NEET-PG 2013 - Biochemistry Practice Questions

Q: Which of the following is NOT required for gluconeogenesis from lactate?

Transamination of pyruvate to alanine. ***Transamination of pyruvate to alanine*** - While **alanine** can be a substrate for gluconeogenesis, **lactate** is directly converted to pyruvate, which then enters the gluconeogenesis pathway. **Transamination to alanine** is not a required intermediate step for lactate-derived glucose production. - The direct conversion of **lactate to pyruvate** by **lactate dehydrogenase** is the key initial step, not its conversion to alanine. *Transport of lactate from muscle to liver* - **Lactate** produced in muscles (e.g., during intense exercise) must be transported to the **liver** via the bloodstream to be used for **gluconeogenesis** in the **Cori cycle**. - This transport is essential for clearing lactate from the periphery and supplying the liver with a gluconeogenic precursor. *Conversion of lactate to pyruvate* - **Lactate dehydrogenase** catalyzes the reversible conversion of **lactate to pyruvate**, which is the critical first step in converting lactate into a gluconeogenic substrate. - This reaction regenerates **NAD+** (not NADH), which is necessary for glycolysis to continue in muscle tissue. *None of the above* - This option is incorrect because there IS a step listed above that is not required: **transamination of pyruvate to alanine** is indeed not necessary for gluconeogenesis from lactate, making Option A the correct answer to this "NOT required" question.

Q: Which of the following tissues relies EXCLUSIVELY on anaerobic glycolysis for ATP production?

Mature RBCs (exclusively anaerobic). ***Mature RBCs (exclusively anaerobic)*** - **Mature red blood cells** lack mitochondria, making them incapable of **oxidative phosphorylation** and thus relying entirely on **anaerobic glycolysis** for ATP. - This pathway produces **2 net ATP** molecules per glucose molecule, which is sufficient for their metabolic needs like maintaining ion gradients. *Skeletal muscle during exercise (anaerobic)* - While skeletal muscle can perform **anaerobic glycolysis** during intense exercise when oxygen supply is limited, it is not an exclusive reliance. - Skeletal muscle also utilizes **aerobic respiration** and **creatine phosphate** for ATP production depending on activity level and oxygen availability. *Cardiac muscle (primarily aerobic)* - **Cardiac muscle** has a very high metabolic demand and is rich in **mitochondria**, relying almost exclusively on **aerobic respiration** for ATP production. - It uses fatty acids, glucose, and lactate as fuel sources, producing a large amount of ATP efficiently with oxygen. *Liver hepatocytes (primarily aerobic)* - **Liver hepatocytes** are highly metabolically active and primarily rely on **aerobic respiration** for ATP production, performing diverse functions such as gluconeogenesis, glycogenolysis, and detoxification. - Although the liver can perform some anaerobic glycolysis under hypoxic conditions, it is not its exclusive or primary mode of ATP synthesis.

Q: The energy for glycogenesis is provided by -

UTP. ***UTP*** - **Uridine triphosphate (UTP)** is essential for **glycogenesis** as it activates glucose by forming **UDP-glucose** from glucose-1-phosphate. - The reaction (Glucose-1-P + UTP → UDP-glucose + PPi) creates a **high-energy intermediate** that drives glycogen synthesis. - The subsequent hydrolysis of pyrophosphate (PPi) makes this activation step **irreversible**, and the energy stored in UDP-glucose is used for **glycosidic bond formation** when glucose is added to the growing glycogen chain. *GTP* - **Guanosine triphosphate (GTP)** is primarily involved in **protein synthesis**, G-protein signaling, and the citric acid cycle. - It is not used for glucose activation in glycogenesis; that role is specific to **UTP**. *GDP* - **Guanosine diphosphate (GDP)** is a product of GTP hydrolysis and functions in regulatory processes. - It does not serve as an energy donor for glycogen synthesis. *AMP* - **Adenosine monophosphate (AMP)** is a low-energy signal molecule that indicates cellular energy depletion. - High AMP levels **inhibit glycogenesis** and activate glycogenolysis through allosteric regulation of key enzymes. - It does not provide energy for anabolic pathways like glycogen synthesis.

Q: Which of the following tests is most commonly used to detect glucose in urine?

c) Glucose-oxidase test. ***Glucose-oxidase test*** - The **glucose-oxidase test** is a highly specific and sensitive enzymatic test used to detect **glucose** in urine. - It uses the enzyme glucose oxidase which specifically catalyzes the oxidation of glucose to gluconic acid and hydrogen peroxide, which then produces a color change. - This is the **most commonly used method** in modern clinical practice for detecting glucosuria due to its **high specificity for glucose** and ease of use (dipstick method). - It is the preferred test for **monitoring diabetes** and screening for hyperglycemia. *Benedict's test* - **Benedict's test** is a general chemical test for **all reducing sugars** (glucose, fructose, galactose, lactose, maltose), not specifically glucose. - It works by reducing copper sulfate (Cu²⁺) to copper oxide (Cu⁺) in an alkaline solution, forming a colored precipitate (green, yellow, orange, or brick-red depending on sugar concentration). - While it can detect glucose, it **lacks specificity** and can give false positives with other reducing substances (vitamin C, certain drugs), making it less suitable for routine clinical testing. *Fehling's solution* - **Fehling's solution** is also a general chemical test for **reducing sugars** based on copper reduction, similar to Benedict's test. - It consists of two solutions mixed before use and detects various reducing sugars, not just glucose. - It is **not commonly used in clinical urine analysis** due to lack of specificity and the need for heating and mixing two solutions, making it impractical compared to the simple glucose-oxidase dipstick. *None of the above* - This option is incorrect because the **glucose-oxidase test** is indeed the most commonly used test for detecting glucose in urine in modern clinical practice.

Q: Fructose intolerance is due to deficiency of which enzyme?

Aldolase B. ***Aldolase B*** - **Hereditary fructose intolerance** is a genetic disorder caused by a deficiency in the enzyme **aldolase B**. - This deficiency leads to an accumulation of **fructose-1-phosphate** in the liver, kidneys, and small intestine, causing **hypoglycemia**, **vomiting**, and **liver damage** upon exposure to fructose. *Fructokinase* - A deficiency in **fructokinase** causes **essential fructosuria**, a benign metabolic disorder. - This condition is asymptomatic because **fructose** simply accumulates in the blood and urine without causing significant clinical problems. *Triokinase* - **Triokinase**, also known as **glycerol kinase**, is involved in glycerol metabolism, converting glycerol to **glycerol-3-phosphate**. - Its deficiency is not directly linked to fructose intolerance and typically presents with **hyperglycerolemia**. *Aldolase A* - **Aldolase A** is one of the three aldolase isoenzymes (A, B, and C) and is primarily involved in **glycolysis**, specifically in the breakdown of **fructose-1,6-bisphosphate**. - A deficiency in aldolase A can lead to **hemolytic anemia** and **myopathy**, not directly fructose intolerance.

Q: Which transporter is responsible for the transport of glucose in the pancreas?

GLUT 2. ***GLUT 2*** - **GLUT2** is a **low-affinity, high-capacity** glucose transporter primarily found in the **pancreatic beta cells**, liver, small intestine, and kidneys. - In pancreatic beta cells, GLUT2 allows rapid entry of glucose for metabolism, leading to **insulin secretion** in response to elevated blood glucose levels. *GLUT 1* - **GLUT1** is a **ubiquitous glucose transporter** found in most tissues, including red blood cells and the blood-brain barrier. - It has a high affinity for glucose, ensuring **basal glucose uptake** even at low concentrations. *GLUT 3* - **GLUT3** is a **high-affinity glucose transporter** concentrated in **neurons** and the brain. - Its efficient glucose uptake is critical for the constant and high energy demands of the central nervous system. *GLUT 4* - **GLUT4** is an **insulin-dependent glucose transporter** primarily found in **adipose tissue** and **striated muscle (skeletal and cardiac muscle)**. - Insulin stimulates the translocation of GLUT4 to the cell membrane, facilitating glucose uptake from the blood after a meal.

Q: Inhibition of glycolysis by increased supply of O2 is called ?

Pasteur effect. ***Pasteur effect*** - The **Pasteur effect** describes the phenomenon where the rate of **glycolysis** is inhibited when **oxygen** is available (aerobic conditions). - This inhibition occurs because **oxidative phosphorylation** is more efficient at generating ATP, leading to reduced reliance on glycolysis for energy production. *Crabtree phenomenon* - The **Crabtree phenomenon** is the opposite of the Pasteur effect, where high concentrations of **glucose** inhibit oxygen consumption in the presence of oxygen. - This is primarily observed in some **cancer cells** and yeast, leading to increased glycolysis even under aerobic conditions. *Lewis phenomenon* - The **Lewis phenomenon** (also known as the hunting reaction) refers to the cyclical vasodilation and constriction of peripheral blood vessels in response to **cold exposure**. - It's a physiological response to protect tissues from **frostbite** and is not related to glycolysis or oxygen supply. *None of the options* - This option is incorrect as the phenomenon described, inhibition of glycolysis by increased O2, is a well-established biochemical process known as the **Pasteur effect**.

Q: Which of the following is not a phospholipid ?

Ganglioside. ***Ganglioside*** - Gangliosides are a type of **glycosphingolipid** because their structure includes a ceramide (a sphingoid base linked to a fatty acid) and a carbohydrate portion with one or more **sialic acid** residues, but no phosphate group. - They are primarily found in **nerve cell membranes** and are crucial for cell-cell recognition and signaling, differentiating them from phospholipids which contain a phosphate group. *Lecithin* - Lecithin, specifically **phosphatidylcholine**, is a common phospholipid characterized by a **phosphate group** and a **choline head group** attached to a diacylglycerol backbone. - It plays vital roles in cell membrane structure and function and is an important emulsifier. *Plasmalogen* - Plasmalogens are a class of phospholipids characterized by a **vinyl ether linkage** at the *sn*-1 position of the glycerol backbone, instead of the typical ester linkage found in other phospholipids. - They retain the defining **phosphate group** that classifies them as phospholipids. *Cardiolipin* - Cardiolipin is a unique phospholipid composed of **two phosphatidic acid moieties** connected by a glycerol molecule, resulting in four fatty acid chains and two phosphate groups. - It is predominantly found in the **inner mitochondrial membrane**, essential for mitochondrial function.

Q: Ketone bodies are not used by?

RBC. ***RBC*** - Red blood cells **lack mitochondria**, which are essential organelles for the **oxidation of ketone bodies** (acetoacetate and β-hydroxybutyrate) for energy production. - Their primary energy source is **anaerobic glycolysis** of glucose. *Muscle* - **Skeletal and cardiac muscles** readily utilize **ketone bodies** as an alternative fuel source, especially during prolonged fasting or starvation. - This helps to conserve glucose for other tissues, particularly the brain. *Brain* - The brain can adapt to use **ketone bodies** for energy when glucose supply is limited, such as during prolonged fasting or in cases of uncontrolled diabetes. - This process is crucial for brain function when glucose levels are low. *Renal cortex* - The **renal cortex** is capable of utilizing **ketone bodies** for energy, particularly during starvation. - The kidney is also involved in the **synthesis of glucose** (gluconeogenesis) and the excretion of ketone bodies.

Q: Which of the following lipoproteins is most strongly associated with an increased risk of cardiovascular diseases and is commonly referred to as "bad cholesterol"?

LDL. ***LDL*** - **Low-density lipoprotein (LDL)** is commonly referred to as "bad" cholesterol because elevated levels are the **primary driver** of atherosclerotic plaque buildup in arterial walls. - LDL particles transport cholesterol from the liver to peripheral tissues; when present in excess, they infiltrate the arterial intima and undergo oxidative modification, triggering inflammatory responses that lead to atherosclerosis. - **Clinical significance:** LDL cholesterol is the primary target of lipid-lowering therapy in cardiovascular disease prevention. *VLDL* - **Very low-density lipoprotein (VLDL)** primarily transports endogenously synthesized **triglycerides** from the liver to peripheral tissues. - While elevated VLDL levels do contribute to cardiovascular risk (particularly through conversion to small, dense LDL particles), it is not the primary lipoprotein targeted in cardiovascular risk assessment. *Chylomicron* - **Chylomicrons** transport **dietary lipids** (triglycerides and cholesterol) from the intestines to tissues after meals. - They are rapidly cleared from circulation (half-life of 5-10 minutes) and are typically not present during fasting, making their contribution to chronic atherosclerotic plaque formation minimal. *Lp(a)* - **Lipoprotein(a) [Lp(a)]** is structurally similar to LDL but contains an additional apolipoprotein(a) molecule, which has homology to plasminogen and may interfere with fibrinolysis. - While Lp(a) is an independent cardiovascular risk factor, it is less commonly measured in routine clinical practice, and **LDL remains the cornerstone lipoprotein** for cardiovascular risk stratification and management.

Question 1

Which of the following is NOT required for gluconeogenesis from lactate?

Accepted Answer

Transamination of pyruvate to alanine

Answer

Transport of lactate from muscle to liver

Answer

Conversion of lactate to pyruvate

Answer

None of the above

Question 2

Which of the following tissues relies EXCLUSIVELY on anaerobic glycolysis for ATP production?

Accepted Answer

Mature RBCs (exclusively anaerobic)

Answer

Skeletal muscle during exercise (anaerobic)

Answer

Liver hepatocytes (primarily aerobic)

Answer

Cardiac muscle (primarily aerobic)

Question 3

The energy for glycogenesis is provided by -

Accepted Answer

UTP

Answer

GTP

Answer

GDP

Answer

AMP

Question 4

Which of the following tests is most commonly used to detect glucose in urine?

Accepted Answer

c) Glucose-oxidase test

Answer

a) Benedicts test

Answer

b) Fehling solution

Answer

d) None of the above

Question 5

Fructose intolerance is due to deficiency of which enzyme?

Accepted Answer

Aldolase B

Answer

Aldolase A

Answer

Fructokinase

Answer

Triokinase

Question 6

Which transporter is responsible for the transport of glucose in the pancreas?

Accepted Answer

GLUT 2

Answer

GLUT 1

Answer

GLUT 3

Answer

GLUT 4

Question 7

Inhibition of glycolysis by increased supply of O2 is called ?

Accepted Answer

Pasteur effect

Answer

Crabtree phenomenon

Answer

Lewis phenomenon

Answer

None of the options

Question 8

Which of the following is not a phospholipid ?

Accepted Answer

Ganglioside

Answer

Lecithin

Answer

Plasmalogen

Answer

Cardiolipin

Question 9

Ketone bodies are not used by?

Accepted Answer

RBC

Answer

Brain

Answer

Muscle

Answer

Renal cortex

Question 10

Which of the following lipoproteins is most strongly associated with an increased risk of cardiovascular diseases and is commonly referred to as "bad cholesterol"?

Accepted Answer

LDL

Answer

VLDL

Answer

Chylomicron

Answer

Lp (a)

NEET-PG 2013 — Biochemistry