Development of a time-resolved fluorescence resonance energy transfer ultra-high throughput screening assay targeting SYK and FCER1G interaction

IF 2.7 4区生物学 Q2 BIOCHEMICAL RESEARCH METHODS

SLAS Discovery Pub Date : 2024-08-21 DOI:10.1016/j.slasd.2024.100177

Yuhong Du , Dongxue Wang , Vittorio L. Katis , Elizabeth L. Zoeller , Min Qui , Allan I. Levey , Opher Gileadi , Haian Fu , the Emory-SAGE-SGC TREAT-AD Center

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引用次数: 0

Abstract

The spleen tyrosine kinase (SYK) and high affinity immunoglobulin epsilon receptor subunit gamma (FCER1G) interaction has a major role in the normal innate and adaptive immune responses, but dysregulation of this interaction is implicated in several human diseases, including autoimmune disorders, hematological malignancies, and Alzheimer's Disease. Development of small molecule chemical probes could aid in studying this pathway both in normal and aberrant contexts. Herein, we describe the miniaturization of a time-resolved fluorescence resonance energy transfer (TR-FRET) assay to measure the interaction between SYK and FCER1G in a 1536-well ultrahigh throughput screening (uHTS) format. The assay utilizes the His-SH2 domains of SYK, which are indirectly labeled with anti-His-terbium to serve as a TR-FRET donor and a FITC-conjugated phosphorylated ITAM domain peptide of FCER1G to serve as an acceptor. We have optimized the assay into a 384-well HTS format and further miniaturized the assay into a 1536-well uHTS format. Robust assay performance has been achieved with a Z’ factor > 0.8 and signal-to-background (S/B) ratio > 15. The utilization of this uHTS TR-FRET assay for compound screening has been validated by a pilot screening of 2,036 FDA-approved and bioactive compounds library. Several primary hits have been identified from the pilot uHTS. One compound, hematoxylin, was confirmed to disrupt the SYK/FECR1G interaction in an orthogonal protein–protein interaction assay. Thus, our optimized and miniaturized uHTS assay could be applied to future scaling up of a screening campaign to identify small molecule inhibitors targeting the SYK and FCER1G interaction.

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开发针对 SYK 和 FCER1G 相互作用的时间分辨荧光共振能量转移超高通量筛选测定。

脾脏酪氨酸激酶（SYK）和高亲和性免疫球蛋白epsilon受体亚基γ（FCER1G）的相互作用在正常的先天性和适应性免疫反应中起着重要作用，但这种相互作用的失调与多种人类疾病有关，包括自身免疫性疾病、血液恶性肿瘤和阿尔茨海默病。开发小分子化学探针有助于研究正常和异常情况下的这一通路。在此，我们介绍了一种时间分辨荧光共振能量转移（TR-FRET）测定的微型化技术，该测定可在 1536 孔超高通量筛选（uHTS）格式中测量 SYK 与 FCER1G 之间的相互作用。该测定利用 SYK 的 His-SH2 结构域和 FCER1G 的 FITC 结合的磷酸化 ITAM 结构域肽作为 TR-FRET 供体，前者用抗-His-铽元素间接标记。我们已将该测定优化为 384 孔 HTS 格式，并进一步将其微型化为 1536 孔 uHTS 格式。该检测方法性能稳定，Z'因子大于 0.8，信噪比（S/B）大于 15。这种 uHTS TR-FRET 分析法可用于化合物筛选，已通过对 2,036 种 FDA 批准的生物活性化合物库的试验筛选进行了验证。试验性 uHTS 筛选出了几个主要命中化合物。在一项正交蛋白-蛋白相互作用试验中，一种名为血红素的化合物被证实能破坏 SYK/FECR1G 的相互作用。因此，我们优化和微型化的 uHTS 试验可用于未来扩大筛选活动的规模，以鉴定针对 SYK 和 FCER1G 相互作用的小分子抑制剂。

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来源期刊

SLAS Discovery Chemistry-Analytical Chemistry

CiteScore

7.00

自引率

3.20%

发文量

审稿时长

39 days

期刊介绍： Advancing Life Sciences R&D: SLAS Discovery reports how scientists develop and utilize novel technologies and/or approaches to provide and characterize chemical and biological tools to understand and treat human disease. SLAS Discovery is a peer-reviewed journal that publishes scientific reports that enable and improve target validation, evaluate current drug discovery technologies, provide novel research tools, and incorporate research approaches that enhance depth of knowledge and drug discovery success. SLAS Discovery emphasizes scientific and technical advances in target identification/validation (including chemical probes, RNA silencing, gene editing technologies); biomarker discovery; assay development; virtual, medium- or high-throughput screening (biochemical and biological, biophysical, phenotypic, toxicological, ADME); lead generation/optimization; chemical biology; and informatics (data analysis, image analysis, statistics, bio- and chemo-informatics). Review articles on target biology, new paradigms in drug discovery and advances in drug discovery technologies. SLAS Discovery is of particular interest to those involved in analytical chemistry, applied microbiology, automation, biochemistry, bioengineering, biomedical optics, biotechnology, bioinformatics, cell biology, DNA science and technology, genetics, information technology, medicinal chemistry, molecular biology, natural products chemistry, organic chemistry, pharmacology, spectroscopy, and toxicology. SLAS Discovery is a member of the Committee on Publication Ethics (COPE) and was published previously (1996-2016) as the Journal of Biomolecular Screening (JBS).