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The distribution of cohesin in the mouse genome depends on CTCF, transcription and the cohesin release factor Wapl. Cohesin distribution in mammalian genome Cohesin and CTCF are known to spatially organize mammalian genomes into chromatin loops and topologically associated domains. CTCF binds to specific DNA sequences, but it is unclear how cohesin is recruited to these sites. Here, Jan-Michael Peters and colleagues show that the distribution of cohesin in the mouse genome depends on CTCF, transcription and the cohesin-release factor Wapl. In the absence of CTCF, cohesin accumulates at the transcription start sites of active genes, which are bound by the cohesion-loading complex. In the absence of both CTCF and Wapl, cohesin accumulates at the 3′ end of active genes. The authors propose that cohesin is loaded onto DNA at sites that are distinct from its final binding sites and can be translocated by transcription until it either encounters CTCF bound to DNA or is released by Wapl. A mechanism of transcription-mediated cohesin translocation could allow the extrusion of chromatin loops. Mammalian genomes are spatially organized by CCCTC-binding factor (CTCF) and cohesin into chromatin loops 1 , 2 and topologically associated domains 3 , 4 , 5 , 6 , which have important roles in gene regulation 1 , 2 , 4 , 5 , 7 and recombination 7 , 8 , 9 . By binding to specific sequences 10 , CTCF defines contact points for cohesin-mediated long-range chromosomal cis -interactions 1 , 2 , 4 , 5 , 6 , 7 , 11 . Cohesin is also present at these sites 12 , 13 , but has been proposed to be loaded onto DNA elsewhere 14 , 15 and to extrude chromatin loops until it encounters CTCF bound to DNA 16 , 17 , 18 , 19 . How cohesin is recruited to CTCF sites, according to this or other models, is unknown. Here we show that the distribution of cohesin in the mouse genome depends on transcription, CTCF and the cohesin release factor Wings apart-like (Wapl). In CTCF-depleted fibroblasts, cohesin cannot be properly recruited to CTCF sites but instead accumulates at transcription start sites of active genes, where the cohesin-loading complex is located 14 , 15 . In the absence of both CTCF and Wapl, cohesin accumulates in up to 70 kilobase-long regions at 3′-ends of active genes, in particular if these converge on each other. Changing gene expression modulates the position of these ‘cohesin islands’. These findings indicate that transcription can relocate mammalian cohesin over long distances on DNA, as previously reported for yeast cohesin 20 , 21 , 22 , 23 , that this translocation contributes to positioning cohesin at CTCF sites, and that active genes can be freed from cohesin either by transcription-mediated translocation or by Wapl-mediated release.

The deacetylase enzyme HDAC8 is identified as a crucial regulator of cohesin in humans, and loss-of-function mutations in the HDAC8 gene are found in patients with Cornelia de Lange syndrome. HDAC defects in Cornelia de Lange syndrome The cohesin complex is important for sister-chromatid cohesion and chromosome segregation, as well as for other chromosomal processes such as gene expression and DNA repair. Cornelia de Lange syndrome (CdLS) is a human developmental disorder associated with significant cognitive deficits and structural birth defects. It is caused by mutations in genes that encode subunits of the cohesin complex or the cohesin regulator NIPL. Here, a deacetylase enzyme, HDAC8, is shown to be a critical regulator of cohesin in human cells, and loss-of-function HDAC8 mutations are found in six patients with CdLS from different families. Cornelia de Lange syndrome (CdLS) is a dominantly inherited congenital malformation disorder, caused by mutations in the cohesin-loading protein NIPBL 1 , 2 for nearly 60% of individuals with classical CdLS 3 , 4 , 5 , and by mutations in the core cohesin components SMC1A (∼5%) and SMC3 (<1%) for a smaller fraction of probands 6 , 7 . In humans, the multisubunit complex cohesin is made up of SMC1, SMC3, RAD21 and a STAG protein. These form a ring structure that is proposed to encircle sister chromatids to mediate sister chromatid cohesion 8 and also has key roles in gene regulation 9 . SMC3 is acetylated during S-phase to establish cohesiveness of chromatin-loaded cohesin 10 , 11 , 12 , 13 , and in yeast, the class I histone deacetylase Hos1 deacetylates SMC3 during anaphase 14 , 15 , 16 . Here we identify HDAC8 as the vertebrate SMC3 deacetylase, as well as loss-of-function HDAC8 mutations in six CdLS probands. Loss of HDAC8 activity results in increased SMC3 acetylation and inefficient dissolution of the ‘used’ cohesin complex released from chromatin in both prophase and anaphase. SMC3 with retained acetylation is loaded onto chromatin, and chromatin immunoprecipitation sequencing analysis demonstrates decreased occupancy of cohesin localization sites that results in a consistent pattern of altered transcription seen in CdLS cell lines with either NIPBL or HDAC8 mutations.

The nuclear receptors REV-ERB-α and REV-ERB-β are indispensible for the coordination of circadian rhythm and metabolism; mice without these nuclear receptors show disrupted circadian expression of core circadian clock and lipid homeostatic gene networks. Adjusting the metabolic clock Metabolic processes need to run like clockwork to prevent disease. Core clock proteins drive these rhythms, and the nuclear receptors REV-ERB-α and REV-ERB-β have a central role in regulating the expression of clock genes. Solt et al . report the identification of potent synthetic REV-ERB agonists, termed SR9011 and SR9009, which can alter the circadian expression of core clock genes in the hypothalami of mice. This is shown to alter the expression of metabolic genes in liver, skeletal-muscle and adipose tissue, and results in increased energy expenditure by the mice. The REV-ERB agonists reduce fat mass in diet-induced obese mice and improve dyslipidaemia and hyperglycaemia. These results suggest that synthetic REV-ERB ligands are promising candidates for the treatment of metabolic diseases. Cho et al . present genetic evidence that REV-ERB-α and REV-ERB-β are indispensible for the coordination of circadian rhythm and metabolism. Mice without REV-ERBs show disrupted expression of clock and lipid homeostatic gene networks. They have altered circadian wheel-running behaviour and deregulated lipid metabolism. These data ally REV-ERB-α and REV-ERB-β with PER, CRY and other components of the principal feedback loop that drives circadian expression. The circadian clock acts at the genomic level to coordinate internal behavioural and physiological rhythms via the CLOCK–BMAL1 transcriptional heterodimer. Although the nuclear receptors REV-ERB-α and REV-ERB-β have been proposed to form an accessory feedback loop that contributes to clock function 1 , 2 , their precise roles and importance remain unresolved. To establish their regulatory potential, we determined the genome-wide cis -acting targets (cistromes) of both REV-ERB isoforms in murine liver, which revealed shared recognition at over 50% of their total DNA binding sites and extensive overlap with the master circadian regulator BMAL1. Although REV-ERB-α has been shown to regulate Bmal1 expression directly 1 , 2 , our cistromic analysis reveals a more profound connection between BMAL1 and the REV-ERB-α and REV-ERB-β genomic regulatory circuits than was previously suspected. Genes within the intersection of the BMAL1, REV-ERB-α and REV-ERB-β cistromes are highly enriched for both clock and metabolic functions. As predicted by the cistromic analysis, dual depletion of Rev-erb-α and Rev-erb-β function by creating double-knockout mice profoundly disrupted circadian expression of core circadian clock and lipid homeostatic gene networks. As a result, double-knockout mice show markedly altered circadian wheel-running behaviour and deregulated lipid metabolism. These data now unite REV-ERB-α and REV-ERB-β with PER, CRY and other components of the principal feedback loop that drives circadian expression and indicate a more integral mechanism for the coordination of circadian rhythm and metabolism.

Postnatal growth of mammalian oocytes is accompanied by a progressive gain of DNA methylation, which is predominantly mediated by DNMT3A, a de novo DNA methyltransferase 1 , 2 . Unlike the genome of sperm and most somatic cells, the oocyte genome is hypomethylated in transcriptionally inert regions 2 – 4 . However, how such a unique feature of the oocyte methylome is determined and its contribution to the developmental competence of the early embryo remains largely unknown. Here we demonstrate the importance of Stella, a factor essential for female fertility 5 – 7 , in shaping the oocyte methylome in mice. Oocytes that lack Stella acquire excessive DNA methylation at the genome-wide level, including in the promoters of inactive genes. Such aberrant hypermethylation is partially inherited by two-cell-stage embryos and impairs zygotic genome activation. Mechanistically, the loss of Stella leads to ectopic nuclear accumulation of the DNA methylation regulator UHRF1 8 , 9 , which results in the mislocalization of maintenance DNA methyltransferase DNMT1 in the nucleus. Genetic analysis confirmed the primary role of UHRF1 and DNMT1 in generating the aberrant DNA methylome in Stella-deficient oocytes. Stella therefore safeguards the unique oocyte epigenome by preventing aberrant de novo DNA methylation mediated by DNMT1 and UHRF1. Stella, a factor essential for female fertility, protects the oocyte methylome in mice by suppressing de novo DNA methylation mediated by the DNA methyltransferase DNMT1.

Pathogens use virulence factors to inhibit the immune system 1 . The guard hypothesis 2 , 3 postulates that hosts monitor (or ‘guard’) critical innate immune pathways such that their disruption by virulence factors provokes a secondary immune response 1 . Here we describe a ‘self-guarded’ immune pathway in human monocytes, in which guarding and guarded functions are combined in one protein. We find that this pathway is triggered by ICP0, a key virulence factor of herpes simplex virus type 1, resulting in robust induction of anti-viral type I interferon (IFN). Notably, induction of IFN by ICP0 is independent of canonical immune pathways and the IRF3 and IRF7 transcription factors. A CRISPR screen identified the ICP0 target MORC3 4 as an essential negative regulator of IFN. Loss of MORC3 recapitulates the IRF3- and IRF7-independent IFN response induced by ICP0. Mechanistically, ICP0 degrades MORC3, which leads to de-repression of a MORC3-regulated DNA element (MRE) adjacent to the IFNB1 locus. The MRE is required in cis for IFNB1 induction by the MORC3 pathway, but is not required for canonical IFN-inducing pathways. As well as repressing the MRE to regulate IFNB1 , MORC3 is also a direct restriction factor of HSV-1 5 . Our results thus suggest a model in which the primary anti-viral function of MORC3 is self-guarded by its secondary IFN-repressing function—thus, a virus that degrades MORC3 to avoid its primary anti-viral function will unleash the secondary anti-viral IFN response. MORC3 is revealed as an essential negative regulator of the anti-viral interferon response that functions in an innate immune pathway that detects viral virulence factors. 

Plant immune responses mediated by the hormone jasmonoyl-L-isoleucine (JA-Ile) are metabolically costly and often linked to reduced growth. Although it is known that JA-Ile activates defense responses by triggering the degradation of JASMONATE ZIM DOMAIN (JAZ) transcriptional repressor proteins, expansion of the JAZ gene family in vascular plants has hampered efforts to understand how this hormone impacts growth and other physiological tasks over the course of ontogeny. Here, we combined mutations within the 13-member Arabidopsis JAZ gene family to investigate the effects of chronic JAZ deficiency on growth, defense, and reproductive output. A higher-order mutant (jaz decuple, jazD) defective in 10 JAZ genes (JAZ1–7, -9, -10, and -13) exhibited robust resistance to insect herbivores and fungal pathogens, which was accompanied by slow vegetative growth and poor reproductive performance. Metabolic phenotypes of jazD discerned from global transcript and protein profiling were indicative of elevated carbon partitioning to amino acid-, protein-, and endoplasmic reticulum body-based defenses controlled by the JA-Ile and ethylene branches of immunity. Resource allocation to a strong defense sink in jazD leaves was associated with increased respiration and hallmarks of carbon starvation but no overt changes in photosynthetic rate. Depletion of the remaining JAZ repressors in jazD further exaggerated growth stunting, nearly abolished seed production and, under extreme conditions, caused spreading necrotic lesions and tissue death. Our results demonstrate that JAZ proteins promote growth and reproductive success at least in part by preventing catastrophic metabolic effects of an unrestrained immune response.

FOXP1 syndrome caused by haploinsufficiency of the forkhead box protein P1 (FOXP1) gene is a neurodevelopmental disorder that manifests motor dysfunction, intellectual disability, autism, and language impairment. In this study, we used a Foxp1 +/− mouse model to address whether cognitive and motor deficits in FOXP1 syndrome are associated with mitochondrial dysfunction and oxidative stress. Here, we show that genes with a role in mitochondrial biogenesis and dynamics (e.g., Foxo1, Pgc-1α, Tfam, Opa1, and Drp1) were dysregulated in the striatum of Foxp1 +/− mice at different postnatal stages. Furthermore, these animals exhibit a reduced mitochondrial membrane potential and complex I activity, as well as decreased expression of the antioxidants superoxide dismutase 2 (Sod2) and glutathione (GSH), resulting in increased oxidative stress and lipid peroxidation. These features can explain the reduced neurite branching, learning and memory, endurance, and motor coordination that we observed in these animals. Taken together, we provide strong evidence of mitochondrial dysfunction in Foxp1 +/− mice, suggesting that insufficient energy supply and excessive oxidative stress underlie the cognitive and motor impairment in FOXP1 deficiency.

Bone-resorbing osteoclasts significantly contribute to osteoporosis and bone metastases of cancer. MicroRNAs play important roles in physiology and disease, and present tremendous therapeutic potential. Nonetheless, how microRNAs regulate skeletal biology is underexplored. Here we identify miR-34a as a novel and critical suppressor of osteoclastogenesis, bone resorption and the bone metastatic niche. miR-34a is downregulated during osteoclast differentiation. Osteoclastic miR-34a-overexpressing transgenic mice exhibit lower bone resorption and higher bone mass. Conversely, miR-34a knockout and heterozygous mice exhibit elevated bone resorption and reduced bone mass. Consequently, ovariectomy-induced osteoporosis, as well as bone metastasis of breast and skin cancers, are diminished in osteoclastic miR-34a transgenic mice, and can be effectively attenuated by miR-34a nanoparticle treatment. Mechanistically, we identify transforming growth factor-β-induced factor 2 (Tgif2) as an essential direct miR-34a target that is pro-osteoclastogenic. Tgif2 deletion reduces bone resorption and abolishes miR-34a regulation. Together, using mouse genetic, pharmacological and disease models, we reveal miR-34a as a key osteoclast suppressor and a potential therapeutic strategy to confer skeletal protection and ameliorate bone metastasis of cancers.

Human neurons are functional over an entire lifetime, yet the mechanisms that preserve function and protect against neurodegeneration during ageing are unknown. Here we show that induction of the repressor element 1-silencing transcription factor (REST; also known as neuron-restrictive silencer factor, NRSF) is a universal feature of normal ageing in human cortical and hippocampal neurons. REST is lost, however, in mild cognitive impairment and Alzheimer’s disease. Chromatin immunoprecipitation with deep sequencing and expression analysis show that REST represses genes that promote cell death and Alzheimer’s disease pathology, and induces the expression of stress response genes. Moreover, REST potently protects neurons from oxidative stress and amyloid β-protein toxicity, and conditional deletion of REST in the mouse brain leads to age-related neurodegeneration. A functional orthologue of REST, Caenorhabditis elegans SPR-4, also protects against oxidative stress and amyloid β-protein toxicity. During normal ageing, REST is induced in part by cell non-autonomous Wnt signalling. However, in Alzheimer’s disease, frontotemporal dementia and dementia with Lewy bodies, REST is lost from the nucleus and appears in autophagosomes together with pathological misfolded proteins. Finally, REST levels during ageing are closely correlated with cognitive preservation and longevity. Thus, the activation state of REST may distinguish neuroprotection from neurodegeneration in the ageing brain. REST, a developmental regulator, is markedly induced in human neurons during ageing but is lost in Alzheimer’s disease; REST represses genes that promote neurodegeneration, is neuroprotective in animal models, and is associated with cognitive preservation and longevity in humans. REST protein counters neurodegeneration Age is the biggest risk factor for neurodegenerative disease. But why do some age with cognitive function intact, yet others decline and develop Alzheimer's disease? Here Bruce Yankner and colleagues show that during ageing, a protein known as REST (repressor element 1-silencing transcription factor, also called NRSF) is increasingly expressed in human cortical and hippocampal neurons. REST levels are strongly correlated with cognitive preservation and longevity. REST represses genes that promote cell death and Alzheimer's disease pathology and induces those that mediate the stress response. Moreover, REST protects neurons from oxidative stress and amyloid β-protein toxicity. Deleting REST from the mouse brain results in age-related neuronal cell death. And, in humans with mild cognitive impairment or Alzheimer's disease, REST is excluded from the nucleus in neurons, and this exclusion is associated with autophagy and misfolded proteins. This work suggests that the activation state of REST may distinguish neuroprotection from neurodegeneration in the ageing brain.

Oncogenic levels of MYC, the deregulation of which is implicated in many human tumours, are shown to establish a dependence on ARK5, offering insights into potential therapeutic strategies. Alternative target in MYC-related cancers Deregulated expression of the MYC oncogene is characteristic of many cancers. In an RNA interference screen designed to uncover genes that are crucial for cell survival specifically in MYC-driven tumour cells, Martin Eilers and colleagues have identified the kinase ARK5 as an important factor in MYC-mediated transformation. This is attributable to metabolic stress in MYC-expressing cells in which ARK5 is shown to be crucial for metabolic homeostasis and hence cell survival. ARK5 is also crucial in a MYC-driven mouse model of liver cancer. As a transcriptional regulator, MYC is difficult to target therapeutically, so ARK5 might prove to be an alternative target. Deregulated expression of the MYC oncoprotein contributes to the genesis of many human tumours, yet strategies to exploit this for a rational tumour therapy are scarce. MYC promotes cell growth and proliferation, and alters cellular metabolism to enhance the provision of precursors for phospholipids and cellular macromolecules 1 , 2 . Here we show in human and murine cell lines that oncogenic levels of MYC establish a dependence on AMPK-related kinase 5 (ARK5; also known as NUAK1) for maintaining metabolic homeostasis and for cell survival. ARK5 is an upstream regulator of AMPK and limits protein synthesis via inhibition of the mammalian target of rapamycin 1 (mTORC1) signalling pathway. ARK5 also maintains expression of mitochondrial respiratory chain complexes and respiratory capacity, which is required for efficient glutamine metabolism. Inhibition of ARK5 leads to a collapse of cellular ATP levels in cells expressing deregulated MYC, inducing multiple pro-apoptotic responses as a secondary consequence. Depletion of ARK5 prolongs survival in MYC-driven mouse models of hepatocellular carcinoma, demonstrating that targeting cellular energy homeostasis is a valid therapeutic strategy to eliminate tumour cells that express deregulated MYC.