Abstract
BackgroundHuntington’s disease is a kind of chronic progressive neurodegenerative disease with complex pathogenic mechanisms. To data, the pathogenesis of Huntington’s disease is still not fully understood, and there has been no effective treatment. The rapid development of high-throughput sequencing technologies makes it possible to explore the molecular mechanisms at the transcriptome level. Our previous studies on Huntington’s disease have shown that it is difficult to distinguish disease-associated genes from non-disease genes. Meanwhile, recent progress in bio-medicine shows that the molecular origin of chronic complex diseases may not exist in the diseased tissue, and differentially expressed genes between different tissues may be helpful to reveal the molecular origin of chronic diseases. Therefore, developing integrative analysis computational methods for the multi-tissues gene expression data, exploring the relationship between differentially expressed genes in different tissues and the disease, can greatly accelerate the molecular discovery process.MethodsFor analysis of the intra- and inter- tissues’ differentially expressed genes, we designed an integrative enrichment analysis method based on an artificial neuron (IEAAN). Firstly, we calculated the differential expression scores of genes which are seen as features of the corresponding gene, using fold-change approach with intra- and inter- tissues’ gene expression data. Then, we weighted sum all the differential expression scores through a sigmoid function to get differential expression enrichment score. Finally, we ranked the genes according to the enrichment score. Top ranking genes are supposed to be the potential disease-associated genes.ResultsIn this study, we conducted large amounts of experiments to analyze the differentially expressed genes of intra- and inter- tissues. Experimental results showed that genes differentially expressed between different tissues are more likely to be Huntington’s disease-associated genes. Five disease-associated genes were selected out in this study, two of which have been reported to be implicated in Huntington’s disease.ConclusionsWe proposed a novel integrative enrichment analysis method based on artificial neuron (IEAAN), which displays better prediction precision of disease-associated genes in comparison with the state-of-the-art statistical-based methods. Our comprehensive evaluation suggests that genes differentially expressed between striatum and liver tissues of health individuals are more likely to be Huntington’s disease-associated genes.
Highlights
Huntington’s disease is a kind of chronic progressive neurodegenerative disease with complex pathogenic mechanisms
Huntington’s disease (HD) is a representative neurodegenerative disease, caused by excessive triplet (CAG) repeat located in huntingtin (HTT) gene on chromosome 4 that codes for polyglutamine in the huntingtin protein [1]
The molecular mechanisms of HD can not be completely explained by a single pathogenic factor
Summary
Huntington’s disease is a kind of chronic progressive neurodegenerative disease with complex pathogenic mechanisms. The pathogenesis of Huntington’s disease is still not fully understood, and there has been no effective treatment. Recent progress in bio-medicine shows that the molecular origin of chronic complex diseases may not exist in the diseased tissue, and differentially expressed genes between different tissues may be helpful to reveal the molecular origin of chronic diseases. Developing integrative analysis computational methods for the multi-tissues gene expression data, exploring the relationship between differentially expressed genes in different tissues and the disease, can greatly accelerate the molecular discovery process. It has been reported that many pathogenic factors may be related to the disease, such as neurotrophasthenia, impairment of axon transmission, impairment of metabolic pathways, protein misfolding, inflammation, and intestinal microorganism [6,7,8,9,10,11]. The complicated molecular pathogenesis of HD still remains elusive
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