Novel customizable immunoassay may revolutionize diagnostics and on-site assessments!

A novel customizable OpenGUS immunoassay that detects analytes quickly and effectively has been developed by scientists from Science Tokyo. With specially designed β-glucuronidase (GUS) probes and optimized reaction conditions, this platform provides a hassle-free yet extremely sensitive approach for detecting relevant biomarkers, allergens, or other biomolecules. This makes homogenous immunoassays more widely available for point-of-care diagnostics, high-throughput testing, environmental monitoring, and food safety analysis, even when sophisticated laboratories are unavailable.

Immunoassays have become an essential tool in analytical chemistry over the past few decades. This biochemical technique leverages the natural ability of antibodies to bind to specific targets, enabling the detection and quantification of desired analytes. Though immunoassays are directly responsible for many scientific discoveries in biology and medicine and have long-standing advantages in clinical diagnosis, they have their disadvantages.

Heterogeneous immunoassays require the physical separation of components bound to the antibodies from those that remain unbound. Such methods are robust and reliable, but they involve intricate and lengthy procedures to get results, which requires highly skilled laboratory personnel. On the other hand, homogenous immunoassays do not require separation, since bound antibodies are designed to emit a detectable signal via luminescence or fluorescence. While quicker and more convenient than heterogeneous immunoassays, these techniques involve complex antibody genetic engineering or modification procedures and are also more susceptible to background noise.

To fill this gap, researchers from Institute of Science Tokyo (Science Tokyo), Japan, developed a new type of customizable homogeneous immunoassay. The research team led by Associate Professor Tetsuya Kitaguchi proposed an approach that offers a convenient, versatile, and highly effective strategy to detect various target analytes. The findings of this study were made available online on 18 September 2024 and published on 1 January 2025 in the journal Biosensors and Bioelectronics.

The main elements of this new immunoassay platform are the OpenGUS probes. These probes are artificial proteins made of two Z-domains and a spacer, designed to pinch and strongly bind to one end of the antibodies, and a β-glucuronidase (GUS) monomer. The antibodies get docked in between the Z-domains and, when they bind to their target antigens, the GUS monomers in the probes are brought closer together. This causes the formation of GUS tetramer, an active enzyme capable of cleaving glucuronide substrates, which is the underlying principle for detection. When specially designed glucuronide molecules are cleaved, the resulting products emit a detectable fluorescent signal or cause the color of the solution to visibly change.

A simple combination of antibodies, OpenGUS probes, and specific substrates can detect nanomolar or even picomolar concentrations of analytes. The researchers achieved this feat by introducing strategic mutations in the GUS monomers to reduce the spontaneous activation, as well as by optimizing the composition of the reaction buffer used. “Thanks to our optimization procedure, the immunoassay results can be confirmed using a smartphone or the naked eye in situations where a fluorometer is unavailable, such as outdoors, at home, or in less-equipped laboratories,” remarks Kitaguchi.

The researchers validated their method by detecting three representative analytes: a Japanese cedar pollen allergen, a human protein biomarker for cardiovascular disease, and human lactoferrin, a biomarker for inflammation. Unlike other immunoassay techniques, long pre-incubation periods at low temperatures and complex genetic modification of antibodies was not required. These advantages suggest that the proposed strategy could become the mainstay for both research and practical settings. “We believe that our customizable OpenGUS immunoassay will pave the way for the prompt development of rapid and sensitive homogenous immunoassay platforms for point-of-care diagnostics, high-throughput testing, and onsite environmental assessments,” concludes Kitaguchi, highlighting the impact of their study.

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Institute of Science Tokyo (Science Tokyo) will be established on October 1, 2024, following the merger between Tokyo Medical and Dental University (TMDU) and Tokyo Institute of Technology (Tokyo Tech), with the mission of “Advancing science and human wellbeing to create value for and with society.”

https://www.isct.ac.jp/en