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The basics of immunohistochemistry

The basics of immunohistochemistry. principle. Antigen-antibody interactions. Antibodies produced. Antibodies binds antigen. Antigen. HOW IT IS EMPLOYED?. Antigen = Protein of our interest Antibody= we generate . Techniques based on this principle. ELISA FACS WESTERN BLOTTING

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The basics of immunohistochemistry

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  1. The basics of immunohistochemistry

  2. principle • Antigen-antibody interactions Antibodies produced Antibodies binds antigen Antigen

  3. HOW IT IS EMPLOYED? • Antigen = Protein of our interest • Antibody= we generate

  4. Techniques based on this principle • ELISA • FACS • WESTERN BLOTTING • IMMUNOHISTOCHEMISTY

  5. Immunohistochemistry – what’s good about it? • Antibodies bind to antigen in specific manner • Can be used to locate particular cells and proteins • Can be used to identify cellular events – e.g.apoptosis

  6. Introduction • Immunohistochemistry is the localization of antigens (proteins) in tissue sections • by the use of labeled antibodies as specific reagents • through antigen-antibody interactions • visualized by a marker such as fluorescent dye, enzyme. • IHC takes its name from the roots • "immuno," in reference to antibodies used in the procedure, • and "histo," meaning tissue (compare toimmunocytochemistry).

  7. TYPES OF VISUALISATION • Visualising an antibody-antigen interaction can be accomplished in a number of ways. • Chromogenic • an antibody is conjugated to an enzyme, such as peroxidase, that can catalyse a colour-producing reaction  • fluorescent • Alternatively, the antibody can also be tagged to a fluorophore, such as fluorescein or rhodamine

  8. What cellular antigens can we target? • Cytoplasmic • Nuclear • Cell membrane

  9. aPPLICATIONS • disease diagnosis • drug development • and biological research

  10. Types of IHC • Direct • Indirect

  11. Direct method- primary antibody only • one step staining method • involves a labeled antibody reacting directly with the antigen in tissue sections. • This technique utilizes only one antibody and the procedure is short and quick. • However, it is insensitive due to little signal amplification and rarely used since the introduction of indirect method. Goat anti-actin labeled with 594

  12. Indirect method – primary and secondary antibodies • involves an unlabeled primary antibody (first layer) which react with tissue antigen, • and a labeled secondary antibody (second layer) react with primary antibody  • This method is more sensitive due to signal amplification  • economic Donkey anti-goat labeled with 488 Goat anti-actin

  13. IHC protocol

  14. Sample preparation (FFPE) formalin fixed paraffin embedded • Tissue fixation • To ensure the preservation of tissue architecture and cell morphology, prompt and adequate fixation is essential • the most common fixative is formaldehyde (FF) • Embedding • in paraffin • to maintain the natural shape and • architecture of the sample during long-term storage and sectioning for IHC (PE) • Sectioning • Into slices as thin as 4-5 μm • with a microtome • Mounting • onto glass slides that are coated with an adhesive •  3-aminopropyltriethoxysilane (APTS) or poly-L-lysine • gelatin, egg albumin or Elmer's glue. 

  15. Antigen retrieval • What? • Retrieve your antigen for detection by IHC • Why? • Formaldehyde fixation generates methylene bridges • that crosslink proteins in tissue samples; • these bridges can mask antigen presentation and prevent antibody binding. • How? • to unmask the antibody epitopes, • either by heat (heat-induced epitope retrieval; HIER) • or enzymatic degradation (proteolytic-induced epitope retrieval; PIER).

  16. Blocking Endogenous target activtiy • What? • Quenching or masking endogenous forms of enzymatic proteins (biotin, peroxidases or phosphatases) • Why? • When using Enzymatic detection • To prevent false positive and high background detection. • How? • Hydrogen peroxide – peroxidases • levamisole - Alkaline phosphatase • Avidin - biotin

  17. Blocking non-specific sites • What? • Masking sites that are similar to target sites • Why? • antibodies may partially or weakly bind to sites on nonspecific proteins that are similar to target • nonspecific binding causes high background staining that can mask the detection of the target antigen.  • How? • Commonly blocking buffers are used • normal serum, non-fat dry milk, BSA or gelatin

  18. Non-specific staining Before block After block

  19. controls • Postive control • to test a protocol or procedure and make sure it works. • It will be ideal to use the tissue that has the expression of your antigen • If the positive control tissue showed negative staining, the protocol or procedure needs to be checked until a good positive staining is obtained. • Negative control • To test for the specificity of an antibody involved • Exclude the primary antibody – no color should be obtained

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