Salt effects on histone subunit interactions as studied by fluorescence spectroscopy

Royer, Catherine A.; Rusch, Ruth M.; Scarlata, Suzanne

doi:10.1021/bi00442a015

Cited by 17 publications

(23 citation statements)

References 23 publications

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“…Lowering the salt concentration to 200 mM slightly stabilized the protein to 6 X 10~8 M. Our data indicate a small negative volume change for the dissociation of the core particle octamer. The (H3)2(H4)2 tetramer, as was shown in the previous paper (Royer et al, 1989), also formed predominantly dimers of tetramers at higher protein or salt concentrations. In the study presented here, we found the dissociation constant for the H3/H4 octamer to dimer transition to be 1 X 10~21 M3 ***(Cly-2 = 4 X 10~8 M) at 2 M NaCl for the CT preparation.…”

supporting

confidence: 79%

Histone subunit interactions as investigated by high pressure

Scarlata¹,

Ropp²,

Royer³

1989

Biochemistry

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High-pressure fluorescence polarization was used to investigate subunit interactions of the histone H2A-H2B dimer and the H3/H4 tetramer isolated from calf thymus (CT) and chicken erythrocyte (CE) chromatin. The proteins were individually labeled with the fluorescent probe 5-(dimethylamino)-naphthalene-1-sulfonate (dansyl or DNS), and the fluorescence polarization was measured as a function of pressure. The long fluorescence lifetime of the probe allows for the observation of global rotations of the protein, the rate of which is dependent upon the aggregation state. From the pressure dependence of the dansyl polarization, the Kd of H2A-H2B dissociation of the CE dimer was found to be approximately 1 X 10(-7) M at 2.0 M NaCl. Lowering the salt concentration to 200 mM slightly stabilized the protein to 6 X 10(-8) M. Our data indicate a small negative volume change for the dissociation of the core particle octamer. The (H3)2(H4)2 tetramer, as was shown in the previous paper (Royer et al., 1989), also formed predominantly dimers of tetramers at higher protein or salt concentrations. In the study presented here, we found the dissociation constant for the H3/H4 octamer to dimer transition to be 1 X 10(-21) M3 (C1/2 = 4 X 10(-8) M) at 2 M NaCl for the CT preparation. Decreasing the salt concentration to 200 mM reduced the stability of the CT H3/H4 octamer to 9 X 10(-21) M3 (C1/2 = 8 X 10(-8) M). The dimer of the CE tetramer also dissociated upon application of pressure in 2 M salt.(ABSTRACT TRUNCATED AT 250 WORDS)

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supporting

confidence: 79%

Histone subunit interactions as investigated by high pressure

Scarlata¹,

Ropp²,

Royer³

1989

Biochemistry

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“…Moreover, the apparent Stokes diameter obtained from the fits increased with the time of equilibration over a time scale of tens of minutes, ultimately reaching values that were significantly in excess of that determined for the octamer itself. It is known that the H2A-H2B heterodimers and the H32H42 tetramers produced by dissociation of histone octamers can form unnatural aggregates in approximately physiological ionic strength (Baxevanis et al, 1991;Royer et al, 1989;Scarlata et al, 1989;Sperling & Bustin, 1975; van Holde, 1989). We suspected that some of the heterodimers or tetramers or both might be polymerizing over time and that the autocorrelation functions obtained included contributions from both aggregates and any remaining heterodimers and tetramers.…”

Section: Resultsmentioning

confidence: 99%

“…An important attribute of this model is that it allows for maintenance of a relationship between regulatory signals encoded in the form of posttranslational histone modifications (van Holde, 1989;Wassarman & Kornberg, 1989) and the underlying DNA sequence. However, histone octamers are unstable in physiological ionic conditions; at equilibrium, octamers dissociate into an H3jH42 tetramer and two H2A-H2B heterodimers (Thomas & Butler, 1977; van Holde, 1989;Wassarman & Kornberg, 1989), and these in turn can repolymerize into nonnative H3-H4 or H2A-H2B polymers (Baxevanis et al, 1991;Royer et al, 1989;Scarlata et al, 1989;Sperling & Bustin, 1975; van Holde, 1989). If histone octamers were to dissociate during the time scale of polymerase progression, they would not be able to re-form a nucleosome after the polymerase had passed by.…”

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confidence: 99%

Lifetime of the histone octamer studied by continuous-flow quasielastic light scattering: Test of a model for nucleosome transcription

Feng

Scherl²,

Widom³

1993

Biochemistry

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An instrument for continuous-flow quasielastic light scattering is described that allows the translational diffusion coefficient of macromolecules to be determined as a function of time after the initiation of some time-dependent process by mixing. Control experiments are carried out using the proteins lysozyme and BSA to verify that flow of the solution does not lead to erroneous results. The instrument is used to determine the lifetime of the histone octamer. A solution of octamer that is artificially stabilized in 2.0 M NaCl is rapidly diluted to physiological ionic strength, and the Stokes diameter is determined as a function of the time, delta t, after mixing. We find that the octamers dissociate into their component H2A-H2B heterodimers and H(3)2H4 tetramers on a time scale that is faster than the earliest time point for which data were obtained, 1 s after mixing. This result argues against a simple mechanism for the progression of RNA or DNA polymerase through chromatin.

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“…FP has also been used to study the dynamics of monomer/dimer formation . Royer et al have studied the effect of salt concentration on histone subunit interactions using fluorescence polarization …”

Section: Introductionmentioning

confidence: 99%

“…[25][26][27] Royer et al have studied the effect of salt concentration on histone subunit interactions using fluorescence polarization. 28,29 Self-interaction chromatography (SIC) is a technique that can provide information about the self-interactions of a given protein, the second virial coefficient (B 22 ) and the effect of mobile phase modifiers on these interactions. 30 Cross interaction chromatography (CIC) is a modified form of SIC which enables one to study weak interactions between two different proteins.…”

Section: Introductionmentioning

confidence: 99%

Implementation of an experimental and computational tool set to study protein‐mAb interactions

Ranjan

Chung²,

Zhu³

et al. 2019

Biotechnology Progress

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This work focused on the development of a combined experimental and computational tool set to study protein‐mAb interactions. A model protein library was first screened using cross interaction chromatography to identify proteins with the strongest retention. Fluorescence polarization was then employed to study the interactions and thermodynamics of the selected proteins—lactoferrin, pyruvate kinase, and ribonuclease B with the mAb. Binding affinities of lactoferrin and pyruvate kinase to the mAb were seen to be relatively salt insensitive in the range examined. Further, a strong entropic contribution was observed, suggesting the importance of hydrophobic interactions. On the other hand, ribonuclease B‐mAb binding was seen to be enthalpically driven and salt sensitive, indicating the importance of electrostatic interactions. Protein–protein docking was then carried out and the results identified the CDR region on the mAb as an important binding site for all three proteins. The binding interfaces identified for the mAb‐lactoferrin and mAb‐pyruvate kinase systems were found to contain complementary hydrophobic and oppositely charged clusters on the interacting regions which were indicative of both hydrophobic and electrostatic interactions. On the other hand, the binding site on ribonuclease B was predominantly positively charged with minimal hydrophobicity. This resulted in an alignment with negatively charged clusters on the mAb, supporting the contention that these interactions were primarily electrostatic in nature. Importantly, these computational results were found to be consistent with the fluorescence polarization data and this combined approach may have utility in examining mAb‐HCP interactions which can often complicate the downstream processing of biologics. © 2019 American Institute of Chemical Engineers

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Salt effects on histone subunit interactions as studied by fluorescence spectroscopy

Cited by 17 publications

References 23 publications

Histone subunit interactions as investigated by high pressure

Histone subunit interactions as investigated by high pressure

Lifetime of the histone octamer studied by continuous-flow quasielastic light scattering: Test of a model for nucleosome transcription

Implementation of an experimental and computational tool set to study protein‐mAb interactions

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