Histone carbonylation occurs in proliferating cells

Chromatin is a dynamic structure formed mainly by DNA and histones, and chemical modifications on these elements regulate its compaction. Histone posttranslational modifications (PTMs) have a direct impact on chromatin conformation, controlling important cellular events such as cell proliferation and differentiation. Redox-related posttranslational modifications may have important effects on chromatin structure and function, offering a new intriguing area of research termed "redox epigenetics." Little is known about histone carbonylation, a PTM that may be related to modifications in the cellular redox environment. The aim of our study was to determine the carbonylation of the various histones during cell proliferation, a moment in cell life during which important redox changes take place. Here, we describe changes in histone carbonylation during cell proliferation in NIH3T3 fibroblasts. In addition, we have studied the variations of poly(ADP-ribosyl)ation and phospho-H2AX at the same time, because both modifications are related to DNA damage responses. High levels of carbonylation on specific histones (H1, H1(0), and H3.1 dimers) were found when cells were in an active phase of DNA synthesis. The modification decreased when nuclear proteasome activity was activated. However, these results did not correlate completely with poly(ADP-ribosyl)ation and phospho-H2AX levels. Therefore, histone carbonylation may represent a specific event during cell proliferation. We describe a new methodology named oxy-2D-TAU Western blot that allowed us to separate and analyze the carbonylation patterns of the histone variants. In addition we offer a new role for histone carbonylation and its implication in redox epigenetics. Our results suggest that histone carbonylation is involved in histone detoxification during DNA synthesis.     

Variations on the topic of the "histone code"

Histones are the fundamental structural proteins intimately associated with eukaryotic DNA to form a highly ordered and condensed nucleoproteic complex termed chromatin. They are the targets of various posttranslational modifications including acetylation, methylation, phosphorylation and ubiquitination that modulate the structure/function of chromatin. The combinatorial nature of histone modifications is hypothesized to define a "histone code" that considerably extends the information potential of the genetic code, giving rise to epigenetic information. Moreover, most core histones consist of several nonallelic variants that can mark specific loci and could play an important role in establishment and maintenance of epigenetic memory. Here we will briefly present our current knowledge about histone posttranslational modifications and their implications in the regulation of epigenetic information. We will next describe core histone variants, insisting on their mode of incorporation into chromatin to discuss their epigenetic function and inheritance.     

Histone phosphorylation: how to proceed

Among all posttranslational modifications that occur on histone tails, phosphorylation is the one that establishes a direct link between chromatin remodeling and intracellular signaling pathways. Specific, conserved serine residues are present on the N-terminal tails of each histone. These are phosphoacceptor sites for a number of kinases, whose identification is essential to decipher the transduction routes leading to various physiological responses. In the case of histone H3, phosphorylation at the Ser10 residue may lead to either activated gene expression or chromatin condensation during mitosis. In addition, phosphorylation at specific sites may be coupled to other distinct modifications, such as acetylation and methylation, generating the so-called "histone code" which postulates that well defined combinatorial modifications at histone tails correspond to specific physiological responses. Here we describe a number of experimental methodologies that are essential for the study of histone phosphorylation. While chromatin immunoprecipitation is useful in recognizing gene targets, the in-gel kinase assay is a first, essential step in establishing the identity of the kinase(s) that operates in response to a specific signaling pathway. The subsequent use of in vitro kinase assays is helpful in validating the implication of a candidate kinase. These powerful approaches are important as identification of the signaling transduction routes leading to chromatin remodeling is critical to an understanding of all cellular processes.     

Histone chaperones link histone nuclear import and chromatin assembly

Histone chaperones are proteins that shield histones from nonspecific interactions until they are assembled into chromatin. After their synthesis in the cytoplasm, histones are bound by different histone chaperones, subjected to a series of posttranslational modifications and imported into the nucleus. These evolutionarily conserved modifications, including acetylation and methylation, can occur in the cytoplasm, but their role in regulating import is not well understood. As part of histone import complexes, histone chaperones may serve to protect the histones during transport, or they may be using histones to promote their own nuclear localization. In addition, there is evidence that histone chaperones can play an active role in the import of histones. Histone chaperones have also been shown to regulate the localization of important chromatin modifying enzymes. This review is focused on the role histone chaperones play in the early biogenesis of histones, the distinct cytoplasmic subcomplexes in which histone chaperones have been found in both yeast and mammalian cells and the importins/karyopherins and nuclear localization signals that mediate the nuclear import of histones. We also address the role that histone chaperone localization plays in human disease. This article is part of a Special Issue entitled: Histone chaperones and chromatin assembly.     

In vitro induction of H1-H1 histone cross-linking by adenosine diphosphate-ribose polymers

It is well-known that H1-H1 interactions are very important for the induction of 30 nm chromatin fiber and that, among all posttranslational modifications, poly(ADP-ribosyl)ation is one of those capable of modifying chromatin structure, mainly through H1 histone. As this protein can undergo both covalent and noncovalent modifications by poly(ADP-ribosyl)ation, our aim was to investigate whether and how ADP-ribose polymers, by themselves, are able to affect the formation of H1-H1 oligomers, which are normally present in a condensed chromatin structure. The results obtained in our in vitro experimental system indicate that ADP-ribose polymers are involved in chromatin decondensation. This conclusion was reached as the result of two different observations: (a) H1 histone molecules can be hosted in clusters on ADP-ribose polymers, as shown by their ability to be chemically cross-linked, and (b) H1 histone has a higher affinity for ADP-ribose polymers than for DNA; ADP-ribose polymers compete, in fact, with DNA for H1 histone binding.     

Structures and interactions of the core histone tail domains

The core histone tail domains are "master control switches" that help define the structural and functional characteristics of chromatin at many levels. The tails modulate DNA accessibility within the nucleosome, are essential for stable folding of oligonucleosome arrays into condensed chromatin fibers, and are important for fiber-fiber interactions involved in higher order structures. Many nuclear signaling pathways impinge upon the tail domains, resulting in posttranslational modifications that are likely to alter the charge, structure, and/or interactions of the core histone tails or to serve as targets for the binding of ancillary proteins or other enzymatic functions. However, currently we have only a marginal understanding of the molecular details of core histone tail conformations and contacts. Here we review data related to the structures and interactions of the core histone tail domains and how these domains and posttranslational modifications therein may define the structure and function of chromatin.     

Histone variants as emerging regulators of embryonic stem cell identity

Dynamic regulation of chromatin structure is an important mechanism for balancing the pluripotency and cell fate decision in embryonic stem cells (ESCs). Indeed ESCs are characterized by unusual chromatin packaging, and a wide variety of chromatin regulators have been implicated in control of pluripotency and differentiation. Genome-wide maps of epigenetic factors have revealed a unique epigenetic signature in pluripotent ESCs and have contributed models to explain their plasticity. In addition to the well known epigenetic regulation through DNA methylation, histone posttranslational modifications, chromatin remodeling, and non-coding RNA, histone variants are emerging as important regulators of ESC identity. In this review, we summarize and discuss the recent progress that has highlighted the central role of histone variants in ESC pluripotency and ESC fate, focusing, in particular, on H1 variants, H2A variants H2A.X, H2A.Z and macroH2A and H3 variant H3.3.     

Posttranslational modifications of CENP-A: marks of distinction

Centromeres are specialized chromosome domain that serve as the site for kinetochore assembly and microtubule attachment during cell division, to ensure proper segregation of chromosomes. In higher eukaryotes, the identity of active centromeres is marked by the presence of CENP-A (centromeric protein-A), a histone H3 variant. CENP-A forms a centromere-specific nucleosome that acts as a foundation for centromere assembly and function. The posttranslational modification (PTM) of histone proteins is a major mechanism regulating the function of chromatin. While a few CENP-A site-specific modifications are shared with histone H3, the majority are specific to CENP-A-containing nucleosomes, indicating that modification of these residues contribute to centromere-specific function. CENP-A undergoes posttranslational modifications including phosphorylation, acetylation, methylation, and ubiquitylation. Work from many laboratories have uncovered the importance of these CENP-A modifications in its deposition at centromeres, protein stability, and recruitment of the CCAN (constitutive centromere-associated network). Here, we discuss the PTMs of CENP-A and their biological relevance.     

Sensing core histone phosphorylation — A matter of perfect timing

Systematic analysis of histone modifications has revealed a plethora of posttranslational modifications that mediate changes in chromatin structure and gene expression. Histone phosphorylation is a transient histone modification that becomes induced by extracellular signals, DNA damage or entry into mitosis. Importantly, phosphorylation of histone proteins does lead not only to the binding of specific reader proteins but also to changes in the affinity for readers or writers of other histone modifications. This induces a cross-talk between different chromatin modifications that allows the spatio-temporal control of chromatin-associated events. In this review we will summarize the progress in our current knowledge of factors sensing reversible histone phosphorylation in different biological scenarios. This article is part of a Special Issue entitled: Molecular mechanisms of histone modification function.     

The analysis of histone modifications

The biological function of many proteins is often regulated through posttranslational modifications (PTMs). Frequently different modifications influence each other and lead to an intricate network of interdependent modification patterns that affect protein-protein interactions, enzymatic activities and sub-cellular localizations. One of the best-studied class of proteins that is affected by PTMs and combinations thereof are the histone molecules. Histones are very abundant, small basic proteins that package DNA in the eukaryotic nucleus to form chromatin. The four core-histones are densely modified within their first 20-40 N-terminal amino acids, which are highly evolutionary conserved despite playing no structural role. The modifications are thought to constitute a histone code that is used by the cell to encrypt various chromatin conformations and gene expression states. The analysis of modified histones can be used as a model to dissect complex modification patterns and to investigate their molecular functions. Here we review techniques that have been used to decipher complex histone modification patterns and discuss the implication of these findings for chromatin structure and function.     

The site-specific installation of methyl-lysine analogs into recombinant histones

Histone lysine residues can be mono-, di-, or trimethylated. These posttranslational modifications regulate the affinity of effector proteins and may also impact chromatin structure independent of their role as adaptors. In order to study histone lysine methylation, particularly in the context of chromatin, we have developed a chemical approach to install analogs of methyl lysine into recombinant proteins. This approach allows for the rapid generation of large quantities of histones in which the site and degree of methylation can be specified. We demonstrate that these methyl-lysine analogs (MLAs) are functionally similar to their natural counterparts. These methylated histones were used to examine the influence of specific lysine methylation on the binding of effecter proteins and the rates of nucleosome remodeling. This simple method of introducing site-specific and degree-specific methylation into recombinant histones provides a powerful tool to investigate the biochemical mechanisms by which lysine methylation influences chromatin structure and function.     

Modulation of chromatin function through linker histone H1 variants

In this review, the structural aspects of linker H1 histones are presented as a background for characterization of the factors influencing their function in animal and human chromatin. The action of H1 histone variants is largely determined by dynamic alterations of their intrinsically disordered tail domains, posttranslational modifications and allelic diversification. The interdependent effects of these factors can establish dynamic histone H1 states that may affect the organization and function of chromatin regions.     

Mechanisms for the inheritance of chromatin states

Studies in eukaryotes ranging from yeast to mammals indicate that specific chromatin structures can be inherited following DNA replication via mechanisms acting in cis. Both the initial establishment of such chromatin structures and their inheritance require sequence-dependent specificity factors and changes in histone posttranslational modifications. Here I propose models for the maintenance of epigenetic information in which DNA silencers or nascent RNA scaffolds act as sensors that work cooperatively with parentally inherited histones to re-establish chromatin states following DNA replication.