DNA methylation (DNAm) occurs at cytosines in CpG dinucleotides and alters gene expression, and hence it may lead to development of diseases. DNAm is an intermediate factor between genome sequence, environmental factors and gene expression; therefore, it could serve as a good choice of biomarker. Both CpG islands (CGI) and biological pathway might have effects on DNA methylation. However, among the methods for studying differential DNAm, to the best of our knowledge, no one has considered incorporating these two factors into analysis simultaneously. We proposed a Bayesian hierarchical model for differential DNAm profiling that takes these two factors into consideration: (1) The CpG location in CGI or not. (2) Pathway information of the gene that the CpG located. We considered six different functions to describe pathway information. The functions concern the presence of genes in pathways, the number of neighboring genes in pathways, and the CpG located in CGI or not. To evaluate the performance of the proposed model, we analyzed the DNAm data of United Kingdom Ovarian Cancer Population Study (UKOPS). The results showed that our proposed model can provide a novel insight into the identification of the disease-related pathways and disease-related genes contained in the pathways. In conclusion, our approach could serve as a tool to explore the molecular mechanism of the development and progression of disease; moreover, based on the pathway information, it may help identify the biomarkers with potential use in clinical applications.