Murine model of triosephosphate isomerase deficiency with anemia and severe neuromuscular dysfunction

Tracey D. Myers , Carolyn Ferguson , Eric Gliniak , Gregg E. Homanics , Michael J. Palladino
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引用次数: 1

Abstract

Triosephosphate isomerase deficiency (TPI Df) is a rare, aggressive genetic disease that typically affects young children and currently has no established treatment. TPI Df is characterized by hemolytic anemia, progressive neuromuscular degeneration, and a markedly reduced lifespan. The disease has predominately been studied using invertebrate and in vitro models, which lack key aspects of the human disease. While other groups have generated mammalian Tpi1 mutant strains, specifically with the mouse mus musculus, these do not recapitulate key characteristic phenotypes of the human disease. Reported here is the generation of a novel murine model of TPI Df. CRISPR-Cas9 was utilized to engineer the most common human disease-causing mutation, Tpi1E105D, and Tpi1null mice were also isolated as a frame-shifting deletion. Tpi1E105D/null mice experience a markedly shortened lifespan, postural abnormalities consistent with extensive neuromuscular dysfunction, hemolytic anemia, pathological changes in spleen, and decreased body weight. There is a ∼95% reduction in TPI protein levels in Tpi1E105D/null animals compared to wild-type littermates, consistent with decreased TPI protein stability, a known cause of TPI Df. This work illustrates the capability of Tpi1E105D/null mice to serve as a mammalian model of human TPI Df. This work will allow for advancement in the study of TPI Df within a model with physiology similar to humans. The development of the model reported here will enable mechanistic studies of disease pathogenesis and, importantly, efficacy testing in a mammalian system for emerging TPI Df treatments.

Abstract Image

三磷酸异构酶缺乏症伴贫血和严重神经肌肉功能障碍小鼠模型
三磷酸异构酶缺乏症(TPI Df)是一种罕见的侵袭性遗传疾病,通常影响幼儿,目前尚无确定的治疗方法。TPI Df的特点是溶血性贫血,进行性神经肌肉变性,寿命明显缩短。该疾病主要使用无脊椎动物和体外模型进行研究,这些模型缺乏人类疾病的关键方面。虽然其他研究小组已经产生了哺乳动物Tpi1突变株,特别是小鼠小家鼠,但这些突变株并没有概括人类疾病的关键特征表型。本文报道了一种新的小鼠TPI Df模型的产生。CRISPR-Cas9被用于设计最常见的人类致病突变Tpi1E105D, Tpi1null小鼠也被分离为移帧缺失。Tpi1E105D/null小鼠的寿命明显缩短,体位异常与广泛的神经肌肉功能障碍一致,溶血性贫血,脾脏病理改变,体重下降。与野生型幼崽相比,Tpi1E105D/null动物的TPI蛋白水平降低了约95%,这与TPI蛋白稳定性下降一致,这是已知的TPI Df的原因。这项工作说明了Tpi1E105D/null小鼠作为人类TPI Df的哺乳动物模型的能力。这项工作将使TPI Df的研究在与人类生理相似的模型中取得进展。本文报道的模型的发展将使疾病发病机理的机制研究成为可能,更重要的是,在哺乳动物系统中对新出现的TPI Df治疗进行疗效测试。
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