Human histone demethylase LSD1 reads the histone code

Human histone demethylase LSD1 is a flavin-dependent amine oxidase that catalyzes the specific removal of methyl groups from mono- and dimethylated Lys4 of histone H3. The N-terminal tail of H3 is subject to various covalent modifications, and a fundamental question in LSD1 biology is how these epigenetic marks affect the demethylase activity. We show that LSD1 does not have a strong preference for mono- or dimethylated Lys4 of H3. Substrate recognition is not confined to the residues neighboring Lys4, but it requires a sufficiently long peptide segment consisting of the N-terminal 20 amino acids of H3. Electrostatic interactions are an important factor in protein-substrate recognition, as indicated by the high sensitivity of Km to ionic strength. We have probed LSD1 for its ability to demethylate Lys4 in presence of a second modification on the same peptide substrate. Methylation of Lys9 does not affect enzyme catalysis. Conversely, Lys9 acetylation causes an almost 6-fold increase in the Km value, whereas phosphorylation of Ser10 totally abolishes activity. LSD1 is inhibited by a demethylated peptide with an inhibition constant of 1.8 microM, suggesting that LSD1 can bind to H3 independently of Lys4 methylation. LSD1 is a chromatin-modifying enzyme, which is able to read different epigenetic marks on the histone N-terminal tail and can serve as a docking module for the stabilization of the associated corepressor complex(es) on chromatin.     

Plk1 puts a (Has)pin on the mitotic histone code

Haspin is an atypical mitotic kinase that phosphorylates histone H3 on threonine 3 (H3T3), which is required to target Aurora B to centromeres. However, how Haspin is activated upon mitotic entry remained unknown. Two independent studies, published in Molecular Cell and in this issue of EMBO reports by Ghenoiu et al [1] and Zhou et al [2], respectively, now show that Plk1 is responsible for Haspin activation as a H3T3 kinase. These results shed light on the spatiotemporal regulation of Aurora B to ensure mitotic fidelity.     

Structural insights to how mammalian capping enzyme reads the CTD code

Physical interaction between the phosphorylated RNA polymerase II carboxyl-terminal domain (CTD) and cellular capping enzymes is required for efficient formation of the 5' mRNA cap, the first modification of nascent mRNA. Here, we report the crystal structure of the RNA guanylyltransferase component of mammalian capping enzyme (Mce) bound to a CTD phosphopeptide. The CTD adopts an extended β-like conformation that docks Tyr1 and Ser5-PO(4) onto the Mce nucleotidyltransferase domain. Structure-guided mutational analysis verified that the Mce-CTD interface is a tunable determinant of CTD binding and stimulation of guanylyltransferase activity, and of Mce function in?vivo. The location and composition of the CTD binding site on mammalian capping enzyme is distinct from that of a yeast capping enzyme that recognizes the same CTD primary structure. Thus, capping enzymes from different taxa have evolved different strategies to read the CTD code.     

Cellular memory and the histone code

The histone tails on the nucleosome surface are subject to enzyme-catalyzed modifications that may, singly or in combination, form a code specifying patterns of gene expression. Recent papers provide insights into how a combinatorial code might be set and read. They show how modification of one residue can influence that of another, even when they are located on different histones, and how modifications at specific genomic locations might be perpetuated on newly assembled chromatin.     

Cracking the enigmatic linker histone code

Recently, the existence of a 'histone code' has been proposed to explain the link between the covalent chemical modification of histone proteins and the epigenetic regulation of gene activity. Although the role of the four 'core' histones has been extensively studied, little is known about the involvement of the linker histone, histone H1 and its variants, in this code. For many years, few sites of chemical modification had been mapped in linker histones, but this has changed recently with the use of functional proteomic techniques, principally mass spectrometry, to characterize these modifications. The functionality of many of these sites, however, remains to be determined.     

The case for Survivin as mitotic regulator

Survivin has been proposed to inhibit apoptosis and to regulate cell division. However, controversy still exists as to whether Survivin can indeed execute these distinct functions and if Survivin somehow coordinates apoptosis and (abnormal) cell division. Recent evidence has demonstrated that Survivin acts as a subunit of the chromosomal passenger complex, which is essential for proper chromosome segregation and cytokinesis. Within this complex, the mitotic kinase Aurora B acts as the enzymatic core, whereas Survivin dictates chromosomal passenger complex localization. This function of Survivin appears to be conserved throughout evolution. Although these findings do not exclude a role for Survivin as apoptosis inhibitor, they make a very strong case for Survivin as mitotic regulator.     

Regulated nucleosome mobility and the histone code

Post-translational modifications of the histone tails are correlated with distinct chromatin states that regulate access to DNA. Recent proteomic analyses have revealed several new modifications in the globular nucleosome core, many of which lie at the histone-DNA interface. We interpret these modifications in light of previously published data and propose a new and testable model for how cells implement the histone code by modulating nucleosome dynamics.     

How does the histone code work?

Patterns of histone post-translational modifications correlate with distinct chromosomal states that regulate access to DNA, leading to the histone-code hypothesis. However, it is not clear how modification of flexible histone tails leads to changes in nucleosome dynamics and, thus, chromatin structure. The recent discovery that, like the flexible histone tails, the structured globular domain of the nucleosome core particle is also extensively modified adds a new and exciting dimension to the histone-code hypothesis, and calls for the re-examination of current models for the epigenetic regulation of chromatin structure. Here, we review these findings and other recent studies that suggest the structured globular domain of the nucleosome core particle plays a key role regulating chromatin dynamics.     

Cracking the survival code: Autophagy-related histone modifications

Modifications of histones, the chief protein components of the chromatin, have emerged as critical regulators of life and death. While the “apoptotic histone code” came to light a few years ago, accumulating evidence indicates that autophagy, a cell survival pathway, is also heavily regulated by histone-modifying proteins. In this review we describe the emerging “autophagic histone code” and the role of histone modifications in the cellular life vs. death decision.     

Breaking the histone code with quantitative mass spectrometry

Histone post-translational modifications (PTMs) comprise one of the most intricate nuclear signaling networks that govern gene expression in a long-term and dynamic fashion. These PTMs are considered to be 'epigenetic' or heritable from one cell generation to the next and help establish genomic expression patterns. While much of the analyses of histones have historically been performed using site-specific antibodies, these methods are replete with technical obstacles (i.e., cross-reactivity and epitope occlusion). Mass spectrometry-based proteomics has begun to play a significant role in the interrogation of histone PTMs, revealing many new aspects of these modifications that cannot be easily determined with standard biological approaches. Here, we review the accomplishments of mass spectrometry in the histone field, and outline the future roadblocks that must be overcome for mass spectrometry-based proteomics to become the method of choice for chromatin biologists.     

植物组蛋白密码研究进展

组蛋白密码学说提出后,大大丰富了人们对遗传信息的认识,使得组蛋白修饰的研究备受瞩目.近年来包括组蛋白乙酰化、甲基化、磷酸化、泛素化等在内的多种共价化学修饰在植物生长发育过程中参与基因表达调控的作用机制逐渐被阐明,组蛋白各种修饰之间的相互关系也有了进一步的认识.随着研究的深入,将加快组蛋白密码的破译,帮助我们认清植物基因表达调控的本质.