Cancer classification based on chromatin accessibility profiles with deep adversarial learning model

Yang, Hai; Wei, Qiang; Li, Dongdong; Wang, Zhe

doi:10.1371/journal.pcbi.1008405

Cited by 7 publications

(1 citation statement)

References 54 publications

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“…There are recent demonstrations for the successful applications of deep learning methods for biomedicine, genetics, and genomics (Ainscough et al ., 2018; Eraslan et al ., 2019; Zou et al ., 2019; Arbab et al ., 2020; Kim et al ., 2021), as well as some examples from plant biology and agricultural science (Washburn et al ., 2019; Wang et al ., 2020; Dunker et al ., 2021; Warman et al ., 2021). Owing to the availability of big datasets generated by epigenetic and epigenomic research, it makes sense that deep learning models have shown promise for the identification of DNA methylation (Angermueller et al ., 2017; Holder et al ., 2017; Lv et al ., 2020; Li et al ., 2021), histone modifications (Xu et al ., 2017; Hoffman et al ., 2019), RNA methylation (Sun et al ., 2019; Wang & Wang, 2020), and chromatin interactions (Zhang et al ., 2018a; Yang et al ., 2020). However, these deep learning models are mostly implemented in nonplant species, so whether these models can be applied usefully in plant species remains unclear.…”

Section: Introductionmentioning

confidence: 99%

A deep learning approach to automate whole‐genome prediction of diverse epigenomic modifications in plants

et al. 2021

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Summary Epigenetic modifications function in gene transcription, RNA metabolism, and other biological processes. However, multiple factors currently limit the scientific utility of epigenomic datasets generated for plants. Here, using deep‐learning approaches, we developed a Smart Model for Epigenetics in Plants (SMEP) to predict six types of epigenomic modifications: DNA 5‐methylcytosine (5mC) and N6‐methyladenosine (6mA) methylation, RNA N6‐methyladenosine (m6A) methylation, and three types of histone modification. Using the datasets from the japonica rice Nipponbare, SMEP achieved 95% prediction accuracy for 6mA, and also achieved around 80% for 5mC, m6A, and the three types of histone modification based on the 10‐fold cross‐validation. Additionally, > 95% of the 6mA peaks detected after a heat‐shock treatment were predicted. We also successfully applied the SMEP for examining epigenomic modifications in indica rice 93‐11 and even the B73 maize line. Taken together, we show that the deep‐learning‐enabled SMEP can reliably mine epigenomic datasets from diverse plants to yield actionable insights about epigenomic sites. Thus, our work opens new avenues for the application of predictive tools to facilitate functional research, and will almost certainly increase the efficiency of genome engineering efforts.

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