Zenon® Mouse IgG Labeling

Zenon® labeling technologyprovides a rapid, versatile and reliable method for producing fluorescently-labeled antibody using a variety of fluorochromes, even with small amounts of unpurified starting material such as hybridoma culture supernatant.

Antibodies labeled using Zenon® technology are suitable for use in all applications where a directly labeled antibody can be used.

Each of the Zenon® mouse IgG labeling kits is designed for use with a particular mouse monoclonal antibody isotype: IgG1, IgG2a, or IgG2b. Zenon® labeling technology uses a labeled Fab fragment directed against the Fc portion of an intact IgG primary antibody in order to form a labeling complex (Figure 1). Formation of the Fab-antibody complex occurs within 5 minutes, and complexes formed using this technology display fluorescence intensity similar to or brighter than that of directly labeled primary antibodies. Multiple Zenon® antibody complexes may be prepared individually and used in a multicolor stain after using the Zenon® blocking reagent.

The following protocols were developed for the staining of peripheral blood mononuclear cells and can be readily adapted to other cell types or whole blood. Note that an Fc blocking step is not required when using antibodies labeled with Zenon® technology by themselves, as the labeling complex hinders Fc receptor access to the antibody.

 
Figure 1. How Zenon® Labeling Technology works. Noncovalent labeling with Zenon® antibody labeling vs. covalent labeling with the Microscale, Monoclonal, and Protein Labeling Kits.

Zenon® labeling reagent
Zenon® blocking reagent
Unlabeled primary mouse antibody
Sample: Cell suspension at ~1 x 10 ⁶ cells/mL or whole blood
Staining buffer: phosphate-buffered saline with 1% BSA (PBS/BSA), or equivalent
 
Sample preparation reagents:

• Cal-Lyse™ lysing solution (Invitrogen) or equivalent erythrocyte lysis reagent
• FIX & PERM® reagents (Invitrogen) or equivalent cell fixation and permeabilization reagents
• 4% formaldehyde in phosphate-buffered saline (PBS) or equivalent cell fixation reagent

Flow cytometry tubes, 12 x 75 mm
Flow cytometer

Staining is Dependent on Molar Ratio

The intensity of staining achieved with Zenon reagent-complexed antibody is dependent on the molar ratio of Fab to antibody. In general, a 3-fold molar excess should be used with abundant targets. For less abundant targets, the molar ratio can be increased by adding more Zenon® labeling reagent with 1 µg antibody. Figure 2 shows the effect of increasing molar ratio on the staining intensity of anti-CD4 on human lymphocytes, and compares this to a direct conjugate of the same clone and fluorochrome. Increasing molar ratio has little effect on background labeling of negative cell populations.



Using Zenon® Labeling Technology  on Non-Purified Antibodies

In cases where the antibody is not a purified protein, as with ascites fluid or hybridoma culture supernatant, Zenon® labeling reagent can still be used to make Fab:Ig complexes, and the ratio will have to be estimated. In this case, the Zenon® labeling reagent will label nonspecific IgGs of the given isotype as well as the specific antibody, but the non-specific IgG complexes should not stain appreciably and should be washed away during the staining procedure.


Brightness of Zenon® Labeling Reagent Fluorescence

Zenon® complexes can be as bright as or brighter than direct conjugates, depending on the molar ratio used, and unfixed samples can retain their fluorescence patterns for several hours. In Figure 3, peripheral blood lymphocytes were labeled with Zenon® reagent-complexed antibodies against CD4 and CD8 using Protocol 3. Unfixed samples were read over 4 hours and showed neither intensity change nor evidence of the Zenon® labeling reagent used for one marker crossing over to label the other marker.


Figure 3.  Stability of two color stains. Peripheral blood mononuclear cells were stained with anti-CD4 + Zenon® R-phycoerythrin (R-PE) mouse IgG ₁ labeling reagent and anti-CD8 + Zenon® Alexa Fluor® 488 mouse IgG ₁ labeling reagent, both used at molar ratio 3. Samples analyzed immediately, at 2 hours and 4 hours: no change in staining pattern was observed.


Versatility of Zenon® Labeling Technology
 
Zenon® labeling technology allows different fluorophore combinations to be explored. Figure 4 shows both combinations of Alexa Fluor® 488 dye- and R-phycoerythrin-labeled CD56 and CD16 stain on lymphocytes.  It is also simple to combine staining of surface and intracellular markers. Figure 5 shows staining of samples with Zenon® labeling reagent complexes of surface CD2 (T and NK cells), surface CD19 (B cells), and ZAP-70, an intracellular marker normally expressed in T and NK cells. ZAP-70 expression in B cell chronic lymphocytic leukemia correlates with disease progression.



Figure 5. Intracellular ZAP-70 staining combined with surface CD2 and CD19 staining of human lymphocytes using Zenon labeling reagents. Samples stained with anti-CD19 + Zenon® R-PE mouse IgG1 labeling reagent (molar ratio 3), anti-CD2 + Zenon® Alexa Fluor® 680-R-PE mouse IgG1 labeling reagent (molar ratio 3) and anti-ZAP-70 + Zenon® Alexa Fluor® 488 mouse IgG1 labeling reagent (molar ratio 3). A lymphocyte gate was used. A) Normal patient sample showing a normal ZAP-70 staining pattern copositive with CD2 lymphocytes B) Normal patient sample showing a normal ZAP-70 staining pattern mutually exclusive with CD19 lymphocytes C & D) Two different patients with B-cell chronic lymphocytic leukemia showing different ZAP-70 expressions in dual parameter testing with CD2, gated on lymphocytes. Data collected in collaboration with M. Suter, Oregon Medical Laboratories, Eugene, OR.