Application Note

HTRF Human TNFα Assay on SpectraMax Paradigm Multi-Mode Microplate Reader

  • Highly robust homogeneous assay
  • Z’ factor ≥ 0.9
  • Streamlined and stable for HTS
  • Faster time to results with SoftMax Pro Software protocols

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Introduction

In this application note we show how the SpectraMax® Paradigm® Multi-Mode Microplate Reader is used to perform robust, no-wash cytokine assays with excellent Z’ factors.

HTRF® is a versatile technology developed by Cisbio Bioassays for detecting biomolecular interactions1. It combines fluorescence resonance energy transfer (FRET) technology with time-resolved (TR) measurement of fluorescence, allowing elimination of short-lived background fluorescence. The assay uses donor and acceptor fluorophores. When donor and acceptor are close enough to each other, excitation of the donor by an energy source (e.g., a flash lamp) triggers an energy transfer to the acceptor, which in turn emits specific fluorescence at a given wavelength.

HTRF uses four specific fluorophores that can be combined to form compatible donor-acceptor TR-FRET pairs. The donors are europium cryptate (Eu3+) and Terbium (Lumi4™-Tb) cryptate, whose long-lived fluorescence enables their use in time-resolved fluorescence assays1. Two acceptors have been developed for use in HTRF assays, XL665 and d2. Both have excitation spectra that overlap the emission spectrum of the HTRF donors. Each has an emission peak at 665 nm that falls within a region where the donor does not emit, or emits very weakly. The original HTRF acceptor, XL665, is a phycobiliprotein pigment purified from red algae. A second generation acceptor, d2, is a modified allophycocyanin that is 100 times smaller than XL665 and was developed to alleviate steric hindrance problems that may occur with XL665-based assays.

Cytokines like tumor necrosis factor alpha (TNFα) are of particular interest in the fields of oncology, infectious disease, allergies, and autoimmune diseases. Disturbances in cytokine regulation are known to cause inappropriate or ineffective immune responses.

The Human TNFα assay kit enables direct quantitative determination of TNFα. It uses a sandwich immunoassay involving two specific antibodies, one anti-TNFα labeled with Eu-Cryptate and the second anti-TNFα labeled with XL665 or d2. In the presence of TNFα, both antibodies bind TNFα, bringing both labels into close proximity so that TRFRET occurs (Figure 1). Signal is proportional to the concentration of antigen in the sample.

Materials

Methods

Human TNFα standards ranging from 20 to 2000 pg/mL were prepared as indicated in the kit product insert. A positive assay control consisting of free human TNFα, and a negative control without human TNFα (no TR-FRET), were included to confirm assay activity and aid in accurate calculation of results.

Reagents were dispensed in a final volume of 20 μL per well as indicated in Table 1.

Standard curve
Negative control
Assay control
10 µL standard
10 µL diluent
10 µL TNFα control
5 µL XL665 conjugate
5 µL Cryptate conjugate

Table 1. Assay setup for a 384-well low-volume plate.

The plate was covered, incubated for three hours at room temperature, then time resolved fluorescence was measured on the SpectraMax Paradigm reader with HTRF Detection Cartridge (see Table 2 for instrument settings).

Optical Configuration
HTRF Detection Cartridge
Read Mode
TR-FRET
Read Type
Endpoint
Wavelengths

Ex 340 nm Em 616 nm

Em 665 nm

PMT and Optics

Number of Pulses: 30

Excitation Time: 0.05 ms

Measurement Delay: 0.03 ms

Integration Time: 0.2 msData Analysis

Table 2. Optimized instrument settings for SpectraMax Paradigm reader with HTRF Detection Cartridge.

Analysis of HTRF assays uses Cisbio’s patented ratiometric reduction method based on the two emission wavelengths detected. Donor emission at 616 nm is used as an internal reference, while acceptor emission at 665 nm is used as an indicator of the biological reaction being assayed. This ratiometric measurement reduces wellto-well variation and eliminates compound interference. Delta F, calculated in step 4 below, reflects signal to background of the assay and is useful for inter-assay comparisons.

Results are calculated from the 665 nm/616 nm ratio and expressed in Delta F as follows:

Z’ factor values were calculated from the negative control and 2000 pg/mL standard2.

Data were generated and analyzed using SoftMax® Pro Software, which contains several preconfigured HTRF protocols to simplify detection and analysis.

HTRF Human TNFα calibration curve measured on the SpectraMax Paradigm reader. Blue circles: black plate; red circles: white plate. The r2 value for each plot is 1.00.

Results

The SpectraMax Paradigm reader has read height and microplate optimization features, which allow users to easily determine the optimal read height and microplate dimensions, increasing the assay dynamic range and sensitivity. Both optimizations were performed for each Greiner plate. Data were expressed as Delta F % (DF %) and plotted against human TNFα concentrations (Figure 2). Best results were obtained with 30 pulses, delay of 0.03 ms and integration time of 0.2 ms (Table 2).

Similar results were obtained using the low-volume white and black 384-well microplates. DF% values ranged from 21 to 927 with the black plate and from 7 to 810 with the white plate. Although the assay window was larger with the black plate, the Z’ factor for the white plate was 0.95, compared to 0.86 for the black plate, indicating slightly better overall assay performance2.

Conclusion

The SpectraMax Paradigm reader with HTRF Detection Cartridge offers high-throughput screening capability with excellent read times and Z’ factors. Simultaneous dual emission detection enables read times of only 2:17 for an entire 384-well plate. Sensitivity and dynamic range are demonstrated by the high Z’ factors obtained on the SpectraMax Paradigm reader. This assay may also be detected on the SpectraMax® i3 and SpectraMax® M5e Multi-Mode Microplate Readers. Data acquisition and analysis are simplified using SoftMax Pro Software with preconfigured HTRF protocols.

References

  1. https://www.htrf.com/htrf-technology
  2. Zhang, J. H., Chung, T. D. Y., and Oldenburg, K. R. (1999). A simple statistical parameter for use in evaluation and validation of high throughput screening assays. J. Biomolecular Screening 4(2): 67-73.

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