Abstract
Molecular crowding causes the compaction of chromatin fibers, contributing to the formation of the nuclear architecture. However, the molecular mechanism of compaction under crowded conditions is not yet fully understood. In this study, we employed the single-molecule optical tweezer method to investigate the effect of molecular crowding on chromatin structure. Force-extension experiments on a 12-mer polynucleosome in the presence of different sizes and concentrations of polyethylene glycol (PEG) as a crowding agent showed that at low concentrations of low-molecular-weight (MW) PEG, the compaction of the polynucleosome was not significant. In this respect, nucleosomes predominantly remained separated, while DNA-histone interactions within individual nucleosomes were slightly stabilized. In contrast, high concentrations of high-MW PEG significantly promote internucleosomal interactions, leading to highly compact polynucleosome conformations. Under these conditions, approximately 30 pN of force was required to disrupt the internucleosomal interactions and release DNA; this force was 36% higher than that required for DNA unwrapping in the absence of PEG. These findings suggest that molecular crowding impacts cellular processes by mechanically regulating chromatin accessibility for regulatory proteins and the passage of motor molecules such as RNA polymerase. Significance Statement Chromatin condensation is closely related to biological processes such as transcription and replication. Molecular crowding has recently attracted attention as a factor regulating chromatin condensation. In this study, we used the optical tweezer method to analyze the molecular mechanisms underlying chromatin condensation. We found that high-molecular weight and high-concentration crowders (polyethylene glycol) induced significant compaction, which involved internucleosomal interactions that markedly reduced DNA accessibility. Our results suggest that molecular crowding not only alters the condensation state, but also mechanically regulates chromatin accessibility.
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Abstract
Molecular crowding causes the compaction of chromatin fibers, contributing to the formation of the nuclear architecture. However, the molecular mechanism of compaction under crowded conditions is not yet fully understood. In this study, we employed the single-molecule optical tweezer method to investigate the effect of molecular crowding on chromatin structure. Force-extension experiments on a 12-mer polynucleosome in the presence of different sizes and concentrations of polyethylene glycol (PEG) as a crowding agent showed that at low concentrations of low-molecular-weight (MW) PEG, the compaction of the polynucleosome was not significant. In this respect, nucleosomes predominantly remained separated, while DNA-histone interactions within individual nucleosomes were slightly stabilized. In contrast, high concentrations of high-MW PEG significantly promote internucleosomal interactions, leading to highly compact polynucleosome conformations. Under these conditions, approximately 30 pN of force was required to disrupt the internucleosomal interactions and release DNA; this force was 36% higher than that required for DNA unwrapping in the absence of PEG. These findings suggest that molecular crowding impacts cellular processes by mechanically regulating chromatin accessibility for regulatory proteins and the passage of motor molecules such as RNA polymerase.
Significance Statement Chromatin condensation is closely related to biological processes such as transcription and replication. Molecular crowding has recently attracted attention as a factor regulating chromatin condensation. In this study, we used the optical tweezer method to analyze the molecular mechanisms underlying chromatin condensation. We found that high-molecular weight and high-concentration crowders (polyethylene glycol) induced significant compaction, which involved internucleosomal interactions that markedly reduced DNA accessibility. Our results suggest that molecular crowding not only alters the condensation state, but also mechanically regulates chromatin accessibility.
Competing Interest Statement
The authors have declared no competing interest.
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