Chen Y , Tokuda JM , Topping T , Sutton JL , Meisburger SP , Pabit SA , Gloss LM , Pollack L .

GM073787 NIGMS NIH HHS , R01-GM085062 NIGMS NIH HHS , R01-GM088645 NIGMS NIH HHS , T32GM008267 NIGMS NIH HHS , T32 GM008267 NIGMS NIH HHS , P41 GM103485 NIGMS NIH HHS

	Figure 1. Contrast variation reveals DNA conformation within protein–nucleic acid complexes. (a) Cartoon depicting how contrast variation is used to isolate scattering from the DNA component in protein–nucleic acid complexes. Left: The protein–nucleic acid complex in solution can be approximated as three phases with electron densities ρSOLV (light blue), ρPROT (orange), and ρDNA (dark blue). Right: Because contrast arises from electron density differences, the electron density of the solvent is increased by adding small molecules such as sucrose until it matches that of the protein. Consequently, the protein is effectively ‘blanked’ and only the DNA contributes to the measured scattering signal. (b) Scattering profiles for NCP components measured separately in 2 M NaCl with and without sucrose. In 50% sucrose, proteins become invisible above the background and only the DNA contributes to the scattering. The resulting signal for the DNA is decreased because of the reduced contrast between the DNA and solvent.
	Figure 2. Schematic of stopped-flow mixing experiment to probe salt-induced disassembly of NCPs without sucrose. Compact NCPs in 0.2 M NaCl mix with buffer containing 3.0 M NaCl to achieve a final NaCl concentration of 1.9 M, where full NCP disassembly occurs. The optimal flow rates and volumes used were 6 ml/s and 315 μl for 0% sucrose and 7.5 ml/s and 375 μl for 50% sucrose. In 0% sucrose, both nucleosomal DNA and histones are ‘visible’, hence TR-SAXS data reports changes in NCP global size, structure and composition. In 50% sucrose, only nucleosomal DNA is ‘visible’, TR-SAXS data directly reveals changes in DNA conformation. λ is the wavelength of the incident X-rays (in à ).
	Figure 3. Kratky plots for 601-NCP in varied [NaCl] with (a) 0% and (b) 50% sucrose. The data (colored circles) and regularized fits to the data (black lines) are scaled and offset to enhance visualization. Because the data in (b) are significantly noisier, a moving average with a span of 9 was used to show the quality of the fits. The transition from a compact to an extended structure is observed as the strongly peaked curve changes to a more plateaued curve at high q with increasing [NaCl].
	Figure 4. Contrast variation reveals DNA conformation during salt-induced disassembly. (a) Radius of gyration (Rg) for 601-NCP and 5S-NCP in equilibrium with different NaCl concentration with and without sucrose. An expansion in size from 45 to 130 à is detected for both constructs with increasing [NaCl]. At 1 M NaCl and 50% sucrose, the 5S-NCP DNA (72 ± 3 à ) is more expanded than the 601-NCP (63 ± 1 à ). (b) P(R)s for 601-NCP in equilibrium with varied [NaCl] and 0% sucrose. A general extension of the NCP is observed with increasing [NaCl]. (c) Models used for calculating theoretical P(R)s for the wrapped (DNA component from the NCP crystal structure 1AOI) and unwrapped (linear 147 bp Widom 601 DNA) states. (d) P(R) peaks at three length scales are attributed to structural features as follows: d1—diameter of duplex DNA; d2—distance between overlapping DNA ends; d3—diameter of wrapped structure. (e) P(R)s for 601-NCP in equilibrium with varied [NaCl] and 50% sucrose. With the signal from proteins eliminated, P(R) reveals how DNA conformation changes as the NCP is destabilized by increasing [NaCl]. (f) Models representing ensembles of conformations selected by EOM that produce theoretical SAXS profiles that best fit the [NaCl]-dependent SAXS data. Percentages reporting weights of models and χ2 values assessing overall fit to experimental SAXS data are shown.
	Figure 5. I(0,t) and Rg(t) analysis monitoring protein dissociation and expansion of NCP size as DNA is released. (a and b) In 0% sucrose, I(0) values (black circles) monitor the time-dependent release of histone components for the 601-NCP and 5S-NCP, respectively. The 601-NCP remains intact for the first 200 ms and is described by a single exponential decay, whereas the 5S-NCP appears to dissociate faster, but shows a double exponential decay. In 50% sucrose, I(0) values (light/cyan circles) are decreased due to the reduced contrast and remain relatively unchanged since the signal arises from DNA alone. (c and d) Time-dependent changes in the radius of gyration reveals DNA unwrapping for 601-NCP and 5S-NCP, respectively. Dynamics were monitored on time scales ranging from 20 ms to 60 s after mixing. Equilibrium values for intact (in 0.2 M NaCl, corrected for contrast – see Supplementary Text: I(0) Analysis) and fully dissociated (in 2.0 M NaCl for 10 min) NCP states are shown for comparison. The gray dashed lines in (c) and (d) represent the Rgs for 601-NCP (=82.15 à ) and 5S-NCP (=95.37 à ) if the ‘J’-shaped DNAs (Figure 6c and d) are bound to intact histone octamers (models shown in Supplementary Figure S7a).
	Figure 6. Time-resolved SAXS with contrast variation reveals DNA conformation of kinetic intermediates. (a) Pairwise distance distribution functions, P(R), computed from time-resolved scattering profiles of 601-NCP and 5S-NCP in 0% sucrose. (b) Time-resolved P(R)s for 601-NCP and 5S-NCP in 50% sucrose revealing DNA conformational changes during salt-induced disassembly. (c and d) Comparison of experimental scattering profiles for (c) 601-NCP and (d) 5S-NCP in 50% sucrose with best fitting theoretical scattering profiles for symmetric (black lines) and asymmetric (red lines) models for the wrapped, intermediate and unwrapped DNAs (offset to aid visualization). Theoretical profiles are calculated from the models shown as insets. The intermediate DNA models were determined using EOM and the goodness of fits was assessed by comparing χ2 values. (e and f) P(R)s for the ensembles (red) selected by EOM analysis (models shown with χ2 fit to SAXS data) compared with the experimental P(R)s (black) determined from (e) the 200 ms kinetic intermediate of the 601-NCP in 50% sucrose and (f) 160 ms data of the 5S-NCP in 50% sucrose (for details see Supplementary Text: Minimum Chi-square (χ2) Fit, Ensemble Optimization Method and Supplementary Figure S8).
	Figure 7. Timeline of salt-induced disassembly of 601-NCP and 5S-NCP. For 601-NCP, DNA opens rapidly from one end and reaches a metastable conformation within the first 20 ms. The histone octamer is disrupted by the asymmetric unwinding, but retains strong electrostatic interactions with 601 DNA and maintains a ‘J’-shaped structure for ∼200 ms. This long-lived intermediate then dissociates at a rate of 0.74 ± 0.08 s−1. 5S-NCPs exhibit much faster dissociation dynamics. After 20 ms, the DNA is mostly unwrapped and extended but still bound to the histone components. No stable intermediates are detected and 5S-NCPs disassemble within 1 s (two rates measured: 41.6 ± 13.9 and 1.13 ± 0.74 s−1).

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