Abstract
In this paper we characterize the performance of linear models trained via widely-used sparse machine learning algorithms. We build polygenic scores and examine performance as a function of training set size, genetic ancestral background, and training method. We show that predictor performance is most strongly dependent on size of training data, with smaller gains from algorithmic improvements. We find that LASSO generally performs as well as the best methods, judged by a variety of metrics. We also investigate performance characteristics of predictors trained on one genetic ancestry group when applied to another. Using LASSO, we develop a novel method for projecting AUC and correlation as a function of data size (i.e., for new biobanks) and characterize the asymptotic limit of performance. Additionally, for LASSO (compressed sensing) we show that performance metrics and predictor sparsity are in agreement with theoretical predictions from the Donoho-Tanner phase transition. Specifically, a future predictor trained in the Taiwan Precision Medicine Initiative for asthma can achieve an AUC of 0.63(0.02)$$0.63_{(0.02)}$$ and for height a correlation of 0.648(0.009)$$0.648_{(0.009)}$$ for a Taiwanese population. This is above the measured values of 0.61(0.01)$$0.61_{(0.01)}$$ and 0.631(0.008)$$0.631_{(0.008)}$$, respectively, for UK Biobank trained predictors applied to a European population.</p>