DNA-induced α-Helical Structure in the NH2-terminal Domain of Histone H1*

It is important to establish the structural properties of linker histones to understand the role they play in chromatin higher order structure and gene regulation. Here, we use CD, NMR, and IR spectroscopy to study the conformation of the amino-terminal domain of histone H1°, free in solution and bound to the DNA. The NH2-terminal domain has little structure in aqueous solution, but it acquires a substantial amount of α-helical structure in the presence of trifluoroethanol (TFE). As in other H1 subtypes, the basic residues of the NH2-terminal domain of histone H1° are clustered in its COOH-terminal half. According to the NMR results, the helical region comprises the basic cluster (Lys11–Lys20) and extends until Asp23. The fractional helicity of this region in 90% TFE is about 50%. His24 together with Pro25constitute the joint between the NH2-terminal helix and helix I of the globular domain. Infrared spectroscopy shows that interaction with the DNA induces an amount of α-helical structure equivalent to that observed in TFE. As coulombic interactions are involved in complex formation, it is highly likely in the complexes with DNA that the minimal region with α-helical structure is that containing the basic cluster. In chromatin, the high positive charge density of the inducible NH2-terminal helical element may contribute to the binding stability of the globular domain.

[1]  R. Vilà,et al.  A helix‐turn motif in the C‐terminal domain of histone H1 , 2008, Protein science : a publication of the Protein Society.

[2]  R. Vilà,et al.  Induction of Secondary Structure in a COOH-terminal Peptide of Histone H1 by Interaction with the DNA , 2001, The Journal of Biological Chemistry.

[3]  F. Goñi,et al.  Structure and dynamics of membrane proteins as studied by infrared spectroscopy. , 1999, Progress in biophysics and molecular biology.

[4]  C. Allis,et al.  Phosphorylation of linker histone H1 regulates gene expression in vivo by mimicking H1 removal. , 1999, Molecular cell.

[5]  C. Crane-Robinson How do linker histones mediate differential gene expression? , 1999, BioEssays : news and reviews in molecular, cellular and developmental biology.

[6]  J. Ausió,et al.  Histone H1 binding does not inhibit transcription of nucleosomal Xenopus laevis somatic 5S rRNA templates. , 1998, Biochemistry.

[7]  A. Wolffe,et al.  The globular domain of histone H1 is sufficient to direct specific gene repression in early Xenopus embryos , 1998, Current Biology.

[8]  T. Archer,et al.  Prolonged glucocorticoid exposure dephosphorylates histone H1 and inactivates the MMTV promoter , 1998, The EMBO journal.

[9]  K. Wüthrich,et al.  Torsion angle dynamics for NMR structure calculation with the new program DYANA. , 1997, Journal of molecular biology.

[10]  M. Record,et al.  Binding of cationic (+4) alanine- and glycine-containing oligopeptides to double-stranded DNA: thermodynamic analysis of effects of coulombic interactions and alpha-helix induction. , 1997, Biochemistry.

[11]  A. Wolffe,et al.  What do linker histones do in chromatin? , 1997, BioEssays : news and reviews in molecular, cellular and developmental biology.

[12]  Xuetong Shen,et al.  Linker Histone H1 Regulates Specific Gene Expression but Not Global Transcription In Vivo , 1996, Cell.

[13]  S. Krimm,et al.  Infrared amide I' band of the coiled coil. , 1996, Biochemistry.

[14]  A. Wolffe,et al.  Developmentally regulated expression of linker-histone variants in vertebrates. , 1994, European journal of biochemistry.

[15]  P. V. von Hippel,et al.  Double-stranded DNA templates can induce alpha-helical conformation in peptides containing lysine and alanine: functional implications for leucine zipper and helix-loop-helix transcription factors. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[16]  A. Wolffe,et al.  Specific regulation of Xenopus chromosomal 5S rRNA gene transcription in vivo by histone H1. , 1994, Genes & development.

[17]  M. Gerstein,et al.  An NMR study on the DNA-binding SPKK motif and a model for its interaction with DNA. , 1993, Protein Engineering.

[18]  V. Ramakrishnan,et al.  Crystal structure of globular domain of histone H5 and its implications for nucleosome binding , 1993, Nature.

[19]  F. Blanco,et al.  CD and 1H-NMR studies on the conformational properties of peptide fragments from the C-terminal domain of thermolysin. , 1993, European journal of biochemistry.

[20]  K. V. van Holde,et al.  Histone H1 and transcription: still an enigma? , 1992, Journal of cell science.

[21]  Hajime Torii,et al.  Model calculations on the amide-I infrared bands of globular proteins , 1992, Other Conferences.

[22]  F. Richards,et al.  Relationship between nuclear magnetic resonance chemical shift and protein secondary structure. , 1991, Journal of molecular biology.

[23]  A. Mirzabekov,et al.  Chromatin superstructure-dependent crosslinking with DNA of the histone H5 residues Thr1, His25 and His62. , 1990, Journal of molecular biology.

[24]  K. Wüthrich NMR of proteins and nucleic acids , 1988 .

[25]  S. Martin,et al.  Alpha‐helix in the carboxy‐terminal domains of histones H1 and H5. , 1988, The EMBO journal.

[26]  H. Susi,et al.  Examination of the secondary structure of proteins by deconvolved FTIR spectra , 1986, Biopolymers.

[27]  James Allan,et al.  Roles of H1 domains in determining higher order chromatin structure and H1 location. , 1986, Journal of molecular biology.

[28]  D. Doenecke,et al.  Differential distribution of lysine and arginine residues in the closely related histones H1 and H5. Analysis of a human H1 gene. , 1986, Journal of molecular biology.

[29]  L. Böhm,et al.  Sequence conservation in the N‐terminal domain of histone H1 , 1985, FEBS letters.

[30]  Ad Bax,et al.  MLEV-17-based two-dimensional homonuclear magnetization transfer spectroscopy , 1985 .

[31]  K Wüthrich,et al.  Polypeptide secondary structure determination by nuclear magnetic resonance observation of short proton-proton distances. , 1984, Journal of molecular biology.

[32]  K. Wüthrich,et al.  Application of phase sensitive two-dimensional correlated spectroscopy (COSY) for measurements of 1H-1H spin-spin coupling constants in proteins. , 1983, Biochemical and biophysical research communications.

[33]  K Wüthrich,et al.  A two-dimensional nuclear Overhauser enhancement (2D NOE) experiment for the elucidation of complete proton-proton cross-relaxation networks in biological macromolecules. , 1980, Biochemical and biophysical research communications.

[34]  E. Bradbury,et al.  Studies on the role and mode of operation of the very-lysine-rich histone H1 in eukaryote chromatin. The three structural regions of the histone H1 molecule. , 1977, European journal of biochemistry.

[35]  R. R. Ernst,et al.  Two‐dimensional spectroscopy. Application to nuclear magnetic resonance , 1976 .

[36]  Y H Chen,et al.  Determination of the helix and beta form of proteins in aqueous solution by circular dichroism. , 1974, Biochemistry.

[37]  F. Goñi,et al.  Quantitative studies of the structure of proteins in solution by Fourier-transform infrared spectroscopy. , 1993, Progress in biophysics and molecular biology.