Abstract
Diabetic nephropathy (DN), the leading cause of end-stage renal disease, has become a massive global health burden. Despite considerable efforts, the underlying mechanisms have not yet been comprehensively understood. In this study, a systematic approach was utilized to identify the microRNA signature in DN and to introduce novel drug targets (DTs) in DN. Using microarray profiling followed by qPCR confirmation, 13 and 6 differentially expressed (DE) microRNAs were identified in the kidney cortex and medulla, respectively. The microRNA-target interaction networks for each anatomical compartment were constructed and central nodes were identified. Moreover, enrichment analysis was performed to identify key signaling pathways. To develop a strategy for DT prediction, the human proteome was annotated with 65 biochemical characteristics and 23 network topology parameters. Furthermore, all proteins targeted by at least one FDA-approved drug were identified. Next, mGMDH-AFS, a high-performance machine learning algorithm capable of tolerating massive imbalanced size of the classes, was developed to classify DT and non-DT proteins. The sensitivity, specificity, accuracy, and precision of the proposed method were 90%, 86%, 88%, and 89%, respectively. Moreover, it significantly outperformed the state-of-the-art (P-value ≤ 0.05) and showed very good diagnostic accuracy and high agreement between predicted and observed class labels. The cortex and medulla networks were then analyzed with this validated machine to identify potential DTs. Among the high-rank DT candidates are Egfr, Prkce, clic5, Kit, and Agtr1a which is a current well-known target in DN. In conclusion, a combination of experimental and computational approaches was exploited to provide a holistic insight into the disorder for introducing novel therapeutic targets.
Highlights
Diabetic nephropathy (DN), the leading cause of end-stage renal disease, has become a massive global health burden
To translate the findings of this study to clinical application, a high-performance machine learning framework, named "modified Group Method of Data Handling with Automatic Feature Selection", was developed and validated for the prediction of drug targets (DTs) in human proteome based on a variety of biochemical and network topology features
For constructing a holistic map of DN, we started with the profile of miRNA related to this disease as these molecules target functionally related genes so each variably expressed miRNA can be a clue to identify a group of related altered genes and functions5, 76. miRNA microarray was performed on the cortex and medulla samples, separately, and the quality of microarray data was confirmed using unsupervised hierarchical clustering and principal component analysis (PCA) (Fig. 3a)
Summary
Diabetic nephropathy (DN), the leading cause of end-stage renal disease, has become a massive global health burden. To translate the findings of this study to clinical application, a high-performance machine learning framework, named "modified Group Method of Data Handling with Automatic Feature Selection (mGMDH-AFS)", was developed and validated for the prediction of DT in human proteome based on a variety of biochemical and network topology features. This classifier was applied to candidate novel therapeutic targets in the constructed holistic map of DN.
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