Cellular Biochemistry Lab., Graduate School of Pharmaceutical Sciences, Nagoya University, Tokai National Higher Education and Research System, Furo-cho, Chikusa, Nagoya, 464-8601, Japan.
Amino Acids. 2023 Jun;55(6):807-819. doi: 10.1007/s00726-023-03272-7. Epub 2023 May 10.
Transglutaminases (TGs) are a protein family that catalyzes isopeptide bond formation between glutamine and lysine residues of various proteins. There are eight TG isozymes in humans, and each is involved in diverse biological phenomena due to their characteristic distribution. Abnormal activity of TG1 and TG2, which are major TG isozymes, is believed to cause various diseases, such as ichthyosis and celiac disease. To elucidate TGs' mechanisms of action and develop new therapeutic strategies, it is essential to develop bioprobes that can specifically examine the activity of each TG isozyme, which has not been sufficiently studied. We previously have identified several substrate peptide sequences containing Gln residues for each isozyme and developed a method to detect isozyme-specific activities by incorporating a labeled substrate peptide into lysine residues of proteins. We prepared the fluorescein isothiocyanate (FITC)-labeled Gln substrate peptide (FITC-K5 and FITC-T26) and Rhodamine B-labeled Lys substrate peptide (RhoB-Kpep). Each TG reaction specifically cross-linked these probe pairs, and the proximity of FITC and Rhodamine B significantly decreased the fluorescence intensity of FITC depending on the concentration and reaction time of each TG. In this study, we developed a peptide-based biosensor that quickly and easily measures TG isozyme-specific activity. This probe is expected to be helpful in elucidating TG's physiological and pathological functions and in developing compounds that modulate TG activity.
转谷氨酰胺酶(TGs)是一类催化各种蛋白质中谷氨酰胺和赖氨酸残基之间异肽键形成的蛋白质家族。人类有 8 种 TG 同工酶,由于其特征分布,每种同工酶都参与不同的生物学现象。异常的 TG1 和 TG2 活性,这两种主要的 TG 同工酶,被认为会导致各种疾病,如鱼鳞癣和乳糜泻。为了阐明 TGs 的作用机制并开发新的治疗策略,开发能够特异性检查每种 TG 同工酶活性的生物探针是至关重要的,但目前对此研究还不够充分。我们之前已经确定了每种同工酶的几个含有谷氨酰胺残基的底物肽序列,并开发了一种方法,通过将标记的底物肽掺入蛋白质的赖氨酸残基中,来检测同工酶特异性活性。我们制备了异硫氰酸荧光素(FITC)标记的 Gln 底物肽(FITC-K5 和 FITC-T26)和罗丹明 B 标记的 Lys 底物肽(RhoB-Kpep)。每种 TG 反应特异性地交联这些探针对,并且 FITC 和罗丹明 B 的接近程度根据每种 TG 的浓度和反应时间显著降低了 FITC 的荧光强度。在这项研究中,我们开发了一种基于肽的生物传感器,可快速、轻松地测量 TG 同工酶特异性活性。该探针有望有助于阐明 TG 的生理和病理功能,并开发调节 TG 活性的化合物。
