Asymmetric Unwrapping of Nucleosomes under Tension Directed by DNA Local Flexibility

SummaryDynamics of the nucleosome and exposure of nucleosomal DNA play key roles in many nuclear processes, but local dynamics of the nucleosome and its modulation by DNA sequence are poorly understood. Using single-molecule assays, we observed that the nucleosome can unwrap asymmetrically and directionally under force. The relative DNA flexibility of the inner quarters of nucleosomal DNA controls the unwrapping direction such that the nucleosome unwraps from the stiffer side. If the DNA flexibility is similar on two sides, it stochastically unwraps from either side. The two ends of the nucleosome are orchestrated such that the opening of one end helps to stabilize the other end, providing a mechanism to amplify even small differences in flexibility to a large asymmetry in nucleosome stability. Our discovery of DNA flexibility as a critical factor for nucleosome dynamics and mechanical stability suggests a novel mechanism of gene regulation by DNA sequence and modifications

BLM helicase measures DNA unwound before switching strands and hRPA promotes unwinding reinitiation

Bloom syndrome (BS) is a rare genetic disorder characterized by genomic instability and a high predisposition to cancer. The gene defective in BS, BLM, encodes a member of the RecQ family of 3′–5′ DNA helicases, and is proposed to function in recombinational repair during DNA replication. Here, we have utilized single-molecule fluorescence resonance energy transfer microscopy to examine the behaviour of BLM on forked DNA substrates. Strikingly, BLM unwound individual DNA molecules in a repetitive manner, unwinding a short length of duplex DNA followed by rapid reannealing and reinitiation of unwinding in several successions. Our results show that a monomeric BLM can ‘measure' how many base pairs it has unwound, and once it has unwound a critical length, it reverses the unwinding reaction through strand switching and translocating on the opposing strand. Repetitive unwinding persisted even in the presence of hRPA, and interaction between wild-type BLM and hRPA was necessary for unwinding reinitiation on hRPA-coated DNA. The reported activities may facilitate BLM processing of stalled replication forks and illegitimately formed recombination intermediates

RecQ-core of BLM unfolds telomeric G-quadruplex in the absence of ATP

Various helicases and single-stranded DNA (ssDNA) binding proteins are known to destabilize G-quadruplex (GQ) structures, which otherwise result in genomic instability. Bulk biochemical studies have shown that Bloom helicase (BLM) unfolds both intermolecular and intramolecular GQ in the presence of ATP. Using single molecule FRET, we show that binding of RecQ-core of BLM (will be referred to as BLM) to ssDNA in the vicinity of an intramolecular GQ leads to destabilization and unfolding of the GQ in the absence of ATP. We show that the efficiency of BLM-mediated GQ unfolding correlates with the binding stability of BLM to ssDNA overhang, as modulated by the nucleotide state, ionic conditions, overhang length and overhang directionality. In particular, we observed enhanced GQ unfolding by BLM in the presence of non-hydrolysable ATP analogs, which has implications for the underlying mechanism. We also show that increasing GQ stability, via shorter loops or higher ionic strength, reduces BLM-mediated GQ unfolding. Finally, we show that while WRN has similar activity as BLM, RecQ and RECQ5 helicases do not unfold GQ in the absence of ATP at physiological ionic strength. In summary, our study points to a novel and potentially very common mechanism of GQ destabilization mediated by proteins binding to the vicinity of these structures

A comparative study of g-quadruplex unfolding and DNA reeling activities of human RECQ5 helicase

RECQ5 is one of five members of the RecQ family of helicases in humans, which include RECQ1, Bloom (BLM), Werner (WRN), RECQ4, and RECQ5. Both WRN and BLM have been shown to resolve G-quadruplex (GQ) structures. Deficiencies in unfolding GQ are known to result in DNA breaks and genomic instability, which are prominent in Werner and Bloom syndromes. RECQ5 is significant in suppressing sister chromatid exchanges during homologous recombination but its GQ unfolding activity are not known. We performed single-molecule studies under different salt (50-150 mM KCl or NaCl) and ATP concentrations on different GQ constructs including human telomeric GQ (with different overhangs and polarities) and GQ formed by thrombin-binding aptamer to investigate this activity. These studies demonstrated a RECQ5-mediated GQ unfolding activity that was an order of magnitude weaker than BLM and WRN. On the other hand, BLM and RECQ5 demonstrated similar single-stranded DNA (ssDNA) reeling activities that were not coupled to GQ unfolding. These results demonstrate overlap in function between these RecQ helicases; however, the relatively weak GQ destabilization activity of RECQ5 compared to BLM and WRN suggests that RECQ5 is not primarily associated with GQ destabilization, but could substitute for the more efficient helicases under conditions where their activity is compromised. In addition, these results implicate a more general role for helicase-promoted ssDNA reeling activity such as removal of proteins at the replication fork, whereas the association of ssDNA reeling with GQ destabilization is more helicase-specific