Thermodynamic Characterization of Linker Histone Binding Interactions with ds-DNA

Machha, Venkata Ramana

17 May 2014

Linker histones (H1) are the basic proteins in higher eukaryotes that are responsible for the final condensation of chromatin. H1 also plays an important role in regulating gene expression. H1 has been described as a transcriptional repressor as it limits the access of transcriptional factors to DNA. Linker histone binds to DNA that enters or exits the nucleosome. Several crystal structures have been published for the nucleosome (histone core/DNA complex), and the interactions of the core histone proteins with DNA are well understood. In contrast the location of the linker histone and its interactions with ds-DNA are poorly understood. In this study we have used isothermal titration calorimetry (ITC), differential scanning calorimetry (DSC), and CD spectropolarimetry to determine the thermodynamic signatures and structural changes that accompany H1 binding to ds-DNA. The thermodynamic parameters for the binding of intact linker histones (H1.1, H1.4, and H10) to highly polymerized calf-thymus DNA and to short double stranded DNA oligomers have been determined. We have also determined the thermodynamics for binding of H10 C-terminal tail (H10-C) and globular domain (H10-G) to calf-thymus DNA. The real surprise in the energetics is that the enthalpy change for formation of the H1/DNA complex is very unfavorable and that H1/DNA complex formation is driven by very large positive changes in entropy. The binding site sizes for H1.1, H1.4, and H10 were determined to be 36bp, 32bp, and 36bp respectively. CD results indicate that CT-DNA is restructured upon complexation with either the full length H1 protein (H10) or its C-terminal domain (H10-C). In contrast, the structure of H10 is largely unchanged in the DNA complex. Temperature dependence of enthalpy change, osmotic stress and ionic strength dependence of Ka were tested using ITC. These results indicate that the entropy driven H1/DNA complexes are a result primarily from the expulsion of bound water molecules from the binding interface. This study provides new insights into the binding of linker Histone H1 to DNA. A better understanding of the functional properties of H1 and its interactions with DNA could provide new insights in understanding the role H1 in DNA condensation and transcriptional regulation.

Histone

H1.1

H1.4

H10

H10-C

H10-G

CT-DNA

chromatin

chromosome

nucleosome

ITC

CD

DSC

Role of linker Histone H1 variants in cell proliferation, Chromatin Structure and Gene expression in breast cancer cells

Sancho Medina, Mònica

30 May 2008

At least eleven histone H1 variants exist in mammalian somatic cells that bind to the linker DNA and stabilize the nucleosome particle contributing to higher order chromatin compaction. In addition of playing a structural role, H1 seems to be involved in the activation and repression of gene expression. It is not well known whether the different variants have specific roles or regulate specific promoters. We have explored this by inducible shRNA-mediated knock-down of each of the H1 variants in a human breast cancer cell line. Rapid inhibition of each H1 variant was not compensated by changes of expression of other variants. A different, reduced subset of genes is altered in each H1 knock-down. Interestingly, H1.2 depletion represses expression of a number of cell cycle genes. This is concomitant with a G1 arrest phenotype observed in this cell line. In addition, H1.2 depletion caused decreased global nucleosome spacing. These effects are specific of H1.2 depletion as they are not complemented by overexpression of other variants and they do not occur in knock-downs for the other variants. Moreover, H1.4 depletion caused cell death in T47D, being the first report of the essentiality of an H1 variant for survival in a human cell type. In addition to this, we have also investigated specificities of H1 subtypes location in particular promoters of interest in our laboratory, as well as specific interactions with other factors by generating HA-tagged H1 variant expressing cell lines. / Al menos once variantes de la histona H1 han sido identificadas en mamíferos, todas ellas se unen al ADN entre nucleosomas contribuyendo así, a la estabilización de la partícula nucleosómica y a la compactación de la cromatina en estructuras de alto orden. Además de jugar un papel estructural, H1 parece estar implicada en la activación y represión de la expresión génica. Se desconoce si las diferentes variantes de H1 tienen funciones específicas o regulan promotores específicos. Con el objetivo de investigar esta hipótesis se han generado líneas celulares que inhiben de forma inducible, mediante la tecnología de ARN interferente, la expresión de cada una de las variantes de forma específica. La inhibición de cada una de las variantes no es compensada por cambios en la expresión del resto de subtipos. Distintos grupos de genes resultan alterados con la depleción de cada una de las variantes de H1. La inhibición de H1.2 reprime la expresión de una serie de genes de ciclo celular, correlacionando con un fenotipo de arresto celular en fase G1 observado en esta línea. Además, la inhibición de H1.2 causa una disminución global del espaciamiento entre nucleosomas. Todos estos efectos parecen ser específicos para la falta de H1.2 ya que no son complementados por la sobreexpresión de otras variantes. Por otro lado, la inhibición de H1.4 causa muerte celular en T47D. Ésta es la primera vez que se describe que una variante de H1 es esencial para la supervivencia de una línea celular humana.En un segundo plano, se han construido líneas celulares con expresión de las variantes de H1 fusionadas al péptido HA, con el objetivo de estudiar la especificidad de su localización en promotores de interés para el grupo, así como interacciones específicas con otros factores celulares.

Expresión génica

Cromatina

Histona H1.5

Histona H1.4

Histona H1.3

Histona H1.2

Histona H1.0

Variantes H1

Histona internucleosómica

Histona H1

Gene expression

Chromatin

Histone H1.5

Histone H1.4

Histone H1.3

Histone H1.2

Histone H1.0

H1 variants

Histone H1

Linker histone

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