Polyacrylamide Gel Electrophoresis (PAGE) – Principle, Procedure, Applications, Advantages & Limitations

Introduction to Polyacrylamide Gel Electrophoresis

• Electrophoresis is a standard method used in molecular biology and biochemistry to separate, identify, and analyze biomolecules like proteins and nucleic acids.
• The separation is achieved by forcing molecules to migrate through a porous gel matrix under an electric field.
• Two main gel types are used: agarose gel and polyacrylamide gel.
• Polyacrylamide Gel Electrophoresis (PAGE) provides greater resolution than agarose gels, especially for proteins and small DNA fragments.
• PAGE is widely used in molecular biology, genetics, forensic science, biochemistry, and biotechnology.

In simple terms: PAGE is a laboratory technique used to separate proteins and nucleic acids based on their size and charge by making them move through a polyacrylamide gel under electricity.

What is Polyacrylamide Gel?

• Polyacrylamide gels are chemically cross-linked gels formed by the polymerization of acrylamide with a cross-linking agent such as N,N’-methylenebisacrylamide.
• The polymerization is initiated by ammonium persulfate (APS) and catalyzed by TEMED (N,N,N’,N’-tetramethylethylenediamine).
• The pore size of the gel depends on the ratio of acrylamide to bisacrylamide, making it highly adjustable for separating molecules of different sizes.
• This makes polyacrylamide gels superior to agarose gels when working with small proteins or DNA fragments.

Principle of PAGE

The principle of PAGE is based on two main concepts:

1. Electrophoretic Mobility
   • Charged molecules migrate in an electric field towards the electrode with the opposite charge.
   • The rate of migration depends on charge, size, and shape of the molecule.
2. Denaturation for Size-Based Separation
   • Different proteins naturally have different shapes and charges, which makes comparison difficult.
   • To overcome this, proteins are treated with SDS (Sodium Dodecyl Sulfate), which:
     • Denatures proteins (removes secondary, tertiary, quaternary structures).
     • Covers them with a uniform negative charge.
   • Thus, the separation depends only on size (molecular weight).

In summary: In SDS-PAGE, proteins move through the gel at different speeds based on their molecular size, with smaller proteins migrating faster.

Requirements for PAGE

To perform PAGE, the following materials are required:

• Acrylamide and Bisacrylamide solution (for resolving and stacking gels).
• Gel loading buffer (contains tracking dye and denaturants).
• Running buffer (commonly Tris-Glycine buffer).
• Staining and destaining solutions (Coomassie Brilliant Blue, silver stain, or ethidium bromide for nucleic acids).
• Protein or nucleic acid samples.
• Molecular weight markers (protein ladders) for comparison.
• Electrophoresis equipment:
  • Gel casting stand and glass plates
  • Combs for sample wells
  • Electrophoresis chamber and power supply

Steps in Polyacrylamide Gel Electrophoresis (PAGE)

1. Sample Preparation

• Protein samples are mixed with SDS to denature and impart uniform negative charge.
• A reducing agent (like β-mercaptoethanol or DTT) may be added to break disulfide bonds.
• Samples are heated (~60–100°C) to ensure full denaturation.
• Tracking dye is added to monitor electrophoresis progress.

2. Preparation of Polyacrylamide Gel

• Gel consists of acrylamide + bisacrylamide, APS, TEMED, and buffer.
• Two layers are prepared:
  • Resolving gel: Higher % acrylamide (5–25%) for separating proteins.
  • Stacking gel: Lower % acrylamide to concentrate samples before separation.
• Gel is cast between two glass plates and wells are created with combs.

3. Loading Samples and Running the Gel

• After polymerization, wells are filled with samples and a molecular weight marker.
• The gel is placed in the electrophoresis chamber filled with buffer.
• Electric current is applied: negatively charged molecules migrate towards the anode.
• Smaller proteins migrate faster through the pores, larger ones slower.

4. Detection/Visualization

• After electrophoresis, gels are stained to visualize separated molecules.
• Common stains:
  • Coomassie Brilliant Blue (routine protein staining).
  • Silver stain (high sensitivity).
  • Ethidium bromide or SYBR Green (for nucleic acids).
• After staining, bands appear at different positions corresponding to proteins/DNA of different sizes.

Applications of PAGE

1. Protein Analysis
   • Estimation of molecular weight.
   • Determination of protein purity.
   • Study of protein subunits and quaternary structures.
   • Peptide mapping.
2. Nucleic Acid Studies
   • Analysis of small DNA or RNA fragments.
   • Detection of mutations or polymorphisms.
3. Medical and Clinical Uses
   • Diagnosing protein abnormalities.
   • Analyzing hemoglobin variants.
   • Studying enzyme deficiencies.
4. Research and Biotechnology
   • Used before Western blotting.
   • Quality control in recombinant protein production.
   • Comparing protein composition between samples.
5. Forensic Applications
   • Identification of proteins/DNA in criminal investigations.

Advantages of PAGE

• High resolving power – sharp, distinct bands.
• Adjustable pore size by changing acrylamide concentration.
• Can separate proteins of similar size effectively.
• Produces highly pure DNA or protein fragments.
• Works well for low molecular weight proteins.

Disadvantages of PAGE

• Preparation is more complex than agarose gels.
• Acrylamide is toxic, requiring careful handling.
• Gels are less reusable – a new gel must be prepared for each run.
• More time-consuming and prone to technical errors.

Types of PAGE

1. SDS-PAGE (Denaturing PAGE)
   • Most common type.
   • Proteins denatured with SDS → separation based only on size.
2. Native PAGE (Non-denaturing PAGE)
   • Proteins retain native structure and activity.
   • Separation depends on charge, shape, and size.
3. 2D-PAGE (Two-dimensional PAGE)
   • Combines isoelectric focusing (IEF) and SDS-PAGE.
   • Used for complex proteomic studies.

Conclusion

• Polyacrylamide Gel Electrophoresis (PAGE) is one of the most important molecular biology techniques for analyzing proteins and nucleic acids.
• With variations like SDS-PAGE, Native PAGE, and 2D-PAGE, it plays a crucial role in diagnostics, proteomics, clinical studies, and biotechnology research.
• Despite being labor-intensive and involving toxic chemicals, its accuracy and resolution make PAGE a gold standard in protein analysis.

Frequently Asked Questions (FAQs) on Polyacrylamide Gel Electrophoresis (PAGE)

Q1. What is Polyacrylamide Gel Electrophoresis (PAGE)?
Ans: PAGE is a laboratory technique used to separate proteins and nucleic acids by moving them through a polyacrylamide gel under an electric field.

Q2. Why is polyacrylamide used instead of agarose?
Ans: Polyacrylamide has smaller, adjustable pores, giving higher resolution for separating proteins and small DNA fragments compared to agarose.

Q3. Who introduced PAGE?
Ans: The technique was developed in the 1950s and 1960s by scientists studying protein separation, later refined into SDS-PAGE by Ulrich K. Laemmli in 1970.

Q4. What is the principle of PAGE?
Ans: Molecules migrate in an electric field at different speeds depending on charge, size, and shape. In SDS-PAGE, separation is based mainly on molecular weight.

Q5. What are the types of PAGE?
Ans:

• SDS-PAGE (denaturing) → size-based separation.
• Native PAGE → separation based on charge, size, and shape (proteins remain active).
• 2D-PAGE → combines isoelectric focusing (pH separation) with SDS-PAGE.

Q6. What is SDS-PAGE?
Ans: SDS-PAGE uses sodium dodecyl sulfate (SDS) to denature proteins and give them a uniform negative charge, so migration depends only on size.

Q7. What is Native PAGE?
Ans: In Native PAGE, proteins are not denatured. They retain their structure and activity, and separation depends on charge + size + shape.

Q8. What is the role of the stacking gel in PAGE?
Ans: The stacking gel has low acrylamide concentration and helps concentrate all proteins into sharp bands before entering the resolving gel.

Q9. What is the function of TEMED in PAGE?
Ans: TEMED (Tetramethylethylenediamine) catalyzes the polymerization of acrylamide into polyacrylamide gel.

Q10. Why is acrylamide considered hazardous?
Ans: Acrylamide monomers are toxic and neurotoxic; they must be handled with gloves and safety precautions.

Q11. What stains are used to visualize proteins in PAGE?
Ans: Common stains:

• Coomassie Brilliant Blue (routine staining)
• Silver stain (high sensitivity)
• SYBR Green / Ethidium Bromide (for nucleic acids)

Q12. Can PAGE be used for DNA and RNA?
Ans: Yes. PAGE can separate small DNA and RNA fragments, but agarose gels are preferred for large DNA fragments.

Q13. What is the difference between PAGE and agarose gel electrophoresis?
Ans: PAGE → high resolution, best for proteins & small DNA.
Agarose gel → best for large DNA fragments (hundreds of bp to kb).

Q14. What is the role of SDS in PAGE?
Ans: SDS denatures proteins and binds uniformly, giving all proteins a negative charge proportional to their length, making separation purely size-based.

Q15. What is 2D-PAGE?
Ans: Two-dimensional PAGE first separates proteins by isoelectric focusing (based on charge) and then by SDS-PAGE (based on size). Used in proteomics.

Q16. How is PAGE used in medicine?
Ans: PAGE is used to detect abnormal blood proteins, hemoglobin variants, and enzyme deficiencies, aiding in disease diagnosis.

Q17. How is PAGE used in biotechnology?
Ans: PAGE helps in protein purification, Western blotting, recombinant protein analysis, and quality control.

Q18. What are the advantages of PAGE?
Ans:

• High resolution.
• Adjustable pore size.
• Sharp bands for accurate analysis.
• Useful for low molecular weight proteins.

Q19. What are the disadvantages of PAGE?
Ans:

• Complex preparation compared to agarose.
• Acrylamide is toxic.
• Gel is single-use.
• Time-consuming.

Q20. Why is PAGE important in research?
Ans: PAGE is a fundamental technique in molecular biology for analyzing proteins, nucleic acids, and is essential for proteomics, clinical studies, and biotechnology.

Q21. What is a protein ladder in PAGE?
Ans: A protein ladder (molecular weight marker) is a mixture of proteins of known sizes used to estimate the size of unknown proteins in a sample.

Q22. Can PAGE be quantitative?
Ans: Mostly qualitative/semi-quantitative. However, with densitometry analysis, PAGE results can provide quantitative information.

Q23. What is the difference between SDS-PAGE and Western blotting?
Ans: SDS-PAGE separates proteins by size.
Western blotting transfers separated proteins to a membrane and uses antibodies for specific protein detection.

References

1. http://elte.prompt.hu/sites/default/files/tananyagok/IntroductionToPracticalBiochemistry/ch07s03.html
2. https://www.wou.edu/las/physci/ch462/Gel%20Electrophoresis.pdf
3. https://microbenotes.com/polyacrylamide-gel-electrophoresis-page/
4. https://www.slideshare.net/mbn1994/introduction-principle-instrumentation-and-applications-of-sdspage-55728195
5. https://en.wikipedia.org/wiki/Polyacrylamide_gel_electrophoresis
6. https://msu.edu/course/css/451/Lecture/PT-electrophoresis%20(2009).pdf
7. http://library.umac.mo/ebooks/b28050459.pdf