What is the most important tool used in genetic engineering?
If the content of adenine (A) is 15%, what is the percentage of guanine (G) in the DNA?
The gaps between Okazaki fragments on the lagging strand during DNA replication are rejoined and sealed by:
By which enzyme is cDNA synthesized from RNA?
Which of the following is not classified as a chaperone protein?
Which of the following is NOT a function of glycosaminoglycans?
Which is an inhibitor of ferrochelatase ?
Bile acids consist of all of the following except -
Which of the following statements is true regarding the functions of cAMP and cGMP?
Aminolevulinic acid is a metabolic product in the synthesis of -
NEET-PG 2015 - Biochemistry NEET-PG Practice Questions and MCQs
Question 51: What is the most important tool used in genetic engineering?
- A. Topoisomerase
- B. DNA Ligase
- C. Restriction endonuclease (Correct Answer)
- D. Helicase
Explanation: ***Restriction endonuclease*** - **Restriction endonucleases** are crucial for genetic engineering as they specifically cut DNA at particular recognition sites, allowing the insertion or deletion of genes. - This precise cutting ability is fundamental for creating **recombinant DNA** molecules. *Helicase* - **Helicase** is primarily involved in unwinding the DNA double helix during processes like DNA replication and transcription. - While essential for cellular functions, it does not directly manipulate DNA for gene insertion or modification in the way restriction enzymes do. *Topoisomerase* - **Topoisomerase** enzymes are responsible for managing DNA supercoiling, preventing tangling during DNA replication and transcription by cutting and rejoining DNA strands. - It plays a role in DNA structure but is not directly used for targeted gene editing or insertion. *DNA Ligase* - **DNA ligase** is essential for joining DNA fragments, which is a critical step in genetic engineering after restriction endonucleases have cut the DNA. - However, while it acts as a "molecular glue" to seal nicks and re-form phosphodiester bonds, it cannot initiate the precise cutting required to isolate genes.
Question 52: If the content of adenine (A) is 15%, what is the percentage of guanine (G) in the DNA?
- A. 15%
- B. 85%
- C. 70%
- D. 35% (Correct Answer)
Explanation: ***35%*** - According to **Chargaff's rules**, in a DNA molecule, the amount of **adenine (A) is equal to the amount of thymine (T)**, and the amount of **guanine (G) is equal to the amount of cytosine (C)**. - If A = 15%, then T must also be 15%. This means A + T = 30%. Since the total percentage of all bases is 100%, G + C must be 100% - 30% = 70%. As G = C, then G = 70% / 2 = 35%. *15%* - This would only be correct if guanine paired with adenine, which it does not; guanine pairs with **cytosine**. - This answer incorrectly assumes that all four bases are present in equal proportions, or that G equals A, which violates **Chargaff's rules**. *85%* - This percentage would imply an incorrect base pairing or an imbalanced ratio of purines and pyrimidines, violating the fundamental structure of DNA. - An 85% guanine content would mean that G + C far exceeds 100% or that T is extremely low, which is biologically impossible. *70%* - This represents the combined percentage of **guanine and cytosine**, not guanine alone. - While it correctly acknowledges the remaining proportion of bases, it fails to divide this sum between the two equal components, **G and C**.
Question 53: The gaps between Okazaki fragments on the lagging strand during DNA replication are rejoined and sealed by:
- A. DNA Ligase (Correct Answer)
- B. DNA Helicase
- C. DNA Phosphorylase
- D. DNA Topoisomerase
Explanation: ***DNA Ligase*** - **DNA ligase** forms a **phosphodiester bond** between the **3'-OH group** of one Okazaki fragment and the **5'-phosphate group** of the adjacent fragment, effectively sealing the nicks. - After **DNA polymerase I** removes the **RNA primers** and fills in the gaps, DNA ligase completes the synthesis of the **lagging strand** during DNA replication. - This enzyme is essential for maintaining the **integrity of the DNA backbone**. *DNA Helicase* - **DNA helicase** functions to **unwind the DNA double helix**, separating the two strands to create a replication fork. - It does not participate in joining DNA fragments. *DNA Phosphorylase* - **DNA phosphorylase** is not a standard enzyme involved in the direct sealing of DNA fragments during replication. - This is not the enzyme responsible for ligating Okazaki fragments. *DNA Topoisomerase* - **DNA topoisomerase** relieves the **supercoiling tension** that builds up in the DNA double helix ahead of the replication fork due to unwinding. - It does not have a role in forming phosphodiester bonds between newly synthesized DNA fragments.
Question 54: By which enzyme is cDNA synthesized from RNA?
- A. Helicase
- B. DNA-dependent DNA polymerase
- C. Topoisomerase
- D. Reverse transcriptase (Correct Answer)
Explanation: ***Reverse transcriptase*** - **Reverse transcriptase** is a unique enzyme that synthesizes a **complementary DNA (cDNA)** strand from an **RNA template**. - This process, known as **reverse transcription**, is crucial in retroviruses and molecular biology techniques like RT-PCR. *Helicase* - **Helicase** enzymes are responsible for **unwinding nucleic acid double helices**, separating DNA strands during replication and transcription. - It does not synthesize DNA from an RNA template. *DNA-dependent DNA polymerase* - **DNA-dependent DNA polymerase** synthesizes new **DNA strands using an existing DNA template** during DNA replication. - It cannot use RNA as a template to synthesize DNA. *Topoisomerase* - **Topoisomerase** enzymes are involved in **managing DNA supercoiling** by creating transient breaks in the DNA backbone. - They do not synthesize DNA from any template.
Question 55: Which of the following is not classified as a chaperone protein?
- A. Calnexin
- B. Protein disulfide isomerase
- C. Calreticulin
- D. Calbindin (Correct Answer)
Explanation: ***Calbindin*** - **Calbindin** is a **calcium-binding protein** that helps regulate intracellular calcium levels, particularly in the brain and intestines. - It does not assist in **protein folding** or assembly like chaperone proteins. *Calnexin* - **Calnexin** is a **chaperone protein** located in the endoplasmic reticulum (ER). - It assists in the proper folding and quality control of newly synthesized **glycoproteins**. *Protein disulfide isomerase* - **Protein disulfide isomerase (PDI)** is an ER enzyme that **catalyzes the formation and rearrangement of disulfide bonds** in newly synthesized proteins, which is crucial for proper folding. - Due to its role in enabling correct protein folding, it is considered a **chaperone-like protein**. *Calreticulin* - **Calreticulin** is another **calcium-binding chaperone protein** found in the endoplasmic reticulum. - It works synergistically with calnexin to ensure the **proper folding of glycoproteins**.
Question 56: Which of the following is NOT a function of glycosaminoglycans?
- A. Lubrication of joints
- B. Wound healing process
- C. Anticoagulant activity
- D. Transport of lipids in the bloodstream (Correct Answer)
Explanation: ***Transport of lipids in the bloodstream*** - Glycosaminoglycans (GAGs) generally do not play a direct role in the **transport of lipids** in the bloodstream. Lipid transport is primarily mediated by **lipoproteins** (e.g., chylomicrons, VLDL, LDL, HDL). - While some GAGs might interact with lipoproteins in the extracellular matrix, their fundamental role is not lipid transport but rather structural and signaling functions. *Lubrication of joints* - This is a well-established function of GAGs, particularly **hyaluronic acid**, which contributes to the **viscoelastic properties of synovial fluid**, reducing friction in joints. - Hyaluronic acid helps maintain the **hydration** and **shock-absorbing capacity** of articular cartilage. *Wound healing process* - Glycosaminoglycans, especially **hyaluronic acid** and **heparin sulfate**, are crucial in **wound healing** processes, where they modulate inflammation, cell migration, and tissue remodeling. - They provide a **scaffold for cell proliferation** and differentiation in the wound bed. *Anticoagulant activity* - **Heparin**, a highly sulfated glycosaminoglycan, is a potent **anticoagulant** that works by activating **antithrombin III**, thereby inhibiting various coagulation factors like thrombin. - Other GAGs, like **heparan sulfate** found on cell surfaces, also exhibit mild anticoagulant properties.
Question 57: Which is an inhibitor of ferrochelatase ?
- A. Lead (Correct Answer)
- B. Mercury
- C. Iron
- D. Arsenic
Explanation: ***Lead*** - **Lead** is a potent environmental toxin that directly inhibits the enzyme **ferrochelatase**, preventing the insertion of **iron** into **protoporphyrin IX** to form heme. - This inhibition leads to the accumulation of **protoporphyrin IX** and can cause **anemia** due to impaired **heme synthesis**. *Mercury* - While **mercury** is a heavy metal and neurotoxin, its primary mechanism of toxicity does not involve direct inhibition of **ferrochelatase**. - Its effects are more commonly associated with protein denaturation and enzyme inactivation through binding with **sulfhydryl groups**. *Iron* - **Iron** is a substrate for **ferrochelatase**, not an inhibitor. **Ferrochelatase** catalyzes the insertion of **iron** into **protoporphyrin IX** to complete the synthesis of **heme**. - Deficiencies or excesses of **iron** can affect **heme synthesis**, but **iron** itself does not inhibit the enzyme in a toxic manner. *Arsenic* - **Arsenic** is a metalloid that is toxic through various mechanisms, including interference with cellular respiration and DNA repair. - However, **arsenic** is not known to be a direct inhibitor of **ferrochelatase** in the same way **lead** is.
Question 58: Bile acids consist of all of the following except -
- A. Lithocholic acid
- B. Deoxycholic acid
- C. Bilirubin (Correct Answer)
- D. Chenodeoxycholic acid
Explanation: ***Bilirubin*** - **Bilirubin** is a pigment formed from the breakdown of **heme**, not a bile acid. - It is excreted in bile but does not aid in **lipid digestion** or **absorption**. *Lithocholic acid* - **Lithocholic acid** is a **secondary bile acid** formed in the colon by bacterial dehydroxylation of chenodeoxycholic acid. - It is still considered a bile acid, despite its secondary nature. *Deoxycholic acid* - **Deoxycholic acid** is a **secondary bile acid** formed by bacterial action on cholic acid in the colon. - Like other bile acids, it plays a role in **fat digestion** and **absorption**. *Chenodeoxycholic acid* - **Chenodeoxycholic acid** is a **primary bile acid** synthesized in the liver from cholesterol. - It is one of the main bile acids directly involved in **emulsifying dietary fats**.
Question 59: Which of the following statements is true regarding the functions of cAMP and cGMP?
- A. All of the above statements are true
- B. They act on membrane receptors.
- C. They are both second messengers. (Correct Answer)
- D. They act by post-translational modification.
Explanation: ***They are both second messengers.*** - **cAMP (cyclic adenosine monophosphate)** and **cGMP (cyclic guanosine monophosphate)** are crucial intracellular signaling molecules. - They relay signals from **first messengers** (like hormones or neurotransmitters) received at the cell surface to intracellular targets, thus acting as second messengers. *They act on membrane receptors.* - **cAMP** and **cGMP** are *produced* in response to activation of **membrane receptors** by first messengers, but they themselves do not act directly on these receptors. - Their action is primarily *intracellular*, binding to and activating various enzymes and proteins like **protein kinases**. *All of the above statements are true* - This statement is incorrect because the claim that they act on membrane receptors is false. - Only one of the statements provided is accurate regarding the functions of cAMP and cGMP. *They act by post-translational modification.* - While cAMP and cGMP can lead to **post-translational modification** (e.g., phosphorylation by protein kinases A and G), they are not themselves the direct modifiers. - They act as **allosteric regulators** of enzymes, which then catalyze the modifications.
Question 60: Aminolevulinic acid is a metabolic product in the synthesis of -
- A. Tryptophan
- B. Collagen
- C. Glycosaminoglycans
- D. Heme (Correct Answer)
Explanation: ***Heme*** - **Aminolevulinic acid (ALA)** is the first committed precursor in the **heme biosynthesis pathway**. - Its formation from succinyl CoA and glycine is catalyzed by **ALA synthase**, which is the rate-limiting enzyme. *Tryptophan* - **Tryptophan** is an essential amino acid and a precursor for molecules like **serotonin**, **melatonin**, and **niacin**. - Its synthesis does not involve aminolevulinic acid. *Collagen* - **Collagen** is a structural protein primarily composed of amino acids such as **glycine, proline, and hydroxyproline**. - Its synthesis pathway is distinct and does not utilize aminolevulinic acid. *Glycosaminoglycans* - **Glycosaminoglycans (GAGs)** are long, unbranched polysaccharides consisting of repeating disaccharide units, significant components of the **extracellular matrix**. - Their synthesis involves various sugars and enzymes, but not aminolevulinic acid.