Wolff Julia Melina, Lang Konrad, Chen Mengmeng, Milosavljevic Julian, Kayser Séverine, Helmstädter Martin, Walz Gerd, Abed Ahmed, Gerstner Lea, Bahar Sami, Ulbrich Maximilian H, Hermle Tobias
Renal Division, Department of Medicine, Faculty of Medicine and Medical Center-University of Freiburg, Freiburg, Germany.
Renal Division, Department of Medicine, Faculty of Medicine and Medical Center-University of Freiburg, Freiburg, Germany; Spemann Graduate School of Biology and Medicine (SGBM) and Faculty of Biology, University of Freiburg, Freiburg, Germany.
Kidney Int. 2025 Jul;108(1):57-73. doi: 10.1016/j.kint.2025.03.030. Epub 2025 Apr 30.
Nephrin, the key structural protein of the slit diaphragm, is encoded by NPHS1. Pathogenic variants in this gene are the primary cause of congenital nephrotic syndrome. About 400 variants have been described but functional characterization in vitro is very limited.
Here, we express human nephrin in Drosophila nephrocytes, which possess a molecularly conserved slit diaphragm to facilitate functional studies.
Immunofluorescence of the human transgene revealed assembly into a complex linear architecture after silencing of sns, the Drosophila nephrin. This pattern suggests lateral clustering of human nephrin into a macromolecular configuration which resembles nephrin in vivo but is absent in cultured cells. In Drosophila nephrocytes, transgenic nephrin colocalized with the endogenous slit diaphragm proteins Pyd and Kirre, indicating a hybrid multi-protein complex. Transmission electron microscopy with pre-embedding immunogold labeling revealed an atypical, tubular ultrastructure. The linear nephrin did not adequately restore membrane invaginations, endocytic function or cellular survival, suggesting that proper signaling function requires additional indispensable cofactors. Murine NEPH1 alone was insufficient but associated with transgenic nephrin. Notably, the linear nephrin assembly provided a read-out for investigation of patient-derived variants. This distinct pattern was altered in transgenes reflecting patient variants with milder clinical presentation, including novel variant NPHS1-V1241G. The impact on the pattern largely correlated with the age of onset of nephrotic syndrome of the respective variant, as demonstrated by automated image annotation for quantitative evaluation.
Our findings demonstrate that transgenesis of NPHS1 in nephrocytes is a viable approach for investigation of slit diaphragm formation and precise functional characterization of patient variants.
Nephrin是裂孔隔膜的关键结构蛋白,由NPHS1编码。该基因的致病变异是先天性肾病综合征的主要原因。已描述了约400种变异,但体外功能表征非常有限。
在此,我们在果蝇肾细胞中表达人Nephrin,果蝇肾细胞具有分子保守的裂孔隔膜,便于进行功能研究。
人转基因的免疫荧光显示,在果蝇Nephrin(sns)沉默后组装成复杂的线性结构。这种模式表明人Nephrin横向聚集形成大分子构型,类似于体内的Nephrin,但在培养细胞中不存在。在果蝇肾细胞中,转基因Nephrin与内源性裂孔隔膜蛋白Pyd和Kirre共定位,表明形成了混合多蛋白复合物。预包埋免疫金标记的透射电子显微镜显示出非典型的管状超微结构。线性Nephrin不能充分恢复膜内陷、内吞功能或细胞存活,这表明正常的信号功能需要其他不可或缺的辅助因子。单独的小鼠NEPH1不足,但与转基因Nephrin相关。值得注意的是,线性Nephrin组装为研究患者来源的变异提供了一个检测指标。在反映临床表现较轻的患者变异的转基因中,这种独特模式发生了改变,包括新型变异NPHS1-V1241G。如通过自动图像注释进行定量评估所示,对该模式的影响在很大程度上与各变异的肾病综合征发病年龄相关。
我们的研究结果表明,在肾细胞中进行NPHS1转基因是研究裂孔隔膜形成和患者变异精确功能表征的可行方法。
