Abstract
Following recent observations of large scale correlated motion of chromatin inside the nuclei of live differentiated cells, we present a hydrodynamic theory - the two-fluid model - in which the content of a nucleus is described as a chromatin solution with the nucleoplasm playing the role of the solvent and the chromatin fiber that of a solute. This system is subject to both passive thermal fluctuations and active scalar and vector events that are associated with free energy consumption, such as ATP hydrolysis. Scalar events drive the longitudinal viscoelastic modes (where the chromatin fiber moves relative to the solvent) while vector events generate the transverse modes (where the chromatin fiber moves together with the solvent). Using linear response methods, we derive explicit expressions for the response functions that connect the chromatin density and velocity correlation functions to the corresponding correlation functions of the active sources and the complex viscoelastic moduli of the chromatin solution. We then derive general expressions for the flow spectral density of the chromatin velocity field. We use the theory to analyze experimental results recently obtained by one of the present authors and her co-workers. We find that the time dependence of the experimental data for both native and ATP-depleted chromatin can be well-fitted using a simple model - the Maxwell fluid - for the complex modulus, although there is some discrepancy in terms of the wavevector dependence. Thermal fluctuations of ATP-depleted cells are predominantly longitudinal. ATP-active cells exhibit intense transverse long wavelength velocity fluctuations driven by force dipoles. Fluctuations with wavenumbers larger than a few inverse microns are dominated by concentration fluctuations with the same spectrum as thermal fluctuations but with increased intensity.
| Original language | English |
|---|---|
| Pages (from-to) | 1871-1881 |
| Number of pages | 11 |
| Journal | Biophysical Journal |
| Volume | 106 |
| Issue number | 9 |
| DOIs | |
| State | Published - 6 May 2014 |
Bibliographical note
Funding Information:R.B. thanks the national Science Foundation for support under Division of Materials Research grant No.1006128. The work of A.Y.G. and Y.R. was supported in part by a grant from the US-Israel Binational Science Foundation. Y.R.’s research was supported by the I-CORE Program of the Planning and Budgeting Committee and The Israel Science Foundation. A.Z.’s research reported in this publication was supported by the Damon Runyon Cancer Research Foundation under Award No. DRG 2040-10 and by the National Institute of General Medical Sciences of the National Institutes of Health under Award No. K99GM104152.
Funding
R.B. thanks the national Science Foundation for support under Division of Materials Research grant No.1006128. The work of A.Y.G. and Y.R. was supported in part by a grant from the US-Israel Binational Science Foundation. Y.R.’s research was supported by the I-CORE Program of the Planning and Budgeting Committee and The Israel Science Foundation. A.Z.’s research reported in this publication was supported by the Damon Runyon Cancer Research Foundation under Award No. DRG 2040-10 and by the National Institute of General Medical Sciences of the National Institutes of Health under Award No. K99GM104152.
| Funders | Funder number |
|---|---|
| US-Israel Binational Science Foundation | |
| National Science Foundation | |
| National Institutes of Health | |
| National Institute of General Medical Sciences | K99GM104152 |
| Division of Materials Research | 1006128 |
| Damon Runyon Cancer Research Foundation | DRG 2040-10 |
| Israel Science Foundation | |
| Planning and Budgeting Committee of the Council for Higher Education of Israel |
