John P. Baldwin

Post-translational modifications of the linker histone variants and their association with cell mechanisms

In recent years, a considerable amount of research has been focused on establishing the epigenetic mechanisms associated with DNA and the core histones. This effort is driven by the fact that epigenetics is intimately involved with genomics in a whole range of molecular processes. However, there is now a consensus that the epigenetics of the linker histones are just as important. The result of that consensus is that the post‐translational modifications (PTMs) for most of the linker histone variants in human and mouse have now been established by a number of experimental techniques, foremost of which is mass spectrometry (MS). MS was also used by our group to establish the PTMs of the linker histone variants in chicken erythrocytes. Although it is now known which types of PTM occur at particular locations on the linker histone variants, there is still a large gap in the knowledge of how this data relates to function. The focus of this review is an analysis of the PTM data for the linker histones from several species, but with an emphasis on human, mouse, and chicken. Our analysis reveals that certain PTMs can be clearly correlated with specific functions of the linker histones in particular cell types, and that unique PTM patterns exist for different cell types.

Low-resolution structure of the complex of human blood platelet factor 4 with heparin determined by small-angle neutron scattering

Small-angle neutron scattering was used to confirm that human platelet factor 4 was a compact tetrameric globular protein of radius of gyration 1.74 nm and indistinguishable from a sphere. The same technique, when applied to the 1:1 mol/mol complex of platelet factor and heparin of Mr 14000, revealed that the radius of gyration of the particle varied, depending on the relative proportion of 2H2O to H2O in the solvent. Analysis of this variation by the method of Ibel and Stuhrmann (Ibel, K. and Stuhrmann, H.B. (1975) J. Mol. Biol. 93, 255-266) revealed that in the complex the material of greatest neutron-scattering length (the highly sulphated polysaccharide heparin) was furthest from the centre of the particle. This confirms the postulate of Luscombe and Holbrook (Luscombe, M. and Holbrook, J.J. (1983) in Glycoconjugates (Chester, A.M., Heinegård, D., Lundblad, A. and Svensson, S., eds.), pp. 818-819, Secretariat, Lund) that the exact 1:1 mole ratio of heparin (Mr greater than 10 000) to platelet factor in this stable complex arises from the heparin winding around the outside of a globular protein core.

Characterization of post-translational modifications of the linker histones H1 and H5 from chicken erythrocytes using mass spectrometry.

Histone linker proteins H1 and H5 were purified from chicken erythrocyte cell nuclei under nondenaturing conditions. The purified linker histones were analyzed using in-solution enzymatic digestions followed by nanoflow reverse-phase high-performance liquid chromatography tandem mass spectrometry. We have identified all six major isoforms of the chicken histone H1 (H101, H102, H103, H110, H11R and H11L) and, in addition, the specialist avian isoform H5. In all the histone variants, both the acetylated and nonacetylated N (alpha)-terminal peptides were identified. Mass spectrometry analysis also enabled the identification of a wide range of post-translational modifications including acetylation, methylation, phosphorylation and deamidation. Furthermore, a number of amino acids were identified that were modified with both acetylation and methylation. These results highlight the extensive modifications that are present on the linker histone proteins, indicating that, similar to the core histones, post-translational modifications of the linker histones may play a role in chromatin remodelling and gene regulation.

Plant Chromatin Structure and Post-Translational Modifications

Abstract Although a majority of the key works on chromatin structure and function have been carried out using animal tissues, studies of plant chromatin and the characterization of the histones and nonhistone chromosomal proteins are now developing well. There are clear functional differences between plant and animal genomes, including the percentage of total DNA transcribed, levels of ploidy, and the pathways of morphogenesis and cell differentiation. It is therefore not surprising that differences are appearing between animal and plant chromatin, for example, the consensus amino acid sequence for the plant H3 globular domain; the extensions to the basic domain regions of some plant histones such as H2A, which have specific interactions with linker DNA; the larger molecular weight of the plant H1 molecule with its extended basic domains correlated with short lengths of linker DNA, and the absence of the five residue binding segment in the globular part of plant H1, which suggests differences in the organ...

Histone Structures: Targets for Modifications by Molecular Assemblies

Abstract: The core histone proteins contain modification sites that are key elements in the regulation of the cell cycle, DNA replication and repair with histone assembly, control of gene expression, and transcriptional elongation. Much work has been done on the various molecular assemblies that remodel nucleosomes, methylate, ubiquitinate, and cause ADP‐ribosylation of histones, and acetylate and phosphorylate core histone tails. The core histones are the final targets of the enzymes in the molecular assemblies. What structural changes in the histones are correlated with these modifications? This paper considers the high‐resolution structure of the histone octamer and stresses the importance of histone docking sequences in the binding of the two (H2A‐H2B) dimers to the (H3‐H4)2 tetramer. There is an extensive acid‐base area of interaction between histone octamers in crystals at high salt, which may have implications for nucleosome remodeling. We show that there are regions of high α‐helix probability in all core histone N‐terminal tails in regions where lysine acetylation occurs. There are also consensus sequences spanning up to eight amino acid residues between some histone tail regions. Circular dichroism studies using synchrotron radiation at wavelengths as low as 130 nm are promising for the accurate measurement of changes of histone secondary structure related to function.

Purification of histone core octamers and 2.15 Å X-ray analysis of crystals in KCl/phosphate

Intact histone octamers, produced by a new method quickly and in bulk, were crystallized in KCl/phosphate, and the X-ray data were analysed to 2.15 A, confirming a P65 space group. This environment preserves the high-resolution structure of the octamers and will be useful for studying them with other functionally important molecules. The octamers form into left-handed superhelices hexagonally spaced by 158.65 A, having a pitch of 102.57 A with six octamers per turn. A dipotassium tetraiodo mercurate derivative had good phasing power and should prove valuable in refining the structure after molecular-replacement analysis with lower resolution coordinates; the heavy atom was isomorphously placed at a unique site between the two H3-cysteine residues in the octamer.

Efficient purification of chromatin architectural proteins: histones, HMGB proteins and FKBP3 (FKBP25) immunophilin

A two-step process of high ionic strength lysis of chicken erythrocyte cell nuclei followed by cation-exchange chromatography has separated at very high yield all the histone and HMGB (high-mobility group B) nuclear proteins, except the less-soluble histone tetramers. Surprisingly high yields of the nuclear immunophilin FKBP3 (FKBP25) and Hsp70 (heat-shock protein 70) co-fractionate with HMGB1 and HMGB3. Furthermore, these proteins can be separated by anion-exchange chromatography. The purified nuclear proteins retain their native, post-translational modification (PTM) marks, including those associated with chromatin-fibre remodelling. These marks are intimately associated with the control of the cell cycle. The methods herein are therefore of value for targeting these and other nuclear proteins for future proteomic studies in healthy and diseased cells.

Cofractionation of HMGB proteins with histone dimers

An effective and flexible method is presented that can be used to investigate cofractionation of groups of nuclear proteins. The method was used to analyze chromatin-related proteins, of which high-mobility group B (HMGB) proteins consistently cofractionated by cation-exchange chromatography with the histone dimer (H2A-H2B). This led to the hypothesis that the two form a complex, further suggested by gel filtration, in which the HMGBs with core histones eluted as a defined high-molecular-weight peak. A necessary requirement for further studying protein interactions is that the constituents are of the highest possible purity and the pure histone dimers and tetramers used in this study were derived from pure histone octamers with their native marks. There is a growing interest in protein-protein interactions and an increasing focus on protein-interaction domains: most frequently, pull-down assays are used to examine these. The technology presented here can provide an effective system that complements pull-down assays.

New crystals of the histone core octamer diffract to higher resolution, 2.65 A.

A new crystal form of the histone octamer, crystallized in 1.6 M KCl, 1.6 M phosphate, diffracts to appreciably better than 2.6 A resolution. The crystals have space group P6(1) or P6(5) and lattice parameters a = b = 158.29, c = 103.27 A, alpha = beta = 90, gamma = 120 degrees, with one molecule per asymmetric unit. The new crystals promise to yield more detail of the histone basic domains and a higher resolution structure for the histone octamer.