Regulation of ISWI involves inhibitory modules antagonized by nucleosomal epitopes

Chromatin remodeling complexes (CRCs) mobilize nucleosomes to mediate the access of DNA-binding factors to their sites in vivo. These CRCs contain a catalytic subunit that bears an ATPase/DNA translocase domain, and flanking regions that bind nucleosomal epitopes(1). A central question is whether and how these flanking regions regulate ATP hydrolysis or the coupling of hydrolysis to DNA translocation, to affect nucleosome sliding efficiency. ISWIfamily CRCs contain ISWI(2), which utilizes its ATPase/DNA translocase domain to pump DNA around the histone octamer to enable sliding(3-7)_ENREF_13. ISWI is positively regulated by two ‘activating’ nucleosomal epitopes: the ‘basic patch’ on the H4 tail, and extranucleosomal (linker) DNA(8-13). Previous work defined the HSS domain in the ISWI C-terminus that binds linker DNA, needed for ISWI activity(14,15). Here, we define two new, conserved, and separate regulatory regions on Drosophila ISWI, AutoN and NegC, that negatively regulate ATP hydrolysis (AutoN) or the coupling of ATP hydrolysis to productive DNA translocation (NegC). Rather than ‘activating’, the two aforementioned nucleosomal epitopes actually inhibit the negative regulation of AutoN and NegC. Remarkably, mutation/removal of AutoN and NegC enables significant nucleosome sliding without the H4 ‘basic patch’ or extranucleosomal DNA, or the HSS domain – converting ISWI to biochemical attributes of SWI/SNF-family ATPases. Thus, the ISWI ATPase catalytic core is an intrinsically-active DNA translocase which conducts nucleosome sliding, onto which selective ‘inhibition-of-inhibition’ modules are placed, to help ensure that remodeling occurs only in the presence of proper nucleosomal epitopes. This supports a general concept for the specialization of chromatin remodeling ATPases, where specific regulatory modules adapt an ancient active DNA translocase to conduct particular tasks only on the appropriate chromatin landscape.