TY - JOUR T1 - A pitfall for machine learning methods aiming to predict across cell types JF - bioRxiv DO - 10.1101/512434 SP - 512434 AU - Jacob Schreiber AU - Ritambhara Singh AU - Jeffrey Bilmes AU - William Stafford Noble Y1 - 2019/01/01 UR - http://biorxiv.org/content/early/2019/01/04/512434.abstract N2 - Machine learning models to predict phenomena such as gene expression, enhancer activity, transcription factor binding, or chromatin conformation are most useful when they can generalize to make accurate predictions across cell types. In this situation, a natural strategy is to train the model on experimental data from some cell types and evaluate performance on one or more held-out cell types. In this work, we show that, when the training set contains examples derived from the same genomic loci across multiple cell types, then the resulting model can be susceptible to a particular form of bias related to memorizing the average activity associated with each genomic locus. Consequently, the trained model may appear to perform well when evaluated on the genomic loci that it was trained on but tends to perform poorly on loci that it was not trained on. We demonstrate this phenomenon by using epigenomic measurements and nucleotide sequence to predict gene expression and chromatin domain boundaries, and we suggest methods to diagnose and avoid the pitfall. We anticipate that, as more data and computing resources become available, future projects will increasingly risk suffering from this issue. ER -