Author: Elisa Oberbeckmann; Vanessa Niebauer; Shinya Watanabe; Lucas Farnung; Manuela Moldt; Andrea Schmid; Patrick Cramer; Craig L. Peterson; Sebastian Eustermann; Karl-Peter Hopfner; Philipp Korber
Title: Ruler elements in chromatin remodelers set nucleosome array spacing and phasing Document date: 2020_2_29
ID: 5hkd80eh_28_1
Snippet: on of sliding rates, i.e., the yaxis in Figure 7A could correspond to "overall sliding rate to the left or to the right". If sliding rates are reciprocally regulated (example 1, Figure 7A ), the sum of absolute sliding rate values is constant at each position ( Figure 7B ), but not upon asymmetric regulation of sliding direction (examples 2 and 3, Figure 7A ). As special case (example 3, Figure 7A ,B), the dynamic equilibrium point may correspond.....
Document: on of sliding rates, i.e., the yaxis in Figure 7A could correspond to "overall sliding rate to the left or to the right". If sliding rates are reciprocally regulated (example 1, Figure 7A ), the sum of absolute sliding rate values is constant at each position ( Figure 7B ), but not upon asymmetric regulation of sliding direction (examples 2 and 3, Figure 7A ). As special case (example 3, Figure 7A ,B), the dynamic equilibrium point may correspond to a minimum of absolute sliding rate. This case corresponds to the "kinetic release" model (Manelyte et al., 2014; Rippe et al., 2007) , which posits that remodelers position nucleosomes at sites where the nucleosome is the (locally) poorest substrate for remodeling.
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