Integration of transcriptomic data identifies key hallmark genes in hypertrophic cardiomyopathy

Hypertrophic cardiomyopathy (HCM) is a genetically heterogeneous cardiac muscle disorder characterized by left ventricle hypertrophy in the absence of abnormal loading conditions [1]. HCM occurs in at least 1 in 500 of the general population, making it one of the most common inherited heart diseases [2]. In 70% of HCM patients, the disease is caused by mutations in sarcomeric genes, Z-disc genes, calcium-handling genes and so on. The genetic background of about 30% HCM patients remains unknown [3]. The cellular signaling processes that lead from the primary mutation to the HCM phenotype are also poorly understood. Therefore, it is essential to investigate the pathogenic mechanisms and develop novel diagnostic hallmark genes.

Two gene expression profiling technologies, microarray and RNA sequencing (RNA-Seq), have been widely used for obtaining gene expression signature. Compared to microarray, RNA-Seq can simultaneously detect whole gene expression levels [4]. Existing evidence showed a high consistency between microarray and RNA-Seq [5, 6].

In the last decade, various methods for classification have been developed and gained great attention of biomedical applications [7, 8]. In most classification studies, support vector machines (SVM), random forest (RF), K-Nearest-Neighbors (KNN) are reported as the foremost classifiers producing high accuracies [9].

In this study, the integrated analysis of transcriptomic datasets from different platforms was performed to identify differentially expressed genes (DEGs) between HCM patients and healthy controls (Fig. 1). Machine learning methods, including SVM, RF and KNN, were applied to prioritize the HCM candidate hallmark genes. This study provided novel perspective for understanding mechanism and exploiting new therapeutic means for HCM.

In the last decades, two gene expression profiling technologies including microarray and RNA-Seq have been proved to be excellent in revealing the biomarkers and cellular pathways of human disease [29]. Previous studies on HCM transcriptomic data have focused on only the microarray datasets or the RNA-Seq datasets [30, 31]. Advances in bioinformatics and the increasing number of transcriptomic datasets have enabled a full exploration of the integrated transcriptomic data to reveal molecular mechanisms underlying HCM.

An exhaustive search from the GEO, ArrayExpress, and SRA public repository has been performed to collect HCM and control heart tissue samples from both technologies. After data integration and DEGs extraction, the general LFC value of the identified DEGs were relatively low, we assume that the mild change of gene expression may be related to the slow disease progression of most HCM cases.

During the classification process, SVM, RF and KNN technologies were implemented for the DEGs evaluation. The differences in performance among classification techniques are usual in this type of problems, and several papers comparing classification techniques for biological data can be found in the literature [32‐34]. In the results above-mentioned, SVM classifier attains an optimal performance using only 8 genes. The behavior is also seen in the KNN technique, although with a lower performance. RF classifier obtained similar results when using the complete set of 48 genes but fails to design a simpler classifier with a low number of genes with optimal performance [32]. Thus, these results support the design of an optimal classifier based on SVM classifier with only eight genes.

The PPI network established between known HCM disease genes and eight HCM candidate hallmark genes contains helpful information for understanding the role of them in the development of HCM. JAK2 and GADD45A were found to be hub genes in the PPI network, indicating their important roles underlying HCM. Further functional enrichment analysis also showed that some intermediate genes participate in positive regulation of cardiac muscle tissue growth and cardiac septum morphogenesis.

Janus kinase 2, encoded by JAK2, is a protein tyrosine kinase involved in a specific subset of cytokine receptor signaling pathways. As a member of JAK family, JAK2 is an important component in the Janus kinase/signal transducer and activator of transcription (JAK/STAT) signaling pathway. The JAK/STAT signaling triggers multiple signals involved in development, homeostasis and inflammation [35, 36]. Accumulating evidence indicated that the JAK/STAT signaling pathway played a vital role in transducing stress and growth signals in the hypertrophic heart [37, 38]. The JAK/STAT pathway also transduces signals for a wide array of cytokines and growth factors including ANGII, TNF-α, IL-1β, IL-6 and IFN-γ, all of which have been involved in cardiac hypertrophy [39‐42]. Moreover, JAK2 has previously been reported to play an important role in left ventricular remodeling during pressure overload hypertrophy, and the development of hypertrophy can be blocked by pharmacological inhibition of JAK2 kinase [43]. Furthermore, one mutation V617F in JAK2 has been identified in one patient with myeloproliferative disorder (MPD) and HCM, suggesting a potential causative role of JAK2 in the development of HCM phenotype [44]. Recent studies also showed that cardiac JAK2 was critical for maintaining normal heart function, and its ablation produced a severe pathologic phenotype composed of myocardial remodeling [45]. Taken together, it is likely that JAK2 plays a central role in the pathogenesis of HCM. From our previous study, rare mutations in JAK2 were identified in 9/72 (12.5%) HCM patients without mutations in known HCM disease genes (Table 2) [3]. It would be interesting to further explore the specific role of these mutations and their associations with HCM.

Another hub gene GADD45A, encoding growth arrest and DNA damage inducible alpha, is a member of GADD45 gene family, which have been implicated in stress signaling responses to various physiological or environmental stressors, thus contributing to the maintenance of genomic stability [46]. Several previous studies have evaluated the hypothesis that two other GADD45 isoforms, including GADD45G and GADD45B, may have relevance to cardiac physiopathology [47, 48].

As one candidate hallmark gene, METTL7B is a member of mammalian methyltransferase-like family. The expression of METTL7B in HCM significantly decreased in our study. In line with our findings, one recent study showed that the expression levels of METTL7B in the cardiac tissue in the diabetic cardiomyopathy patient group were statistically lower than those in the healthy group [49]. However, the expression of METTL7B was significantly increased in iPSC-CMs compared with hESCs and fibroblasts. Despite the opposite results, all the present data support the importance of METTL7B in HCM, experimental data have yet to be fully investigated to determine its pathogenic relevance.

Additionally, the list of HCM-related genes between our study and previous studies of those datasets were compared and found that even though some genes appeared in the opposite direction in separated datasets [30, 50], most HCM relevant genes showed the same directions between microarray and RNA-seq datasets, including the eight candidate HCM hallmark genes.

Furthermore, due to the limited number of genes detected in the microarray datasets compared to the RNA-seq datasets, focusing on common DEGs through the intersection of datasets tend to lose some important information that RNA-seq would confer. Unfortunately, no enriched biological function and pathway based on the 48 identified HCM relevant genes can be found through GO and pathway analysis. However, we are confident with the results because they have been validated in different platforms and different patient cohorts.

Previous studies have demonstrated that distinct cellular pathways were involved in the development of HCM corresponding to different causative gene mutations [40]. However, based on the results in this study, we assumed that the eight candidate hallmark genes may act as a central role in the mutual cellular pathways underlying the HCM phenotype, which can somehow be triggered by most causative gene mutation. Further studies are needed to decipher the specific role of the candidate hallmark genes associated with HCM.

Integrating transcriptomic datasets from different platforms, have greatly aid the utility of biological data and improved the interpretation of gene expression values. Our results showed that the pipeline has good performance and a high accuracy of the classifier to distinguish unknown samples. Additionally, the central role of JAK2 and GADD45A in the pathogenic mechanism of HCM was highlighted. These findings will greatly contribute to extending our knowledge of the biological changes underlying HCM and providing perspective to reveal the pathology and develop therapeutic targets for HCM.