Interplay between histone deacetylase SIR-2, linker histone H1 and histone methyltransferases in heterochromatin formation

Maintenance of intact heterochromatin structure through epigenetic mechanisms is essential for cell survival. Defects in heterochromatin formation caused by loss of chromatin-modifying enzymes lead to genomic instability and cellular senescence. The NAD+-dependent histone deacetylase SIR-2 and the H1 linker histone are intriguing chromatin elements that are connected to chromatin regulation and cell viability in the single cellular eukaryotic organism yeast. However, it remains an open question how SIR-2 and H1 mediate heterochromatin formation in simple multi-cellular organisms such as C. elegans and in even more complex organisms such as mammals. Recently we have identified SIR-2.1 and the H1 histone subtype, HIS-24 as factors involved in heterochromatin regulation at subtelomeric regions in C. elegans. In addition we show that SIR-2.1, HIS-24, and MES-2, a ortholog to Enhancer of zeste E(Z) are functionally related in heterochromatin formation contributing to fertility and embryogenesis. Here we discuss the interplay between SIR-2, H1 histone and histone methyltransferases in modulation of chromatin structure in further detail.     

DNA methylation affects nuclear organization, histone modifications, and linker histone binding but not chromatin compaction

DNA methylation has been implicated in chromatin condensation and nuclear organization, especially at sites of constitutive heterochromatin. How this is mediated has not been clear. In this study, using mutant mouse embryonic stem cells completely lacking in DNA methylation, we show that DNA methylation affects nuclear organization and nucleosome structure but not chromatin compaction. In the absence of DNA methylation, there is increased nuclear clustering of pericentric heterochromatin and extensive changes in primary chromatin structure. Global levels of histone H3 methylation and acetylation are altered, and there is a decrease in the mobility of linker histones. However, the compaction of both bulk chromatin and heterochromatin, as assayed by nuclease digestion and sucrose gradient sedimentation, is unaltered by the loss of DNA methylation. This study shows how the complete loss of a major epigenetic mark can have an impact on unexpected levels of chromatin structure and nuclear organization and provides evidence for a novel link between DNA methylation and linker histones in the regulation of chromatin structure.     

Special issue on epigenetic inheritance by histone modifications, histone variants and non-coding RNAs

Keeping in view the ever-growing importance of understanding the epigenetic phenomena shaping the behavior of life, our team decided to embark on the idea to organize this special issue of Frontiers in Biology on Epigenetics.Epigenetics refers to the study of heritable changes in gene expression without changes in DNA sequence, which is accomplished by DNA methylation, histone modifications, histone variants, chromatin remodeling, and non-coding RNAs.     

Metabolic substrates,histone modifications,and heart failure

Histone epigenetic modifications are chemical modification changes to histone amino acid residues that modulate gene expression without altering the DNA sequence. As both the phenotypic and causal factors, cardiac metabolism disorder exacerbates mitochondrial ATP generation deficiency, thus promoting pathological cardiac hypertrophy. Moreover, several concomitant metabolic substrates also promote the expression of hypertrophy-responsive genes via regulating histone modifications as substrates or enzyme-modifiers, indicating their dual roles as metabolic and epigenetic regulators. This review focuses on the cardiac acetyl-CoA-dependent histone acetylation, NAD⁺-dependent SIRT-mediated deacetylation, FAD⁺-dependent LSD-mediated, and α-KG-dependent JMJD-mediated demethylation after briefly addressing the pathological and physiological cardiac energy metabolism. Besides using an “iceberg model” to explain the dual role of metabolic substrates as both metabolic and epigenetic regulators, we also put forward that the therapeutic supplementation of metabolic substrates is promising to blunt HF via re-establishing histone modifications.     

Effects of acetic acid-alcohol,trypsin, histone 1 and histone fragments on Giemsa staining patterns in chromosomes

Summary In an effort to minimize subjective bias, a classification scheme was devised to assess Giemsa staining patterns obtained with experiments involving acetic acid-alcohol and exogenously applied histone 1 and polypeptides. A single rinse of metaphase preparations with acetic acid-alcohol quantitatively reduced Giemsa dye binding. Acid-alcohol irrversibly changed the conformation of HI and its ability to interfere with trypsin G-banding. Our results suggest that, in addition to protein extraction, acid-alcohol may alter the conformation of acid-insoluble components of metaphase chromosomes. The carboxy-terminal polypeptide (residues 73–212) from NBS cleavage of H1 was an effective inhibitor of Giemsa staining and trypsin G-banding. However, this polypeptide which is preferential for supercoiled DNA was much less efficient in inhibiting Giemsa staining of trypsinized metaphase chromosomes. The molecular consequences of these experiments are discussed.     

dBigH1, a second histone H1 in Drosophila,and the consequences for histone fold nomenclature

Recently, Pérez-Montero and colleagues (Developmental cell, 26: 578–590, 2013) described the occurrence of a new histone H1 variant (dBigH1) in Drosophila. The presence of unusual acidic amino acid patches at the N-terminal end of dBigH1 is in contrast to the arginine patches that exist at the N- and C-terminal domains of other histone H1-related proteins found in the sperm of some organisms. This departure from the strictly lysine-rich composition of the somatic histone H1 raises a question about the true definition of its protein members. Their minimal essential requirements appear to be the presence of a lysine- and alanine–rich, intrinsically disordered C-terminal domain, with a highly helicogenic potential upon binding to the linker DNA regions of chromatin. In metazoans, specific targeting of these regions is further achieved by a linker histone fold domain (LHFD), distinctively different from the characteristic core histone fold domain (CHFD) of the nucleosome core histones.     

dBigH1, a second histone H1 in Drosophila,and the consequences for histone fold nomenclature

Recently, Pérez-Montero and colleagues (Developmental cell, 26: 578–590, 2013) described the occurrence of a new histone H1 variant (dBigH1) in Drosophila. The presence of unusual acidic amino acid patches at the N-terminal end of dBigH1 is in contrast to the arginine patches that exist at the N- and C-terminal domains of other histone H1-related proteins found in the sperm of some organisms. This departure from the strictly lysine-rich composition of the somatic histone H1 raises a question about the true definition of its protein members. Their minimal essential requirements appear to be the presence of a lysine- and alanine–rich, intrinsically disordered C-terminal domain, with a highly helicogenic potential upon binding to the linker DNA regions of chromatin. In metazoans, specific targeting of these regions is further achieved by a linker histone fold domain (LHFD), distinctively different from the characteristic core histone fold domain (CHFD) of the nucleosome core histones.     

Epigenetic regulation by histone methylation and histone variants

Epigenetics is the study of heritable changes in gene expression that are not mediated at the DNA sequence level. Molecular mechanisms that mediate epigenetic regulation include DNA methylation and chromatin/histone modifications. With the identification of key histone-modifying enzymes, the biological functions of many histone posttranslational modifications are now beginning to be elucidated. Histone methylation, in particular, plays critical roles in many epigenetic phenomena. In this review, we provide an overview of recent findings that shape the current paradigms regarding the roles of histone methylation and histone variants in heterochromatin assembly and the maintenance of the boundaries between heterochromatin and euchromatin. We also highlight some of the enzymes that mediate histone methylation and discuss the stability and inheritance of this modification.     

Sodium arsenite modulates histone acetylation, histone deacetylase activity and HMGN protein dynamics in human cells

Extensive epidemiological data indicate that inorganic arsenic is associated with several types of human cancer. Nevertheless, the underlying mechanisms are poorly understood. Among its mode of action are the alterations on DNA methylation, which provoke aberrant gene expression. However, beyond DNA methylation, little is known about arsenic’s effects on chromatin. In this study, we investigated the effects of sodium arsenite (NaAsO₂) on global histone modifications and nucleosome-associated proteins. Our findings revealed that NaAsO₂ exposure significantly increases global histone acetylation. This effect was related to the inhibition of histone deacetylase (HDAC) activity because NaAsO₂ was able to inhibit HDACs comparable to the well-known HDAC inhibitor trichostatin A (TSA). Furthermore, analyses of the dynamic properties of the nucleosome-associated high mobility group N proteins demonstrate that NaAsO₂ elevates their mobility. Thus, our data suggest that NaAsO₂ induces chromatin opening by histone hyperacetylation due to HDAC inhibition and increase of the mobility of nucleosome-associated proteins. As the chromatin compaction is crucial for the regulation of gene expression as well as for genome stability, we propose that chromatin opening by NaAsO₂ may play a significant role to impart its genotoxic effects. Tzutzuy Ramirez and Jan Brocher contributed equally.     

DNA methylation, histone H3 methylation, and histone H4 acetylation in the genome of a crustacean.

In this work, we used antibodies against histone H3 trimethylated at lysine 9 (H3K9m3); against histone H4 acetylated at lysines 5, 8, 12, and 16 (H4ac); and against DNA methylated at 5C cytosine (m5C) to study the presence and distribution of these markers in the genome of the isopod crustacean Asellus aquaticus. The use of these 3 antibodies to immunolabel spermatogonial metaphases yields reproducible patterns on the chromosomes of this crustacean. The X and Y chromosomes present an identical banding pattern with each of the antibodies. The heterochromatic telomeric regions and the centromeric regions are rich in H3K9m3, but depleted in m5C and H4ac. Thus, m5C does not seem to be required to stabilize the silence of these regions in this organism.     

H 1 histone and histone variants in Trypanosoma cruzi

Trypanosoma cruzi chromatin is not condensed in chromosomes during mitosis. In previous studies a characteristic H 1 was not found in SDS or in acid-urea-PAGE. Consequently, it was proposed that the particular behavior of T. cruzi chromatin in dividing cells was due to the absence of an H 1 histone. In the present work, histones from this parasite were systematically characterized by spectrofluorometric analysis, amino acid composition, PAGE in one and in two dimensions, differential extraction with PCA and TCA, immunological cross-reactivity with antisera, and immunoblotting. We conclude that T. cruzi contains all five histones, H 1 presenting solubility and immunological properties similar to those in other species, but with a particular electrophoretic mobility in Triton-PAGE. Thus an explanation other than the absence of H 1 should be offered in order to understand the behavior of T. cruzi chromatin during mitosis. Moreover, histone variants were described by two-dimensional PAGE. The presence of histone variants suggests that they may participate in the regulation of cell proliferation and differentiation of this parasite, as it has been postulated for higher eukaryotes.     

Structure, mechanism, and inhibition of histone deacetylases and related metalloenzymes

Metal-dependent histone deacetylases (HDACs) catalyze the hydrolysis of acetyl-L-lysine side chains in histone and nonhistone proteins to yield l-lysine and acetate. This chemistry plays a critical role in the regulation of numerous biological processes. Aberrant HDAC activity is implicated in various diseases, and HDACs are validated targets for drug design. Two HDAC inhibitors are currently approved for cancer chemotherapy, and other inhibitors are in clinical trials. To date, X-ray crystal structures are available for four human HDACs (2, 4, 7, and 8) and three HDAC-related deacetylases from bacteria (histone deacetylase-like protein (HDLP); histone deacetylase-like amidohydrolase (HDAH); acetylpolyamine amidohydrolase (APAH)). Structural comparisons among these enzymes reveal a conserved constellation of active site residues, suggesting a common mechanism for the metal-dependent hydrolysis of acetylated substrates. Structural analyses of HDACs and HDAC-related deacetylases guide the design of tight-binding inhibitors, and future prospects for developing isozyme-specific inhibitors are quite promising.     

CTCF, cohesin, and histone variants: connecting the genome

During the last decades our view of the genome organization has changed. We moved from a linear view to a looped view of the genome. It is now well established that inter- and intra-connections occur between chromosomes and play a major role in gene regulations. These interconnections are mainly orchestrated by the CTCF protein, which is also known as the "master weaver" of the genome. Recent advances in sequencing and genome-wide studies revealed that CTCF binds to DNA at thousands of sites within the human genome, providing the possibility to form thousands of genomic connection hubs. Strikingly, two histone variants, namely H2A.Z and H3.3, strongly co-localize at CTCF binding sites. In this article, we will review the recent advances in CTCF biology and discuss the role of histone variants H2A.Z and H3.3 at CTCF binding sites.