Gene silencing by heterochromatin is proposed to occur in part from the ability of HP1 proteins to spread across large regions of the genome, compact the underlying chromatin and recruit repressive activities1–3. Here we identify a new property of the human HP1α protein: the ability to form phase-separated droplets. While unmodified HP1α is soluble, either phosphorylation of its N-terminal extension or DNA binding promotes the formation of phase-separated droplets. Phosphorylation driven phase-separation can be promoted or reversed by specific HP1α ligands. Known components of heterochromatin such as nucleosomes and DNA preferentially partition into the HP1α droplets but other molecules such as the transcription factor TFIIB show no preference. Using single-molecule DNA curtains we find that unmodified and phosphorylated HP1α induce rapid compaction of DNA strands into puncta, though with different characteristics. We show by direct protein delivery into mammalian cells that an HP1α mutant incapable of phase separation in vitro forms smaller and fewer nuclear puncta than phosphorylated HP1α. These findings suggest that heterochromatin mediated gene silencing may occur in part through sequestration of compacted chromatin in phase-separated HP1 droplets, which are dissolved or formed by specific ligands based on nuclear context.
SummaryThe infectivity and persistence of Mycobacterium tuberculosis requires the utilization of host cell cholesterol. We have examined the specific role of cytochrome P450 CYP125A1 in the cholesterol degradation pathway using genetic, biochemical and highresolution mass spectrometric approaches. The analysis of lipid profiles from cells grown on cholesterol revealed that CYP125A1 is required to incorporate the cholesterol side-chain carbon atoms into cellular lipids, as evidenced by an increase in the mass of the methyl-branched phthiocerol dimycocerosates. We observed that cholesterol-exposed cells lacking CYP125A1 accumulate cholest-4-en-3-one, suggesting that this is a physiological substrate for this enzyme. Reconstitution of enzymatic activity with spinach ferredoxin and ferredoxin reductase revealed that recombinant CYP125A1 indeed binds both cholest-4-en-3-one and cholesterol, efficiently hydroxylates both of them at C-27, and then further oxidizes 27-hydroxycholest-4-en-3-one to cholest-4-en-3-one-27-oic acid. We determined the X-ray structure of cholest-4-en-3-one-bound CYP125A1 at a resolution of 1.58 Å. CYP125A1 is essential for growth of CDC1551 in media containing cholesterol or cholest-4-en-3-one. In its absence, the latter compound is toxic for both CDC1551 and H37Rv when added with glycerol as a second carbon source. CYP125A1 is a key enzyme in cholesterol metabolism and plays a crucial role in circumventing the deleterious effect of cholest-4-en-3-one.
Mycobacterium tuberculosis (Mtb) is an intracellular pathogen that infects 10 million worldwide and kills 2 million people every year. The uptake and utilization of nutrients by Mtb within the host cell is still poorly understood, although lipids play an important role in Mtb persistence. The recent identification of a large regulon of cholesterol catabolic genes suggests that Mtb can use host sterol for infection and persistence. In this review, we report on recent progress in elucidation of the Mtb cholesterol catabolic reactions and their potential utility as targets for tuberculosis therapeutic agents.
One challenge to the development of new antitubercular drugs is the existence of multiple virulent strains that differ genetically. We and others have recently demonstrated that CYP125A1 is a steroid C 26 -monooxygenase that plays a key role in cholesterol catabolism in Mycobacterium tuberculosis CDC1551 but, unexpectedly, not in the M. tuberculosis H37Rv strain. This discrepancy suggests that the H37Rv strain possesses compensatory activities. Here, we examined the roles in cholesterol metabolism of two other cytochrome P450 enzymes, CYP124A1 and CYP142A1. In vitro analysis, including comparisons of the binding affinities and catalytic efficiencies, demonstrated that CYP142A1, but not CYP124A1, can support the growth of H37Rv cells on cholesterol in the absence of cyp125A1. All three enzymes can oxidize the sterol side chain to the carboxylic acid state by sequential oxidation to the alcohol, aldehyde, and acid. Interestingly, CYP125A1 generates oxidized sterols of the (25S)-26-hydroxy configuration, whereas the opposite 25R stereochemistry is obtained with CYP124A1 and CYP142A1. Western blot analysis indicated that CYP124A1 was not detectably expressed in either the H37Rv or CDC1551 strains, whereas CYP142A1 was found in H37Rv but not CDC1551. Genetic complementation of CDC1551 ⌬cyp125A1 cells with the cyp124A1 or cyp142A1 genes revealed that the latter can fully rescue the growth defect on cholesterol, whereas cells overexpressing CYP124A1 grow poorly and accumulate cholest-4-en-3-one. Our data clearly establish a functional redundancy in the essential C 26 -monooxygenase activity of M. tuberculosis and validate CYP125A1 and CYP142A1 as possible drug targets.Mycobacterium tuberculosis is the causative agent of human tubercular infection (tuberculosis) that, even today, poses a great threat to global human health. More than two billion people (a third of the world population) are infected latently with the bacterium, and of those individuals, ϳ10% will develop active tuberculosis infections during their lifetime. Currently, more than two million lives are claimed annually due to active M. tuberculosis infections (1). Among first world countries, the spread of M. tuberculosis has been kept mostly under control, but there has been a resurgence in developing countries in large part due to the emergence of multidrug-resistant bacterial strains that make the traditional frontline antibiotics less effective (2). Efforts continue on many fronts to understand this complex pathogen with a focus on identification of new drug targets.To proliferate within the macrophages, M. tuberculosis cells undergo a shift in metabolism from using carbohydrates to primarily utilizing host lipids (3-5). Sequencing of the M. tuberculosis genome revealed at least 250 genes predicted to be involved in lipid metabolism (6). A cholesterol catabolism cluster of 51 genes was recently identified in the genome of the M. tuberculosis-related actinomycete Rhodococcus jostti RHA1 (7). This region corresponds to the 82-gene cluster of M. tuberculos...
Mycobacterium tuberculosis (Mtb) produces a variety of methylbranched lipids that serve important functions, including modulating the immune response during pathogenesis and contributing to a robust cell wall that is impermeable to many chemical agents. Here, we report characterization of Mtb CYP124 (Rv2266) that includes demonstration of preferential oxidation of methylbranched lipids. Spectrophotometric titrations and analysis of reaction products indicate that CYP124 tightly binds and hydroxylates these substrates at the chemically disfavored -position. We also report X-ray crystal structures of the ligand-free and phytanic acid-bound protein at a resolution of 1.5 Å and 2.1 Å, respectively, which provide structural insights into a cytochrome P450 with predominant -hydroxylase activity. The structures of ligand-free and substrate-bound CYP124 reveal several differences induced by substrate binding, including reorganization of the I helix and closure of the active site by elements of the F, G, and D helices that bind the substrate and exclude solvent from the hydrophobic active site cavity. The observed regiospecific catalytic activity suggests roles of CYP124 in the physiological oxidation of relevant Mtb methyl-branched lipids. The enzymatic specificity and structures reported here provide a scaffold for the design and testing of specific inhibitors of CYP124.cytochrome P450 ͉ phytanic acid ͉ -hydroxylation ͉ X-ray structure
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