Intrinsic disorder prediction is an active area that has developed over 100 predictors. We identify and investigate a recent trend towards the development of deep neural network (DNN)-based methods. The first DNN-based method was released in 2013 and since 2019 deep learners account for majority of the new disorder predictors. We find that the 13 currently available DNN-based predictors are diverse in their topologies, sizes of their networks and the inputs that they utilize. We empirically show that the deep learners are statistically more accurate than other types of disorder predictors using the blind test dataset from the recent community assessment of intrinsic disorder predictions (CAID). We also identify several well-rounded DNN-based predictors that are accurate, fast and/or conveniently available. The popularity, favorable predictive performance and architectural flexibility suggest that deep networks are likely to fuel the development of future disordered predictors. Novel hybrid designs of deep networks could be used to adequately accommodate for diversity of types and flavors of intrinsic disorder. We also discuss scarcity of the DNN-based methods for the prediction of disordered binding regions and the need to develop more accurate methods for this prediction.
Keywords: BRNN, Bidirectional recurrent neural networks; CAID, Critical Assessment of Intrinsic Protein Disorder; CASP, Critical Assessment of Structure Prediction; CNN, Convolutional neural networks; DNN, Deep neural network; Deep learning; Deep neural networks; Disordered binding regions; Disordered regions; FFNN, Feed forward neural networks; IDP, Intrinsically disordered protein; IDR, Intrinsically disordered region; Intrinsic disorder; Prediction.
© 2022 The Authors.