Project description:Declining tissue function and regenerative capacity underlie many chronic diseases. Experimentally establishing the mechanistic basis for such tissue ageing presents substantial challenges, given decades-long timescales and multifactorial origins. Epigenetic alterations have been proposed to have a key aetiological role, but whether they are correlative or causal remains a key unanswered question, as does their contribution to specific age-related pathologies. Here, we establish a novel epigenetically-driven accelerated ageing syndrome. We demonstrate that DNMT3A gain-of-function mutations in Heyn-Sproul-Jackson syndrome recapitulate age-related gains in DNA methylation, cause multilineage stem cell dysfunction, and phenocopy aspects of ageing in humans and mice. We also show that region-specific DNA hypermethylation at lineage-specific genes can explain reduced stem cell output and lineage skewing. Hence, starting from a Mendelian disorder, we causally implicate DNA methylation-mediated stem cell exhaustion in the aetiology of medically important age-related haematological, bone and metabolic pathologies, that might be targetable by future therapies.

Project description:Declining tissue function and regenerative capacity underlie many chronic diseases. Experimentally establishing the mechanistic basis for such tissue ageing presents substantial challenges, given decades-long timescales and multifactorial origins. Epigenetic alterations have been proposed to have a key aetiological role, but whether they are correlative or causal remains a key unanswered question, as does their contribution to specific age-related pathologies. Here, we establish a novel epigenetically-driven accelerated ageing syndrome. We demonstrate that DNMT3A gain-of-function mutations in Heyn-Sproul-Jackson syndrome recapitulate age-related gains in DNA methylation, cause multilineage stem cell dysfunction, and phenocopy aspects of ageing in humans and mice. We also show that region-specific DNA hypermethylation at lineage-specific genes can explain reduced stem cell output and lineage skewing. Hence, starting from a Mendelian disorder, we causally implicate DNA methylation-mediated stem cell exhaustion in the aetiology of medically important age-related haematological, bone and metabolic pathologies, that might be targetable by future therapies.

Project description:Declining tissue function and regenerative capacity underlie many chronic diseases. Experimentally establishing the mechanistic basis for such tissue ageing presents substantial challenges, given decades-long timescales and multifactorial origins. Epigenetic alterations have been proposed to have a key aetiological role, but whether they are correlative or causal remains a key unanswered question, as does their contribution to specific age-related pathologies. Here, we establish a novel epigenetically-driven accelerated ageing syndrome. We demonstrate that DNMT3A gain-of-function mutations in Heyn-Sproul-Jackson syndrome recapitulate age-related gains in DNA methylation, cause multilineage stem cell dysfunction, and phenocopy aspects of ageing in humans and mice. We also show that region-specific DNA hypermethylation at lineage-specific genes can explain reduced stem cell output and lineage skewing. Hence, starting from a Mendelian disorder, we causally implicate DNA methylation-mediated stem cell exhaustion in the aetiology of medically important age-related haematological, bone and metabolic pathologies, that might be targetable by future therapies.

Project description:Declining tissue function and regenerative capacity underlie many chronic diseases.Experimentally establishing the mechanistic basis for such tissue ageing presents substantial challenges, given decades-long timescales and multifactorial origins. Epigenetic alterations have been proposed to have a key aetiological role, but whether they are correlative or causal remains a key unanswered question, as does their contribution to specific age-related pathologies. Here, we establish a novel epigenetically-driven accelerated ageing syndrome. We demonstrate that DNMT3A gain-of-function mutations in Heyn-Sproul-Jackson syndrome recapitulate age-related gains in DNA methylation, cause multilineage stem cell dysfunction, and phenocopy aspects of ageing in humans and mice. We also show that region-specific DNA hypermethylation at lineage-specific genes can explain reduced stem cell output and lineage skewing. Hence, starting from a Mendelian disorder, we causally implicate DNA methylation-mediated stem cell exhaustion in the aetiology of medically important age-related haematological, bone and metabolic pathologies, that might be targetable by future therapies.

Project description:Overgrowth with Intellectual Disability (OGID) is characterized by generalized overgrowth, including a head circumference and/or height ≥ 2 standard deviations (s.d.) above the mean, accompanied by mild to moderate intellectual disability. Sotos Syndrome, the most common form of OGID, results from loss-of-function (LoF) mutations in NSD1, which encodes a histone methyltransferase. Another major OGID subtype, Tatton-Brown-Rahman syndrome, is caused by LoF mutations in DNMT3A, encoding a de novo DNA methyltransferase. In contrast, gain-of-function (GoF) mutations in DNMT3A cause Heyn-Sproul-Jackson syndrome, characterized by growth restriction and microcephaly. We hypothesize that NSD1 LoF and DNMT3A LoF mutations share a convergent DNA methylation signature that is distinct from the pattern seen in DNMT3A GoF mutations. To test this, we generated human embryonic stem cell lines carrying these growth syndrome-associated mutations in NSD1 and DNMT3A, profiled their DNA methylation patterns using the Illumina EPIC array, and analyzed both shared and unique methylation phenotypes.

Project description:Overgrowth with Intellectual Disability (OGID) is characterized by generalized overgrowth, including a head circumference and/or height ≥ 2 standard deviations (s.d.) above the mean, accompanied by mild to moderate intellectual disability. Sotos Syndrome, the most common form of OGID, results from loss-of-function (LoF) mutations in NSD1, which encodes a histone methyltransferase. Another major OGID subtype, Tatton-Brown-Rahman syndrome, is caused by LoF mutations in DNMT3A, encoding a de novo DNA methyltransferase. In contrast, gain-of-function (GoF) mutations in DNMT3A cause Heyn-Sproul-Jackson syndrome, characterized by growth restriction and microcephaly. We hypothesize that NSD1 LoF and DNMT3A LoF mutations share a convergent DNA methylation signature that is distinct from the pattern seen in DNMT3A GoF mutations. To test this, we generated human embryonic stem cell lines carrying these growth syndrome-associated mutations in NSD1 and DNMT3A, profiled their DNA methylation patterns using the Illumina EPIC array, and analyzed both shared and unique methylation phenotypes.

Project description:Overgrowth with Intellectual Disability (OGID) is characterized by generalized overgrowth, including a head circumference and/or height ≥ 2 standard deviations (s.d.) above the mean, accompanied by mild to moderate intellectual disability. Sotos Syndrome, the most common form of OGID, results from loss-of-function (LoF) mutations in NSD1, which encodes a histone methyltransferase. Another major OGID subtype, Tatton-Brown-Rahman syndrome, is caused by LoF mutations in DNMT3A, encoding a de novo DNA methyltransferase. In contrast, gain-of-function (GoF) mutations in DNMT3A cause Heyn-Sproul-Jackson syndrome, characterized by growth restriction and microcephaly. We hypothesize that NSD1 LoF and DNMT3A LoF mutations share a convergent DNA methylation signature that is distinct from the pattern seen in DNMT3A GoF mutations. To test this, we generated human embryonic stem cell lines carrying these growth syndrome-associated mutations in NSD1 and DNMT3A, profiled their DNA methylation patterns using the Illumina EPIC array, and analyzed both shared and unique methylation phenotypes.

Project description:The mammalian central nervous system (CNS) is susceptible to age-related pathologies, resulting in progressive, irreversible disease. Neurodegenerative eye conditions, like glaucoma and age-related macular degeneneration (AMD), are on the rise due to increased life expectancy. Despite this, there are currently no long-term therapies to prevent degeneration and vision loss. The short-lived African turquoise kililfsh (Nothobranchius furzeri GRZ-AD) is an ideal genetic model for ageing studies, exhibiting rapid ageing phenotypes within its four to six-mont lifespan. Investigating the molecular consequences of ageing in the retina, we conducted bulk RNA-sequencing, revealing dysregulation of genetic pathways associated with ageing CNS and retinal diseas in the aged killifish retina.

Project description:Transcriptional profiling of human control and Néstor-Guillermo Progeria Syndrome (NGPS) mesenchymal stem cells (MSCs). Somatic cell reprogramming involves rejuvenation of adult cells and relies on the ability to erase age-associated molecular marks. Accordingly, reprogramming efficiency declines with ageing, and age-associated features such as genetic instability, cell senescence or telomere shortening negatively affect this process. However, the regulatory mechanisms that constitute age-associated barriers for cell reprogramming remain largely unknown. Here, by using cells from patients with premature ageing, we demonstrate that NF-κB activation is a critical barrier for the generation of induced pluripotent stem cells (iPSCs) in ageing. We show that NF-κB repression occurs during cell reprogramming towards a pluripotent state. Conversely, ageing-associated NF-κB hyperactivation impairs generation of iPSCs by eliciting reprogramming repressors DOT1L and YY1, reinforcing cell senescence signals and down-regulating pluripotency genes. We also show that genetic and pharmacological NF-κB inhibitory strategies significantly increase the reprogramming efficiency of fibroblasts from Néstor-Guillermo Progeria Syndrome (NGPS) and Hutchinson-Gilford Progeria Syndrome (HGPS) patients, as well as from normal aged donors. Finally, we demonstrate that DOT1L inhibition in vivo ameliorates the accelerated ageing phenotype and extends lifespan in a progeroid animal model. Collectively, our results provide evidence for a novel role of NF-κB in the control of cell fate transitions and reinforce the interest of studying age-associated molecular impairments to implement cell reprogramming methodologies, and to identify new targets of rejuvenation strategies. Control and NGPS MSCs were differentiated into bone in the presence or absence of sodium salicylate. Total RNA was extracted and global gene expression was analyzed.

Project description:Transcriptional profiling of human control and Néstor-Guillermo Progeria Syndrome (NGPS) fibroblasts and induced pluripotent stem cells (iPSCs). Somatic cell reprogramming involves rejuvenation of adult cells and relies on the ability to erase age-associated molecular marks. Accordingly, reprogramming efficiency declines with ageing, and age-associated features such as genetic instability, cell senescence or telomere shortening negatively affect this process. However, the regulatory mechanisms that constitute age-associated barriers for cell reprogramming remain largely unknown. Here, by using cells from patients with premature ageing, we demonstrate that NF-κB activation is a critical barrier for the generation of induced pluripotent stem cells (iPSCs) in ageing. We show that NF-κB repression occurs during cell reprogramming towards a pluripotent state. Conversely, ageing-associated NF-κB hyperactivation impairs generation of iPSCs by eliciting reprogramming repressors DOT1L and YY1, reinforcing cell senescence signals and down-regulating pluripotency genes. We also show that genetic and pharmacological NF-κB inhibitory strategies significantly increase the reprogramming efficiency of fibroblasts from Néstor-Guillermo Progeria Syndrome (NGPS) and Hutchinson-Gilford Progeria Syndrome (HGPS) patients, as well as from normal aged donors. Finally, we demonstrate that DOT1L inhibition in vivo ameliorates the accelerated ageing phenotype and extends lifespan in a progeroid animal model. Collectively, our results provide evidence for a novel role of NF-κB in the control of cell fate transitions and reinforce the interest of studying age-associated molecular impairments to implement cell reprogramming methodologies, and to identify new targets of rejuvenation strategies. Control and NGPS fibroblasts were reprogrammed. RNA was extracted and transcriptional profiling was obtained with GeneChip Human Exon 1.0 ST Arrays.