Effect of A-tract-mediated linker histone orientation on trinucleosome compaction

Linker histones (LH) have been shown to preferentially bind to AT-rich DNA, particularly A-tracts, contiguous stretches of adenines. Using spFRET (single pair Forster/Fluorescence Resonance Energy Transfer), we recently found that the globular domain (gH) of Xenopus laevis H1.0b LH orients towards A-tracts on the linker-DNA (L-DNA) while binding on-dyad in LH:mononucleosome complexes. Here, we investigate the impact of this A-tract-mediated orientation of the gH on the compaction of higher-order structures by studying trinucleosomes as minimal models for chromatin. Two 600 bp DNA sequences were constructed, each containing three consecutive Widom 601 core sequences connected by about 40 bp L-DNA but differing in the positioning of A-tracts on either the outer or the inner L-DNAs flanking the first and third Widom 601 sequences. The two inner L-DNAs were fluorescently labelled at their midpoints. Trinucleosomes were reconstituted using the doubly labelled DNA, core histone octamers and H1.0b. SpFRET was performed for a range of NaCl concentrations to measure the compaction and whether gH orientations affected the stability of the trinucleosomes to salt-induced dissociation. While the LH compacted the trinucleosomes, the extent of compaction and the stability were similar for the two DNA sequences. Modeling constrained by the measured FRET efficiency suggests that the structures adopted by the trinucleosomes correspond to the standard zig-zagged two-helical start arrangement with the first and third nucleosomes stacked on top of each other. In this arrangement, the first and third LHs are insufficiently close to interact and affect compaction. Thus, despite differences in the positioning of the A-tracts in the sequences studied, LH binding compacts the corresponding trinucleosomes similarly. Why it mattersThe compaction and three-dimensional structure of chromatin affect the exposure of the DNA and thus regulate gene expression. Linker histone proteins bind to nucleosomes and thereby contribute to chromatin compaction. We here investigated whether the DNA A-tract-mediated orientation of a linker histone globular domain affects chromatin structure by using a trinucleosome as a minimal model for chromatin. Our observations suggest that the trinucleosome structure and compaction are robust against differences in linker histone globular domain orientations. eTOC blurbWe investigate whether DNA sequences, such as adenine-tracts, and sequence-induced linker histone reorientation affect chromatin structure. Using trinucleosomes as model systems for chromatin, we demonstrate that the chromatin structure and compaction are robust to the studied DNA sequence differences and sequence-induced linker histone orientation.