The basic unit of chromatin is the nucleosome, a histone octamer with 147 base pairs of DNA wrapped around it. Positions of nucleosomes relative to each other and to DNA elements have a strong impact on chromatin structure and gene activity and are tightly regulated at multiple levels,
i.e., DNA sequence, transcription factor binding, histone modifications and variants, and chromatin remodeling enzymes (Bell
et al., 2011; Hughes and Rando, 2014). Nucleosome positions in cells or isolated nuclei can be detected by partial nuclease digestion of native or cross-linked chromatin followed by ligation-mediated polymerase chain reaction (LM-PCR) (McPherson
et al., 1993; Soutoglou and Talianidis, 2002). This protocol describes a nucleosome positioning assay using Micrococcal Nuclease (MNase) digestion of formaldehyde-fixed chromatin followed by LM-PCR. We exemplify the nucleosome positioning assay for the promoter of genes encoding ribosomal RNA (rRNA genes or rDNA) in mice, which has two mutually exclusive configurations. The rDNA promoter harbors either an upstream nucleosome (
NucU) covering nucleotides -157 to -2 relative to the transcription start site, or a downstream nucleosome (
NucD) at position -132 to +22 (Li
et al., 2006; Xie
et al., 2012). Radioactive labeling of LM-PCR products followed by denaturing urea-polyacrylamide gel electrophoresis allows resolution and relative quantification of both configurations. As depicted in the diagram in Figure 1, the nucleosome positioning assay is a versatile low to medium throughput method to map discrete nucleosome positions with high precision in a semi-quantitative manner.
Figure 1. Flow chart depicting the nucleosome positioning assay. The diagram shows how the assay is used to detect the ratio between upstream (
NucU) and downstream (
NucD) nucleosome positions at the mouse rDNA promoter. After all steps have been performed, the LM-PCR yields two radiolabeled products that differ in size and correspond to
NucU and
NucD. Signal intensities of the bands reflect the relative abundance of each nucleosome position in the original sample.