Joy Shaon, Mi Tianxiong, Lyu Rui-Liang, Pewklang Thitima, Thompson Tye, Sefiani Arthur, Kamkaew Anyanee, Burgess Kevin
Department of Chemistry, Texas A&M University, Box 30012, College Station, Texas 77842-3012, United States.
Department of Neuroscience and Experimental Therapeutics, Health Science Center, Texas A&M University, Bryan, Texas 77807, United States.
ACS Chem Neurosci. 2025 Aug 6;16(15):2776-2784. doi: 10.1021/acschemneuro.4c00833. Epub 2025 Jul 9.
Neurotrophins (NTs, including NGF, BDNF, NT-4, and NT-3) are extracellular cytokines which modulate the survival and growth of cells expressing tropomyosin receptor kinases (Trks) A-C. Cells which express Trks include many neural tissues. For instance, corneal nerves secrete NTs to counteract epithelium disruption. Potential therapeutic applications of Trk agonism are numerous, but the use of NTs is limited by problems with production, in vivo stability, and side effects of the protein. Only humanized recombinant NGF has been clinically approved: Cenegermin for treatment of neurotrophic keratitis (NK) in the eye. Consequently, low molecular mass Trk agonists are of interest as surrogates for humanized NTs. One low molecular mass TrkA modulator from our lab, a -organopeptide , emerged as a clinical candidate for treatment of dry eye disease and reached phase 3 trials. However, it remains to be determined whether similar agonists or modulators of other Trks might exhibit similar effects. Moreover, was moved into trials without much optimization. This work was undertaken to identify -organopeptides which would activate TrkA, B, and/or C and to compare their potencies to . The immediate goal was to select compounds for studies to probe relief from desiccating stress to the eye in a mouse model relative to . In fact, in vivo assays on select compounds developed in the work described here have already been published. Three new -organopeptides selected for Trk agonism or modulation and were tested, and a superior lead for relief of desiccating stress in vivo was identified. Interestingly, that lead compound was designed to mimic NT-3, not NGF. This paper describes how those new -organopeptides were designed, prepared, and then selected via screens on Trk-transfected cells. It also outlines and explains obstacles which limit progress in this type of study.
神经营养因子(NTs,包括神经生长因子(NGF)、脑源性神经营养因子(BDNF)、神经营养因子-4(NT-4)和神经营养因子-3(NT-3))是细胞外细胞因子,可调节表达原肌球蛋白受体激酶(Trks)A-C的细胞的存活和生长。表达Trks的细胞包括许多神经组织。例如,角膜神经分泌NTs以对抗上皮细胞破坏。Trk激动剂的潜在治疗应用众多,但NTs的使用受到生产、体内稳定性和蛋白质副作用等问题的限制。只有人源化重组NGF已获得临床批准:cenegermin用于治疗眼部神经营养性角膜炎(NK)。因此,低分子量Trk激动剂作为人源化NTs的替代物备受关注。我们实验室的一种低分子量TrkA调节剂,一种有机肽,成为治疗干眼病的临床候选药物并进入了3期试验。然而,其他Trks的类似激动剂或调节剂是否会表现出类似效果仍有待确定。此外,该有机肽在没有进行太多优化的情况下就进入了试验阶段。开展这项工作的目的是鉴定能够激活TrkA、B和/或C的有机肽,并将它们的效力与该有机肽进行比较。直接目标是选择化合物用于研究,以探究相对于该有机肽而言,在小鼠模型中缓解眼部干燥应激的情况。事实上,本文所述工作中开发的选定化合物的体内试验已经发表。测试了三种新的被选定用于Trk激动或调节的有机肽以及该有机肽,并确定了一种在体内缓解干燥应激方面更优的先导化合物。有趣的是,该先导化合物被设计为模拟NT-3,而非NGF。本文描述了这些新有机肽是如何设计、制备的,然后通过在Trk转染细胞上的筛选进行选择。它还概述并解释了限制这类研究进展的障碍。
