19. Which one of the following techniques is suitable for the large-scale purification of isozymes (A and B) that differ from each other by a single positively charged amino acid?
A. Chromatofocusing
B. Gel filtration chromatography
C. Native PAGE
D. Analytical isoelectric focusing
Chromatofocusing is the ideal technique for large-scale purification of isozymes differing by a single charged amino acid.
This MCQ tests charge-based separation methods suitable for preparative scale.
Correct Answer
A. Chromatofocusing [ from prior context]
Option Analysis
Isozymes A and B differ by one positively charged amino acid (e.g., Lys vs. neutral), creating a small pI difference (~0.1-0.5 units). Large-scale purification requires charge exploitation at preparative volumes.
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A. Chromatofocusing: Correct. This ion-exchange chromatography variant creates a predefined pH gradient (pH 9→4) on anion/cation exchangers. Isozymes focus (stop migrating) at their exact pI positions and elute sharply. Perfect for small pI differences; scalable to hundreds of mL bed volumes for industrial purification. [prior -27 context]
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B. Gel filtration chromatography: Incorrect. Separates by size/shape only—charge differences are irrelevant. Both isozymes (similar MW) co-elute together. Not suitable for charge-based separation. [prior ,5]
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C. Native PAGE: Incorrect. Polyacrylamide gel electrophoresis separates by charge/mass but is analytical (small gel volumes, μg scale). Cannot handle large-scale (grams/liters) purification required here.
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D. Analytical isoelectric focusing: Incorrect. IEF separates at pI positions in pH gradients but is analytical/preparative small-scale (rotor/tube gels). Not designed for industrial large-scale purification.
Large-scale purification isozymes single positively charged amino acid is critical for enzyme production in biotech/pharma. A single Lys/Arg difference creates exploitable pI variation for chromatofocusing.
Chromatofocusing Principle
Anion/cation exchanger equilibrated at high pH (9.0). Polybuffer (ampholyte mimic) creates internal pH gradient (9→4) during elution. Proteins bind → migrate → focus at pI → elute as narrow peaks (ΔpI = 0.05 resolvable).
Scalable: 100 mL → 10 L columns routine. Recovery: >90%. Resolution: Better than standard ion-exchange for close pI. [biochem principle]
Why Other Techniques Fail Large Scale
| Technique | Scale | Basis | Single Charge Resolution | Industrial Use |
|---|---|---|---|---|
| Chromatofocusing | Large (L) | pI gradient | Excellent (ΔpI 0.05) | ✅ Pharma |
| Gel Filtration | Large | Size | None | ❌ Size only |
| Native PAGE | Analytical (μg) | Charge/mass | Good | ❌ Not scalable |
| Analytical IEF | Analytical/prep (mg) | pI | Excellent | ❌ Limited volume |
Real-World Application
LDH isozymes (heart M4 vs. muscle H4) differ by charged residues → chromatofocusing baseline resolves. Industrial: Alkaline phosphatase isozymes for diagnostics.
GATE Exam Strategy
Pattern: “Large-scale” eliminates PAGE/IEF. “Single charged AA” eliminates size methods. Answer: Charge gradient chromatography (chromatofocusing > ion-exchange).
This PYQ tests scale + separation principle integration—key for bioprocess engineering questions.
2 Comments
Vanshika Sharma
January 29, 2026Chromatofocusing
Kanica Sunwalka
June 25, 2026chromatofocusing