating the following moiety?
Beta-alanine is derived from ?
Which of the following is not a precursor in the synthesis of pyrimidines?
NEET-PG 2012 - Biochemistry NEET-PG Practice Questions and MCQs
Question 161: Where does omega oxidation of fatty acids occur?
- A. Endoplasmic Reticulum (Correct Answer)
- B. Cytosol
- C. Mitochondria
- D. None of the options
Explanation: ***Endoplasmic Reticulum*** - **Omega oxidation** of fatty acids occurs in the **endoplasmic reticulum (microsomes)** of liver and kidney cells. - This pathway involves **hydroxylation of the terminal omega carbon** by **cytochrome P450 enzymes** located in the smooth ER. - The omega carbon is then oxidized to a **carboxyl group**, forming a **dicarboxylic acid**. - This is a **minor pathway** that becomes important when **beta-oxidation is impaired** or for metabolism of **medium-chain fatty acids**. *Cytosol* - The cytosol is involved in **fatty acid synthesis**, not omega oxidation. - While some later steps of fatty acid metabolism occur in the cytosol, the initial hydroxylation step of omega oxidation requires ER-localized cytochrome P450 enzymes. *Mitochondria* - **Mitochondria** are the primary site for **beta-oxidation** of fatty acids, not omega oxidation. - Beta-oxidation sequentially removes **two-carbon units from the carboxyl end**, which is distinct from omega oxidation. - The dicarboxylic acids produced by omega oxidation may subsequently undergo beta-oxidation in mitochondria. *None of the options* - This option is incorrect because the endoplasmic reticulum is the correct cellular location for omega oxidation. - The ER contains the necessary cytochrome P450 enzymes for the hydroxylation reaction that initiates this pathway.
Question 162: Which of the following is not affected in Abetalipoproteinemia ?
- A. LDL
- B. HDL (Correct Answer)
- C. IDL
- D. VLDL
Explanation: ***HDL*** - **Abetalipoproteinemia** is caused by a defect in the **microsomal triglyceride transfer protein (MTP)**, which is essential for the assembly and secretion of **chylomicrons**, **VLDL**, and subsequently **LDL** and **IDL**. - **HDL synthesis** and secretion occur independently of MTP, as nascent HDL particles are formed in the plasma from lipids and apolipoproteins (primarily apoA-I) released from other lipoproteins and cells. *LDL* - **LDL** is critically affected in abetalipoproteinemia because it is a metabolic product of **VLDL**. - Since **VLDL** production is severely impaired due to the MTP defect, there is a profound deficiency of **LDL** in the plasma. *VLDL* - **VLDL** production is severely impaired in abetalipoproteinemia because **microsomal triglyceride transfer protein (MTP)** is required for its assembly and secretion from the liver. - The inability to load triglycerides onto apoB leads to very low or absent plasma **VLDL** levels. *IDL* - **IDL** is an intermediate lipoprotein in the metabolism of **VLDL** to **LDL**. - Given that both **VLDL** and **LDL** are severely deficient in abetalipoproteinemia, **IDL** levels are also consequently very low or absent.
Question 163: What is the metabolic abnormality associated with Zellweger syndrome?
- A. Accumulation of long-chain fatty acids
- B. Accumulation of short-chain fatty acids
- C. Accumulation of very long-chain fatty acids (Correct Answer)
- D. Accumulation of medium-chain fatty acids
Explanation: ***Accumulation of very long-chain fatty acids*** - **Zellweger syndrome** is a peroxisomal biogenesis disorder, meaning that peroxisomes, which are responsible for the **beta-oxidation** of very long-chain fatty acids (VLCFAs), are absent or dysfunctional. - The inability to break down **VLCFAs** leads to their accumulation in various tissues, causing significant neurological and systemic dysfunction. *Accumulation of long-chain fatty acids* - While peroxisomes can contribute to the metabolism of some **long-chain fatty acids (LCFAs)**, their primary role in this context is with **VLCFAs**. - **Mitochondria** are the main organelles responsible for the beta-oxidation of most LCFAs. *Accumulation of short-chain fatty acids* - **Short-chain fatty acids (SCFAs)** are primarily produced by gut bacteria and are metabolized in the mitochondria and other cellular compartments. - Their accumulation is not characteristic of **Zellweger syndrome**. *Accumulation of medium-chain fatty acids* - **Medium-chain fatty acids (MCFAs)** are primarily metabolized in the **mitochondria** and do not typically accumulate in Zellweger syndrome. - Disorders affecting MCFA metabolism usually point to different enzyme deficiencies, such as **MCAD deficiency.**
Question 164: Which of the following substances is not derived from tyrosine?
- A. Thyroxine
- B. Melanin
- C. Nicotinic acid (Correct Answer)
- D. Dopamine
Explanation: ***Nicotinic acid*** - **Nicotinic acid** (niacin, vitamin B3) is synthesized from **tryptophan** in the body, not tyrosine. - It plays a crucial role in metabolism as a precursor for NAD+ and NADH, which are involved in various enzymatic reactions. *Thyroxine* - **Thyroxine** (T4), a thyroid hormone, is derived from the amino acid **tyrosine**. - **Iodine** is incorporated into tyrosine residues on thyroglobulin to form monoiodotyrosine (MIT) and diiodotyrosine (DIT), which then couple to form T4 (and T3). *Melanin* - **Melanin**, the pigment responsible for skin, hair, and eye color, is synthesized from **tyrosine** through a pathway involving the enzyme **tyrosinase**. - This process involves the hydroxylation of tyrosine to 3,4-dihydroxyphenylalanine (DOPA) and subsequent oxidation reactions. *Dopamine* - **Dopamine**, an important neurotransmitter, is synthesized from **tyrosine** in a two-step process in the brain and adrenal medulla. - Tyrosine is first hydroxylated to DOPA by **tyrosine hydroxylase**, and then DOPA is decarboxylated to dopamine by DOPA decarboxylase.
Question 165: Which amino acid is used by the liver in the urea cycle?
- A. Glutamine
- B. Glutamate
- C. Aspartate (Correct Answer)
- D. Ornithine
Explanation: ***Aspartate*** - **Aspartate** provides the second nitrogen atom to the urea cycle, directly contributing to the formation of **argininosuccinate** through condensation with citrulline. - It is crucial for the efficient removal of **ammonia** in the form of urea. *Glutamine* - **Glutamine** transports ammonia from peripheral tissues to the liver and kidneys, but it is typically deamidated to **glutamate** before its nitrogen can enter the urea cycle. - While it's a major ammonia carrier, it's not directly incorporated into urea as an intact amino acid. *Glutamate* - **Glutamate** can donate its amino group to form **aspartate** (via transamination with oxaloacetate) or release ammonia directly (via glutamate dehydrogenase), both of which then enter the urea cycle. - However, glutamate itself is not directly incorporated into the urea molecule in the same way aspartate is. *Ornithine* - **Ornithine** is an amino acid that participates in the urea cycle as a carrier molecule, being regenerated at the end of each cycle. - While essential for the cycle to function, it is not "used" in the sense of being consumed or providing nitrogen for urea formation - rather it acts as a catalytic intermediate that is recycled.
Question 166: Anaplerotic reaction is catalyzed by?
- A. Enolase
- B. Pyruvate kinase
- C. G6PD
- D. Pyruvate carboxylase (Correct Answer)
Explanation: ***Pyruvate carboxylase*** - **Pyruvate carboxylase** catalyzes the ATP-dependent carboxylation of **pyruvate** to **oxaloacetate**. - This reaction is crucial for replenishing intermediates of the **citric acid cycle**, making it an anaplerotic reaction. *Enolase* - **Enolase** catalyzes the conversion of **2-phosphoglycerate** to **phosphoenolpyruvate** in **glycolysis**. - This reaction is part of catabolism and does not replenish citric acid cycle intermediates. *Pyruvate kinase* - **Pyruvate kinase** catalyzes the final step of **glycolysis**, converting **phosphoenolpyruvate** to **pyruvate**. - This enzyme is involved in ATP production and the overall catabolic pathway of glucose. *G6PD* - **Glucose-6-phosphate dehydrogenase (G6PD)** is the rate-limiting enzyme in the **pentose phosphate pathway**. - It produces **NADPH** and precursors for nucleotide synthesis, but not directly involved in anaplerotic reactions for the citric acid cycle.
Question 167: Which macronutrient has the highest thermogenic effect?
- A. Fat
- B. Proteins (Correct Answer)
- C. Carbohydrate
- D. Alcohol
Explanation: ***Proteins*** - Proteins have the **highest thermogenic effect** (also known as the **thermic effect of food** or TEF) among macronutrients, typically ranging from **20-30%** of their caloric content. - This high TEF is due to the energy required for their **digestion**, **absorption**, and **metabolism** (e.g., deamination, protein synthesis), making them more metabolically "expensive" to process than fats or carbohydrates. *Fat* - Fat has the **lowest thermogenic effect**, accounting for approximately **0-3%** of its caloric content. - This low TEF is because fats are **easily absorbed** and stored, requiring minimal energy for their processing. *Carbohydrate* - Carbohydrates have an intermediate thermogenic effect, typically ranging from **5-10%** of their caloric content. - The energy expenditure for carbohydrate metabolism involves processes like **digestion**, **absorption**, and **glucose oxidation** or conversion to glycogen. *Alcohol* - While alcohol has a relatively high thermogenic effect (**20-25%**), it is **not classified as a macronutrient** in traditional nutritional science. - The three primary macronutrients are proteins, carbohydrates, and fats. Among these, **proteins** have the highest TEF.
Question 168: Pantothenic acid is needed for donating the following moiety?
- A. Carboxyl
- B. Hydroxyl
- C. Amino
- D. Acetyl group (Correct Answer)
Explanation: ***Acetyl group*** - **Pantothenic acid** (vitamin B5) is a crucial component of **coenzyme A (CoA)**, which plays a central role in transferring **acetyl groups**. - This transfer is vital in numerous metabolic pathways, including the **Krebs cycle**, fatty acid synthesis, and fatty acid oxidation. *Carboxyl* - The transfer of **carboxyl groups** is typically mediated by a different coenzyme, **biotin** (vitamin B7), not pantothenic acid. - Biotin-dependent enzymes are involved in carboxylation reactions like those in gluconeogenesis and fatty acid synthesis. *Hydroxyl* - While hydroxyl groups are common in organic chemistry, pantothenic acid's primary role is not the donation of isolated **hydroxyl groups**. - Hydroxyl groups are often donated or accepted during redox reactions or hydrolysis, often by specific enzymes directly. *Amino* - The transfer of **amino groups** is primarily associated with **pyridoxal phosphate (PLP)**, the active form of vitamin B6. - PLP-dependent enzymes, such as **transaminases**, are critical for amino acid metabolism.
Question 169: Beta-alanine is derived from ?
- A. Adenosine
- B. Uracil (Correct Answer)
- C. Guanosine
- D. Thymine
Explanation: ***Correct Option: Uracil*** - **Uracil**, a pyrimidine base found in RNA, is the primary source of **β-alanine** through its catabolic pathway. - The degradation sequence: **Uracil** → **Dihydrouracil** → **β-Ureidopropionate** → **β-Alanine** + CO₂ + NH₃ - This pathway is catalyzed by enzymes including dihydropyrimidine dehydrogenase and β-ureidopropionase. - **β-Alanine** is also obtained from dietary sources and is a component of carnosine and pantothenic acid (Vitamin B5). *Incorrect Option: Thymine* - **Thymine** is a pyrimidine base in DNA with a similar catabolic pathway to uracil. - However, thymine produces **β-aminoisobutyrate** (NOT β-alanine) as its final product. - The pathway: **Thymine** → **Dihydrothymine** → **β-Ureidoisobutyrate** → **β-Aminoisobutyrate** - The extra methyl group on thymine (compared to uracil) results in a different end product. *Incorrect Option: Adenosine* - **Adenosine** is a purine nucleoside composed of adenine and ribose. - Purine catabolism leads to **uric acid** formation, not β-alanine. - It follows the pathway: Adenosine → Inosine → Hypoxanthine → Xanthine → Uric acid. *Incorrect Option: Guanosine* - **Guanosine** is a purine nucleoside consisting of guanine and ribose. - Like adenosine, it is catabolized to **uric acid** via xanthine. - It does not participate in β-alanine synthesis.
Question 170: Which of the following is not a precursor in the synthesis of pyrimidines?
- A. Glutamine
- B. Carbon dioxide (CO2)
- C. Aspartic acid
- D. Thymidine (Correct Answer)
Explanation: ***Thymidine*** - **Thymidine** is a *nucleoside* consisting of deoxyribose and thymine. It is a *product* and a component of DNA, not a precursor in the *de novo synthesis* of pyrimidine bases. - While it can be incorporated into DNA via the *salvage pathway*, it does not serve as an initial building block for the pyrimidine ring itself. *Glutamine* - **Glutamine** provides the **nitrogen atoms** crucial for the formation of the pyrimidine ring, specifically N3 in the pyrimidine base. - It is a key donor of *amino groups* in various anabolic pathways, including nucleotide synthesis. *Carbon dioxide (CO2)* - **Carbon dioxide (CO2)** contributes one of the carbon atoms (C2) to the pyrimidine ring. - It combines with **ammonia** (derived from glutamine) to form **carbamoyl phosphate**, an essential intermediate. *Aspartic acid* - **Aspartic acid** provides four atoms (N1, C4, C5, C6) of the pyrimidine ring. - Its carbon skeleton and amino group are directly incorporated into the pyrimidine structure during the *de novo synthesis* pathway.