Cell Membrane Structure and Function Indian Medical PG Practice Questions and MCQs
Practice Indian Medical PG questions for Cell Membrane Structure and Function. These multiple choice questions (MCQs) cover important concepts and help you prepare for your exams.
Cell Membrane Structure and Function Indian Medical PG Question 1: Assertion: RMP depends on proteins and phosphate ions.
Reason: Diffusion potential can be calculated using nernst equation.
Choose the best statement regarding the assertion and reason.
- A. Assertion false, Reason true
- B. Both true, Reason is the explanation of assertion
- C. Assertion true, Reason false
- D. Both true, Reason is not the explanation of assertion (Correct Answer)
Cell Membrane Structure and Function Explanation: ***Both true, Reason is not the explanation of assertion***
- The **Assertion is TRUE**: The resting membrane potential (RMP) does depend on intracellular **proteins and phosphate ions**, which are large, non-diffusible anions that remain trapped inside the cell. These molecules contribute significantly to the **net negative charge** of the intracellular compartment and create the **Gibbs-Donnan effect**. At physiological pH, most intracellular proteins are negatively charged, and phosphate ions (HPO₄²⁻, H₂PO₄⁻) are major intracellular anions. While the primary determinants of RMP are the concentration gradients and membrane permeabilities of K⁺, Na⁺, and Cl⁻ ions, the presence of non-diffusible anions (proteins and phosphates) is essential for establishing the baseline negative intracellular environment.
- The **Reason is TRUE**: The **Nernst equation** (E = RT/zF × ln[ion]out/[ion]in) is indeed used to calculate the **equilibrium potential** (also called diffusion potential) for a single permeable ion. This equation determines the membrane potential at which the electrical gradient exactly balances the concentration gradient for that specific ion, resulting in no net ion movement.
- **However, the Reason does NOT explain the Assertion**: The Nernst equation calculates equilibrium potentials for diffusible ions like K⁺, Na⁺, and Cl⁻. It does NOT explain the contribution of **non-diffusible** anions (proteins and phosphates) to the RMP. The actual RMP, which involves multiple ions with different permeabilities, is calculated using the **Goldman-Hodgkin-Katz (GHK) equation**, not the Nernst equation. The two statements are independently true but address different aspects of membrane potential physiology.
*Assertion false, Reason true*
- This is **incorrect** because the assertion is actually TRUE. Intracellular proteins and phosphate ions do contribute to the RMP by providing fixed negative charges that influence the distribution of diffusible ions and create the electrochemical environment necessary for RMP establishment.
*Both true, Reason is the explanation of assertion*
- This is **incorrect** because while both statements are true, the Nernst equation (Reason) does not explain how proteins and phosphate ions contribute to RMP (Assertion). The Nernst equation applies only to permeable ions, whereas proteins and phosphates are impermeant molecules whose role is explained by the Gibbs-Donnan equilibrium and their contribution to fixed negative charges.
*Assertion true, Reason false*
- This is **incorrect** because the reason is TRUE. The Nernst equation is a fundamental and valid equation in membrane physiology that accurately calculates the equilibrium potential for any permeable ion based on its concentration gradient.
Cell Membrane Structure and Function Indian Medical PG Question 2: Which of the following statements about the Na-K pump is false?
- A. It is not directly involved in the generation of action potentials.
- B. It is electrogenic
- C. It needs ATP for its functioning
- D. It is located on the apical membrane of cell (Correct Answer)
Cell Membrane Structure and Function Explanation: ***It is located on the apical membrane of cell***
- The **Na-K pump**, or **Na+/K+-ATPase**, is primarily located on the **basolateral membrane** of epithelial cells, not **apical membrane**.
- Its strategic placement on the basolateral membrane is crucial for maintaining cellular polarity and driving transepithelial transport processes, such as reabsorption in the kidneys.
*It is electrogenic*
- The Na-K pump is indeed **electrogenic** because it transports three **Na+ ions** out of the cell for every two **K+ ions** pumped in.
- This unequal charge distribution creates a net movement of one positive charge out of the cell, contributing to the **resting membrane potential**.
*It is not directly involved in the generation of action potentials.*
- While the Na-K pump is essential for **maintaining the ion gradients** necessary for **action potentials**, it is not directly involved in their rapid depolarization or repolarization phases.
- Action potentials are primarily generated by the rapid opening and closing of **voltage-gated ion channels** (e.g., Na+ and K+ channels).
*It needs ATP for its functioning*
- The Na-K pump is an **active transport mechanism** that moves ions against their concentration gradients, requiring **energy in the form of ATP hydrolysis**.
- This **ATP-dependent process** ensures the continuous maintenance of the Na+ and K+ gradients, crucial for various cellular functions, including nerve impulse transmission and muscle contraction.
Cell Membrane Structure and Function Indian Medical PG Question 3: Which of the following statements accurately describes G proteins?
- A. Are associated with cellular membranes and play a crucial role in signal transduction. (Correct Answer)
- B. Regulate second messengers like cyclic adenosine monophosphate (cAMP).
- C. Play a role in the amplification of hormonal signals.
- D. Consist of three subunits: alpha, beta, and gamma.
Cell Membrane Structure and Function Explanation: ***Are associated with cellular membranes and play a crucial role in signal transduction.***
- **G proteins** are critical components of **G protein-coupled receptors (GPCRs)**, which are embedded in the **cellular membrane**.
- They act as molecular switches, relaying signals from diverse extracellular stimuli (like hormones, neurotransmitters, and light) across the cell membrane into the cell's interior, thus initiating a **signal transduction pathway**.
- This is the most comprehensive and accurate description of G proteins as a whole.
*Regulate second messengers like cyclic adenosine monophosphate (cAMP).*
- While G proteins do regulate second messengers such as **cAMP** by activating enzymes like **adenylyl cyclase**, this describes a **specific mechanism of action**, not a broad description of what G proteins are.
- This statement is accurate but too narrow, describing one particular function rather than their fundamental role in membrane association and general signal transduction.
*Play a role in the amplification of hormonal signals.*
- G proteins are involved in signal transduction pathways that can lead to **signal amplification**, but this is a **downstream effect**, not their primary defining characteristic.
- Mentioning their role only in amplification of hormonal signals is too narrow and doesn't capture their fundamental nature as signal transducers.
*Consist of three subunits: alpha, beta, and gamma.*
- This statement accurately describes **heterotrimeric G proteins** (the most common type involved in GPCR signaling), which do have three subunits (Gα, Gβ, Gγ).
- However, this is **incorrect as a general description** because there are also **monomeric G proteins** (small GTPases like Ras, Rho, Rac, and Rab) that consist of a single polypeptide chain.
- Since the question asks about "G proteins" in general without specifying heterotrimeric G proteins, this statement is incomplete and therefore incorrect.
Cell Membrane Structure and Function Indian Medical PG Question 4: Which of the following is the primary mechanism that drives sodium reabsorption in the proximal tubule?
- A. Sodium reabsorption through cotransport with amino acids at the luminal membrane.
- B. Sodium reabsorption through cotransport with glucose at the luminal membrane.
- C. Sodium reabsorption through countertransport with hydrogen ions at the luminal membrane.
- D. Active sodium transport via the Na+-K+-ATPase pump at the basolateral membrane. (Correct Answer)
Cell Membrane Structure and Function Explanation: ***Active sodium transport via the Na+-K+-ATPase pump at the basolateral membrane.***
- This pump **actively transports sodium out of the cell** into the interstitial fluid, creating a low intracellular sodium concentration.
- The **Na+-K+-ATPase** is the primary driver of sodium reabsorption throughout the nephron, creating the electrochemical gradient for other sodium transporters.
*Sodium reabsorption through cotransport with amino acids at the luminal membrane.*
- While **sodium-amino acid cotransport** does occur in the proximal tubule, it accounts for only a fraction of total sodium reabsorption.
- The primary driving force for this cotransport is the **low intracellular sodium concentration** maintained by the Na+-K+-ATPase.
*Sodium reabsorption through cotransport with glucose at the luminal membrane.*
- **Sodium-glucose cotransporters (SGLTs)** are crucial for glucose reabsorption in the proximal tubule, moving glucose into the cell along with sodium.
- However, glucose cotransport represents a specific mechanism for glucose handling, not the overarching mechanism for sodium reabsorption.
*Sodium reabsorption through countertransport with hydrogen ions at the luminal membrane.*
- The **Na+-H+ exchanger (NHE3)** is significant for exchanging sodium for hydrogen ions at the luminal membrane in the proximal tubule.
- This mechanism is important for **acid-base balance** and some sodium reabsorption, but it is secondary to the Na+-K+-ATPase in driving the overall sodium gradient.
Cell Membrane Structure and Function Indian Medical PG Question 5: Which ion movement is primarily responsible for hyperpolarization of the cell membrane?
- A. Chloride (Cl-) influx
- B. Potassium (K+) efflux (Correct Answer)
- C. Sodium (Na+) influx
- D. None of the options
Cell Membrane Structure and Function Explanation: ***Potassium (K+) efflux***
- **Potassium efflux** (K+ leaving the cell) is the **primary mechanism** responsible for hyperpolarization of the cell membrane across most cell types.
- When K+ channels open, positive charges leave the cell, making the intracellular environment more negative relative to the extracellular space, thereby **hyperpolarizing** the membrane.
- This mechanism is responsible for:
- **Afterhyperpolarization** following action potentials
- Setting the **resting membrane potential** close to the K+ equilibrium potential (-90 mV)
- **Repolarization and hyperpolarization phases** of action potentials
- Examples include delayed rectifier K+ channels and calcium-activated K+ channels.
*Chloride (Cl-) influx*
- While Cl- influx can cause hyperpolarization (especially through **GABA-A receptors** in neurons), it is a **secondary or specialized mechanism**, not the primary one.
- In many mature neurons, the Cl- equilibrium potential is close to the resting potential, limiting its hyperpolarizing effect.
- This mechanism is important in **inhibitory neurotransmission** but not universally across all cell types.
*Sodium (Na+) influx*
- **Sodium influx** through voltage-gated sodium channels is responsible for the **depolarization phase** of an action potential.
- This makes the inside of the cell significantly more positive (+30 to +40 mV), which is the opposite of hyperpolarization.
*None of the options*
- This option is incorrect because **potassium efflux** is indeed the primary mechanism for membrane hyperpolarization.
Cell Membrane Structure and Function Indian Medical PG Question 6: Some cells secrete chemicals into the extracellular fluid that act on cells in the same tissue. Which of the following refers to this type of regulation?
- A. Neural
- B. Endocrine
- C. Neuroendocrine
- D. Paracrine (Correct Answer)
Cell Membrane Structure and Function Explanation: ***Paracrine***
- **Paracrine signaling** involves chemical messengers, or **paracrine factors**, that act on **neighboring cells** within the **same tissue** without entering the bloodstream.
- This type of regulation is crucial for local communication and coordination, such as in wound healing or immune responses.
*Neural*
- **Neural regulation** involves communication via **neurons** that transmit **electrical signals** (action potentials) and release **neurotransmitters** at synapses.
- Neurotransmitters act on target cells, which can be distant from the neuron, for rapid and precise responses throughout the body.
*Endocrine*
- **Endocrine regulation** involves glands that secrete **hormones** directly into the **bloodstream**, which then travel to distant target cells in other tissues or organs.
- This form of signaling leads to widespread and long-lasting effects, such as growth regulation or metabolic control.
*Neuroendocrine*
- **Neuroendocrine regulation** is a hybrid system where specialized **neurons** (neurosecretory cells) release **hormones** into the **bloodstream**, rather than releasing neurotransmitters into a synapse.
- An example is the hypothalamus secreting ADH and oxytocin, which act on distant target organs.
Cell Membrane Structure and Function Indian Medical PG Question 7: Magnesium is not involved in ?
- A. Cellular oxidation
- B. Hemoglobin synthesis (Correct Answer)
- C. Membrane transport
- D. Glucose tolerance
Cell Membrane Structure and Function Explanation: ***Hemoglobin synthesis***
- **Magnesium** is not directly involved in the synthesis of **hemoglobin**; **iron** is the crucial mineral for this process.
- While magnesium is vital for many enzymatic reactions, it does not play a direct role in forming the heme structure or globin chains.
*Cellular oxidation*
- **Magnesium** acts as a **cofactor** for numerous enzymes involved in **cellular respiration** and **oxidative phosphorylation**, which are key processes in cellular oxidation.
- These enzymatic reactions are critical for energy production within the cell.
*Membrane transport*
- **Magnesium** ions are essential for the proper functioning of various **ion channels** and **pumps**, such as the **Na+/K+ ATPase**, which are fundamental for maintaining **membrane potential** and **active transport**.
- It influences the permeability of cell membranes and the movement of substances across them.
*Glucose tolerance*
- **Magnesium** plays a significant role in **glucose metabolism** and **insulin signaling**, affecting **glucose uptake** and utilization by cells, thereby influencing **glucose tolerance**.
- Deficiency in magnesium has been linked to **insulin resistance** and an increased risk of **type 2 diabetes**.
Cell Membrane Structure and Function Indian Medical PG Question 8: HIV envelope is formed by:
- A. Host cell
- B. Virus
- C. Both (Correct Answer)
- D. None of the options
Cell Membrane Structure and Function Explanation: ***Both (Correct Answer)***
- The HIV envelope is a **composite structure** derived from both host and viral components
- The **lipid bilayer** is acquired from the **host cell membrane** during viral budding
- **Viral glycoproteins (gp120 and gp41)** encoded by the viral genome are inserted into this host-derived membrane
- This makes the envelope a true hybrid structure essential for viral infectivity
*Host cell (Incomplete)*
- While the **lipid bilayer** of the envelope comes from the host cell membrane during budding, this alone does not form a functional envelope
- The host cell provides the membrane scaffold but lacks the viral glycoproteins necessary for receptor binding and cell entry
- Without viral proteins, the envelope cannot mediate infection
*Virus (Incomplete)*
- The virus encodes essential **envelope glycoproteins** (gp120 for receptor binding, gp41 for membrane fusion)
- However, the virus does **not synthesize the lipid bilayer** itself
- The viral genome lacks genes for lipid synthesis; the membrane must be acquired from the host
*None of the options*
- This is incorrect as the HIV envelope clearly requires contributions from **both** the host cell (lipid membrane) and the virus (glycoproteins)
Cell Membrane Structure and Function Indian Medical PG Question 9: Which of the following statements about apoptosis is not true?
- A. Cellular swelling (Correct Answer)
- B. Nuclear compaction
- C. Intact cell membrane
- D. Formation of apoptotic bodies
Cell Membrane Structure and Function Explanation: ***Cellular swelling***
- **Apoptosis**, or programmed cell death, is characterized by cell shrinkage, not cellular swelling.
- **Cellular swelling** is typically seen in **necrosis**, which is an uncontrolled form of cell death often due to injury.
*Nuclear compaction*
- **Nuclear compaction**, or **pyknosis**, is a hallmark feature of apoptosis where the nucleus condenses and fragments.
- This process is crucial for the organized dismantling of the cell during programmed cell death.
*Intact cell membrane*
- In apoptosis, the **cell membrane** generally remains intact until the very late stages, preventing the release of cellular contents and subsequent inflammation.
- This intactness differentiates apoptosis from necrosis, where the cell membrane ruptures early.
*Formation of apoptotic bodies*
- The cell fragments into small, membrane-bound structures called **apoptotic bodies**, which are then readily engulfed by phagocytes.
- This mechanism allows for the efficient removal of dying cells without triggering an inflammatory response.
Cell Membrane Structure and Function Indian Medical PG Question 10: Equilibrium potential for an ion is calculated by:
- A. Gibbs Donnan Equilibrium
- B. Nernst Equation (Correct Answer)
- C. Goldman Equation
- D. None of the options
Cell Membrane Structure and Function Explanation: ***Nernst Equation***
- The **Nernst equation** is used to calculate the **equilibrium potential** for a **single ion** across a semi-permeable membrane.
- It considers the **charge of the ion**, the **temperature**, and the **concentration gradient** of the ion across the membrane.
*Gibbs Donnan Equilibrium*
- The **Gibbs-Donnan equilibrium** describes the distribution of **permeable ions** when there is a **non-permeable charged molecule** on one side of a membrane.
- It focuses on the **overall distribution of ions** and water, rather than the equilibrium potential of a *single* ion.
*Goldman Equation*
- The **Goldman-Hodgkin-Katz (GHK) equation**, often referred to as the **Goldman equation**, calculates the **resting membrane potential** of a cell.
- It accounts for the **permeability and concentration gradients** of *multiple* ions (e.g., Na+, K+, Cl-) that contribute to the membrane potential.
*None of the options*
- This option is incorrect because the **Nernst Equation** is specifically designed for calculating the equilibrium potential of a single ion.
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