A hidden protamine PTM code in sperm generates heterogeneous chromatin states and finetunes reproductive fitness.
Lindsay Moritz, Christopher J Woodilla, Ritvija Agrawal, Mashiat Rabbani, Samantha B Schon, Wenxin Xie, Catherine A Tower, Sowmya Srinivasan, Yi Sheng, Michael R Baldwin, Patrick J O'Brien, Rex A Hess, Kyle E Orwig, Sy Redding, Saher Sue Hammoud
Abstract
Open AccessTraditionally, the sperm genome is thought to be packaged by protamines into a uniformly compact and inert chromatin structure. Here, we challenge this long-standing view by demonstrating that protamine post-translational modifications (PTMs) present on distinct protamine molecules create discrete protamine-DNA chromatin states, ranging from weak to tightly associated chromatin configurations. Loss of these modifications alters protamine-DNA interactions in vitro and in vivo , compromising sperm chromatin integrity and impairing fertility. Therefore, these findings demonstrate that protamines do not merely serve as inert packaging proteins; rather protamine PTMs establish functional heterogeneity within sperm chromatin, creating compartment-like domains analogous to those in somatic cells. Thus, PTMs allow protamines to do more than simply compact the paternal genome-they likely encode a molecular blueprint that orchestrates the timely unpacking and reorganization of the paternal genome after fertilization.