Key driver genes as potential therapeutic targets in renal allograft rejection
Zhengzi Yi, Karen L. Keung, Li Li, Min Hu, Bo Lu, Leigh Nicholson, Elvira Jimenez-Vera, Madhav C. Menon, Chengguo Wei, Stephen Alexander, Barbara Murphy, Philip J. O’Connell, Weijia Zhang
Zhengzi Yi, Karen L. Keung, Li Li, Min Hu, Bo Lu, Leigh Nicholson, Elvira Jimenez-Vera, Madhav C. Menon, Chengguo Wei, Stephen Alexander, Barbara Murphy, Philip J. O’Connell, Weijia Zhang
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Research Article Transplantation

Key driver genes as potential therapeutic targets in renal allograft rejection

Abstract

Acute rejection (AR) in renal transplantation is an established risk factor for reduced allograft survival. Molecules with regulatory control among immune pathways of AR that are inadequately suppressed, despite standard-of-care immunosuppression, could serve as important targets for therapeutic manipulation to prevent rejection. Here, an integrative, network-based computational strategy incorporating gene expression and genotype data of human renal allograft biopsy tissue was applied, to identify the master regulators — the key driver genes (KDGs) — within dysregulated AR pathways. A 982–meta-gene signature with differential expression in AR versus non-AR was identified from a meta-analysis of microarray data from 735 human kidney allograft biopsy samples across 7 data sets. Fourteen KDGs were derived from this signature. Interrogation of 2 publicly available databases identified compounds with predicted efficacy against individual KDGs or a key driver–based gene set, respectively, which could be repurposed for AR prevention. Minocycline, a tetracycline antibiotic, was chosen for experimental validation in a murine cardiac allograft model of AR. Minocycline attenuated the inflammatory profile of AR compared with controls and when coadministered with immunosuppression prolonged graft survival. This study demonstrates that a network-based strategy, using expression and genotype data to predict KDGs, assists target prioritization for therapeutics in renal allograft rejection.

Authors

Zhengzi Yi, Karen L. Keung, Li Li, Min Hu, Bo Lu, Leigh Nicholson, Elvira Jimenez-Vera, Madhav C. Menon, Chengguo Wei, Stephen Alexander, Barbara Murphy, Philip J. O’Connell, Weijia Zhang

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Figure 2

Heatmap representation of the 982 differentially expressed meta-genes in AR and functional enrichment analysis.

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Heatmap representation of the 982 differentially expressed meta-genes in...
(A) Heatmap demonstrating expression level of the 982 DEGs in each of the 7 public data sets included in the meta-analysis. The heatmap values are represented as effect size (Hedges’ g) as depicted in the color scale bar above the heatmap. Green is indicative of downregulation (reduced expression) and red indicative of upregulation (increased expression) of each gene in AR compared with non-AR samples within each data set. (B and C) GO enrichment analysis identified that the most enriched biological processes represented by the upregulated genes (B) include immune response, cell activation, and chemotaxis. The downregulated genes were enriched in metabolism and transport processes (C). Negative log of the P value, –log(P), is presented, with higher –log(P) values indicating greater statistical significance. (D) Innate immune cell populations were identified among the upregulated DEGs by cell enrichment analysis based on ImmGen database. Bar chart of significantly enriched cell types is ordered by significance, –log(P) values.