Antonio Adamo scite author profile

Histone demethylase LSD1 regulates transcription by demethylating Lys 4 of histone H3. The crystal structure of the enzyme in complex with CoREST and a substrate-like peptide inhibitor highlights an intricate network of interactions and a folded conformation of the bound peptide. The core of the peptide structure is formed by Arg 2 , Gln 5 , and Ser 10 , which are engaged in specific intramolecular H-bonds. Several charged side chains on the surface of the substrate-binding pocket establish electrostatic interactions with the peptide. The three-dimensional structure predicts that methylated Lys 4 binds in a solvent inaccessible position in front of the flavin cofactor. This geometry is fully consistent with the demethylation reaction being catalyzed through a flavin-mediated oxidation of the substrate amino-methyl group. These features dictate the exquisite substrate specificity of LSD1 and provide a structural framework to explain the fine tuning of its catalytic activity and the active role of CoREST in substrate recognition.Lysine methylation is among the most well characterized histone modifications, and its existence has been known since the early days of chromatin research (1, 2). This type of epigenetic mark provides a huge potential for functional responses in that it can occur in different forms (mono-, di-, and tri-methylation) and on different histone sites, each having a specific physiological meaning. Histone methylation has been long thought to be a low turnover epigenetic mark, but the recent discovery of histone demethylases (3, 4) has challenged this view by demonstrating that histone lysine methylation can be actively and dynamically regulated. Two classes of histone demethylases have been uncovered; the enzymes of the JmjC family use iron as cofactor, whereas lysine-specific demethylase 1 (LSD1) 4 employs FAD as the prosthetic group (5).LSD1 catalyzes the oxidative demethylation of mono-and dimethyl Lys 4 of histone H3, generating hydrogen peroxide and formaldehyde (3, 4). The enzyme is implicated as a key component of distinct co-activator and co-repressor complexes in a surprisingly wide range of cellular processes where it participates in the dynamic transition of transcriptional programs (6). Its catalytic activity is finely tuned by the epigenetic marks present on the H3 N-terminal tail (7) and by other protein partners, such as CoREST, that form a stable complex with the enzyme (8, 9). The three-dimensional structure of LSD1 in its native state (10, 11) and in complex with the LSD1-binding domain of CoREST (12) have revealed that the catalytic center is located in the core of the enzyme main body. A protruding tower domain consisting of two remarkably long helices forms the docking site for the co-repressor protein (Fig. 1A).Here, we describe the structural analysis of LSD1-CoREST bound to a 21-amino acid H3 peptide in which pLys 4 ("p" is for peptide) is mutated to Met. The structural analysis illuminates the molecular properties that enable LSD1 to function as a key transcriptional reg...

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LSD1 regulates the balance between self-renewal and differentiation in human embryonic stem cells

Adamo

et al. 2011

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We identify LSD1 (lysine-specific demethylase 1; also known as KDM1A and AOF2) as a key histone modifier that participates in the maintenance of pluripotency through the regulation of bivalent domains, a chromatin environment present at the regulatory regions of developmental genes that contains both H3K4 di/trimethylation and H3K27 trimethylation marks. LSD1 occupies the promoters of a subset of developmental genes that contain bivalent domains and are co-occupied by OCT4 and NANOG in human embryonic stem cells, where it controls the levels of H3K4 methylation through its demethylase activity. Thus, LSD1 has a role in maintaining the silencing of several developmental genes in human embryonic stem cells by regulating the critical balance between H3K4 and H3K27 methylation at their regulatory regions.

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Alternative Splicing of the Histone Demethylase LSD1/KDM1 Contributes to the Modulation of Neurite Morphogenesis in the Mammalian Nervous System

Zibetti¹,

Adamo²,

Binda³

et al. 2010

J. Neurosci.

146

186

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A variety of chromatin remodeling complexes are thought to orchestrate transcriptional programs that lead neuronal precursors from earliest commitment to terminal differentiation. Here we show that mammalian neurons have a specialized chromatin remodeling enzyme arising from a neurospecific splice variant of LSD1/KDM1, histone lysine specific demethylase 1, whose demethylase activity on Lys4 of histone H3 has been related to gene repression. We found that alternative splicing of LSD1 transcript generates four full-length isoforms from combinatorial retention of two identified exons: the 4 aa exon E8a is internal to the amine oxidase domain, and its inclusion is restricted to the nervous system. Remarkably, the expression of LSD1 splice variants is dynamically regulated throughout cortical development, particularly during perinatal stages, with a progressive increase of LSD1 neurospecific isoforms over the ubiquitous ones. Notably, the same LSD1 splice dynamics can be fairly recapitulated in cultured cortical neurons. Functionally, LSD1 isoforms display in vitro a comparable demethylase activity, yet the inclusion of the sole exon E8a reduces LSD1 repressor activity on a reporter gene. Additional distinction among isoforms is supported by the knockdown of neurospecific variants in cortical neurons resulting in the inhibition of neurite maturation, whereas overexpression of the same variants enhances it. Instead, perturbation of LSD1 isoforms that are devoid of the neurospecific exon elicits no morphogenic effect. Collectively, results demonstrate that the arousal of neuronal LSD1 isoforms pacemakes early neurite morphogenesis, conferring a neurospecific function to LSD1 epigenetic activity.

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7q11.23 dosage-dependent dysregulation in human pluripotent stem cells affects transcriptional programs in disease-relevant lineages

et al. 2014

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Cell reprogramming promises to make characterization of the impact of human genetic variation on health and disease experimentally tractable by enabling the bridging of genotypes to phenotypes in developmentally relevant human cell lineages. Here we apply this paradigm to two disorders caused by symmetrical copy number variations of 7q11.23, which display a striking combination of shared and symmetrically opposite phenotypes--Williams-Beuren syndrome and 7q-microduplication syndrome. Through analysis of transgene-free patient-derived induced pluripotent stem cells and their differentiated derivatives, we find that 7q11.23 dosage imbalance disrupts transcriptional circuits in disease-relevant pathways beginning in the pluripotent state. These alterations are then selectively amplified upon differentiation of the pluripotent cells into disease-relevant lineages. A considerable proportion of this transcriptional dysregulation is specifically caused by dosage imbalances in GTF2I, which encodes a key transcription factor at 7q11.23 that is associated with the LSD1 repressive chromatin complex and silences its dosage-sensitive targets.

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Antonio Adamo

Structural Basis of LSD1-CoREST Selectivity in Histone H3 Recognition

LSD1 regulates the balance between self-renewal and differentiation in human embryonic stem cells

Alternative Splicing of the Histone Demethylase LSD1/KDM1 Contributes to the Modulation of Neurite Morphogenesis in the Mammalian Nervous System

7q11.23 dosage-dependent dysregulation in human pluripotent stem cells affects transcriptional programs in disease-relevant lineages

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