Your search keyword '"Herdy JR"' showing total 18 results

1. Neuronal senescence may drive brain aging.

Author

Herdy JR, Mertens J, and Gage FH

Subjects

Humans, Animals, Mice, Cellular Senescence, Aging physiology, Brain physiology, Neurons physiology

Abstract

Senescence of postmitotic neurons presents challenges and opportunities to modify brain aging.

Published

2024

2. Neural cell state shifts and fate loss in ageing and age-related diseases.

Author

Traxler L, Lucciola R, Herdy JR, Jones JR, Mertens J, and Gage FH

Subjects

Humans, Aged, Neuroglia metabolism, Brain, Aging, Neurons physiology, Neurodegenerative Diseases metabolism

Abstract

Most age-related neurodegenerative diseases remain incurable owing to an incomplete understanding of the disease mechanisms. Several environmental and genetic factors contribute to disease onset, with human biological ageing being the primary risk factor. In response to acute cellular damage and external stimuli, somatic cells undergo state shifts characterized by temporal changes in their structure and function that increase their resilience, repair cellular damage, and lead to their mobilization to counteract the pathology. This basic cell biological principle also applies to human brain cells, including mature neurons that upregulate developmental features such as cell cycle markers or glycolytic reprogramming in response to stress. Although such temporary state shifts are required to sustain the function and resilience of the young human brain, excessive state shifts in the aged brain might result in terminal fate loss of neurons and glia, characterized by a permanent change in cell identity. Here, we offer a new perspective on the roles of cell states in sustaining health and counteracting disease, and we examine how cellular ageing might set the stage for pathological fate loss and neurodegeneration. A better understanding of neuronal state and fate shifts might provide the means for a controlled manipulation of cell fate to promote brain resilience and repair., (© 2023. Springer Nature Limited.)

Published

2023

3. Increased post-mitotic senescence in aged human neurons is a pathological feature of Alzheimer's disease.

Author

Herdy JR, Traxler L, Agarwal RK, Karbacher L, Schlachetzki JCM, Boehnke L, Zangwill D, Galasko D, Glass CK, Mertens J, and Gage FH

Subjects

Humans, Aged, Neurons, Astrocytes, Oncogenes, Brain, Alzheimer Disease

Abstract

The concept of senescence as a phenomenon limited to proliferating cells has been challenged by growing evidence of senescence-like features in terminally differentiated cells, including neurons. The persistence of senescent cells late in life is associated with tissue dysfunction and increased risk of age-related disease. We found that Alzheimer's disease (AD) brains have significantly higher proportions of neurons that express senescence markers, and their distribution indicates bystander effects. AD patient-derived directly induced neurons (iNs) exhibit strong transcriptomic, epigenetic, and molecular biomarker signatures, indicating a specific human neuronal senescence-like state. AD iN single-cell transcriptomics revealed that senescent-like neurons face oncogenic challenges and metabolic dysfunction as well as display a pro-inflammatory signature. Integrative profiling of the inflammatory secretome of AD iNs and patient cerebral spinal fluid revealed a neuronal senescence-associated secretory phenotype that could trigger astrogliosis in human astrocytes. Finally, we show that targeting senescence-like neurons with senotherapeutics could be a strategy for preventing or treating AD., Competing Interests: Declaration of interests F.H.G. is an advisory board member of Cell Stem Cell., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2022

4. Chemical Replacement of Noggin with Dorsomorphin Homolog 1 for Cost-Effective Direct Neuronal Conversion.

Author

Böhnke L, Zhou-Yang L, Pelucchi S, Kogler F, Frantal D, Schön F, Lagerström S, Borgogno O, Baltazar J, Herdy JR, Kittel-Schneider S, Defrancesco M, and Mertens J

Subjects

Carrier Proteins, Humans, Transforming Growth Factors metabolism, Neurons cytology, Pyrazoles, Pyrimidines, Tubulin metabolism

Abstract

The direct conversion of adult human skin fibroblasts (FBs) into induced neurons (iNs) represents a useful technology to generate donor-specific adult-like human neurons. Disease modeling studies rely on the consistently efficient conversion of relatively large cohorts of FBs. Despite the identification of several small molecular enhancers, high-yield protocols still demand addition of recombinant Noggin. To identify a replacement to circumvent the technical and economic challenges associated with Noggin, we assessed dynamic gene expression trajectories of transforming growth factor-β signaling during FB-to-iN conversion. We identified ALK2 (ACVR1) of the bone morphogenic protein branch to possess the highest initial transcript abundance in FBs and the steepest decline during successful neuronal conversion. We thus assessed the efficacy of dorsomorphin homolog 1 (DMH1), a highly selective ALK2-inhibitor, for its potential to replace Noggin. Conversion media containing DMH1 (+DMH1) indeed enhanced conversion efficiencies over basic SMAD inhibition (tSMADi), yielding similar βIII-tubulin (TUBB3) purities as conversion media containing Noggin (+Noggin). Furthermore, +DMH1 induced high yields of iNs with clear neuronal morphologies that are positive for the mature neuronal marker NeuN. Validation of +DMH1 for iN conversion of FBs from 15 adult human donors further demonstrates that Noggin-free conversion consistently yields iN cultures that display high βIII-tubulin numbers with synaptic structures and basic spontaneous neuronal activity at a third of the cost.

Published

2022

5. Warburg-like metabolic transformation underlies neuronal degeneration in sporadic Alzheimer's disease.

Author

Traxler L, Herdy JR, Stefanoni D, Eichhorner S, Pelucchi S, Szücs A, Santagostino A, Kim Y, Agarwal RK, Schlachetzki JCM, Glass CK, Lagerwall J, Galasko D, Gage FH, D'Alessandro A, and Mertens J

Subjects

Glycolysis, Humans, Protein Isoforms genetics, Protein Isoforms metabolism, Pyruvate Kinase genetics, Pyruvate Kinase metabolism, Alzheimer Disease, Neoplasms pathology

Abstract

The drivers of sporadic Alzheimer's disease (AD) remain incompletely understood. Utilizing directly converted induced neurons (iNs) from AD-patient-derived fibroblasts, we identified a metabolic switch to aerobic glycolysis in AD iNs. Pathological isoform switching of the glycolytic enzyme pyruvate kinase M (PKM) toward the cancer-associated PKM2 isoform conferred metabolic and transcriptional changes in AD iNs. These alterations occurred via PKM2's lack of metabolic activity and via nuclear translocation and association with STAT3 and HIF1α to promote neuronal fate loss and vulnerability. Chemical modulation of PKM2 prevented nuclear translocation, restored a mature neuronal metabolism, reversed AD-specific gene expression changes, and re-activated neuronal resilience against cell death., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2022

6. Age-dependent instability of mature neuronal fate in induced neurons from Alzheimer's patients.

Author

Mertens J, Herdy JR, Traxler L, Schafer ST, Schlachetzki JCM, Böhnke L, Reid DA, Lee H, Zangwill D, Fernandes DP, Agarwal RK, Lucciola R, Zhou-Yang L, Karbacher L, Edenhofer F, Stern S, Horvath S, Paquola ACM, Glass CK, Yuan SH, Ku M, Szücs A, Goldstein LSB, Galasko D, and Gage FH

Subjects

Aged, Aging, Fibroblasts, Humans, Neurons, Alzheimer Disease, Induced Pluripotent Stem Cells

Abstract

Sporadic Alzheimer's disease (AD) exclusively affects elderly people. Using direct conversion of AD patient fibroblasts into induced neurons (iNs), we generated an age-equivalent neuronal model. AD patient-derived iNs exhibit strong neuronal transcriptome signatures characterized by downregulation of mature neuronal properties and upregulation of immature and progenitor-like signaling pathways. Mapping iNs to longitudinal neuronal differentiation trajectory data demonstrated that AD iNs reflect a hypo-mature neuronal identity characterized by markers of stress, cell cycle, and de-differentiation. Epigenetic landscape profiling revealed an underlying aberrant neuronal state that shares similarities with malignant transformation and age-dependent epigenetic erosion. To probe for the involvement of aging, we generated rejuvenated iPSC-derived neurons that showed no significant disease-related transcriptome signatures, a feature that is consistent with epigenetic clock and brain ontogenesis mapping, which indicate that fibroblast-derived iNs more closely reflect old adult brain stages. Our findings identify AD-related neuronal changes as age-dependent cellular programs that impair neuronal identity., Competing Interests: Declaration of interests F.H.G. is an advisory board member of Cell Stem Cell., (Copyright © 2021 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2021

7. Cytoplasmic synthesis of endogenous Alu complementary DNA via reverse transcription and implications in age-related macular degeneration.

Author

Fukuda S, Varshney A, Fowler BJ, Wang SB, Narendran S, Ambati K, Yasuma T, Magagnoli J, Leung H, Hirahara S, Nagasaka Y, Yasuma R, Apicella I, Pereira F, Makin RD, Magner E, Liu X, Sun J, Wang M, Baker K, Marion KM, Huang X, Baghdasaryan E, Ambati M, Ambati VL, Pandey A, Pandya L, Cummings T, Banerjee D, Huang P, Yerramothu P, Tolstonog GV, Held U, Erwin JA, Paquola ACM, Herdy JR, Ogura Y, Terasaki H, Oshika T, Darwish S, Singh RK, Mozaffari S, Bhattarai D, Kim KB, Hardin JW, Bennett CL, Hinton DR, Hanson TE, Röver C, Parang K, Kerur N, Liu J, Werner BC, Sutton SS, Sadda SR, Schumann GG, Gelfand BD, Gage FH, and Ambati J

Subjects

Animals, Cytoplasm genetics, DNA, Complementary genetics, Epithelium metabolism, Epithelium pathology, Humans, Macular Degeneration pathology, Retinal Pigments biosynthesis, Retroelements genetics, Reverse Transcription genetics, Alu Elements genetics, Long Interspersed Nucleotide Elements genetics, Macular Degeneration genetics, Retinal Pigments metabolism

Abstract

Alu retroelements propagate via retrotransposition by hijacking long interspersed nuclear element-1 (L1) reverse transcriptase (RT) and endonuclease activities. Reverse transcription of Alu RNA into complementary DNA (cDNA) is presumed to occur exclusively in the nucleus at the genomic integration site. Whether Alu cDNA is synthesized independently of genomic integration is unknown. Alu RNA promotes retinal pigmented epithelium (RPE) death in geographic atrophy, an untreatable type of age-related macular degeneration. We report that Alu RNA-induced RPE degeneration is mediated via cytoplasmic L1-reverse-transcribed Alu cDNA independently of retrotransposition. Alu RNA did not induce cDNA production or RPE degeneration in L1-inhibited animals or human cells. Alu reverse transcription can be initiated in the cytoplasm via self-priming of Alu RNA. In four health insurance databases, use of nucleoside RT inhibitors was associated with reduced risk of developing atrophic macular degeneration (pooled adjusted hazard ratio, 0.616; 95% confidence interval, 0.493-0.770), thus identifying inhibitors of this Alu replication cycle shunt as potential therapies for a major cause of blindness., Competing Interests: Competing interest statement: J.A. is a co-founder of iVeena Holdings, iVeena Delivery Systems, and Inflammasome Therapeutics, and has been a consultant for Allergan, Biogen, Boehringer-Ingelheim, Immunovant, Janssen, Olix Pharmaceuticals, Retinal Solutions, and Saksin LifeSciences unrelated to this work. J.A., B.D.G., B.J.F., S.N., K.A., S.-b.W., I.A., M.A., F.P., N.K., and S.F. are named as inventors on patent applications on macular degeneration filed by the University of Virginia or the University of Kentucky. J.W.H. has received consulting fees from Celgene Corporation unrelated to this work. S.S.S. has received research grants from Boehringer Ingelheim, Gilead Sciences, Portola Pharmaceuticals, and United Therapeutics unrelated to this work. J.A. and B.D.G. are co-founders of DiceRx.

Published

2021

8. One Big Step to a Neuron, Two Small Steps for miRNAs.

Author

Herdy JR, Karbacher L, and Mertens J

Subjects

Cell Differentiation, Cellular Reprogramming, Fibroblasts, Humans, Neurons, MicroRNAs genetics

Abstract

Direct cell fate conversion of human somatic cells into induced neurons (iNs) is often regarded as a highly concerted one-step process. In this issue of Cell Stem Cell, Cates et al. (2021) dissect the iN conversion trajectory into two largely independent steps and identify key players at each stage., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2021

9. Author Correction: L1-associated genomic regions are deleted in somatic cells of the healthy human brain.

Author

Erwin JA, Paquola ACM, Singer T, Gallina I, Novotny M, Quayle C, Bedrosian TA, Alves FIA, Butcher CR, Herdy JR, Sarkar A, Lasken RS, Muotri AR, and Gage FH

Abstract

In the version of this article initially published, NIH grant U01 MH106882 to F.H.G. was missing from the Acknowledgments. The error has been corrected in the HTML and PDF versions of the article.

Published

2018

10. Mitochondrial Aging Defects Emerge in Directly Reprogrammed Human Neurons due to Their Metabolic Profile.

Author

Kim Y, Zheng X, Ansari Z, Bunnell MC, Herdy JR, Traxler L, Lee H, Paquola ACM, Blithikioti C, Ku M, Schlachetzki JCM, Winkler J, Edenhofer F, Glass CK, Paucar AA, Jaeger BN, Pham S, Boyer L, Campbell BC, Hunter T, Mertens J, and Gage FH

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Cell Differentiation, Cells, Cultured, Child, Child, Preschool, Fibroblasts cytology, Gene Expression Regulation, Genes, Mitochondrial, Humans, Infant, Infant, Newborn, Middle Aged, Oxidative Phosphorylation, Phenotype, Tissue Donors, Young Adult, Aging pathology, Cellular Reprogramming, Metabolomics, Mitochondria metabolism, Neurons metabolism

Abstract

Mitochondria are a major target for aging and are instrumental in the age-dependent deterioration of the human brain, but studying mitochondria in aging human neurons has been challenging. Direct fibroblast-to-induced neuron (iN) conversion yields functional neurons that retain important signs of aging, in contrast to iPSC differentiation. Here, we analyzed mitochondrial features in iNs from individuals of different ages. iNs from old donors display decreased oxidative phosphorylation (OXPHOS)-related gene expression, impaired axonal mitochondrial morphologies, lower mitochondrial membrane potentials, reduced energy production, and increased oxidized proteins levels. In contrast, the fibroblasts from which iNs were generated show only mild age-dependent changes, consistent with a metabolic shift from glycolysis-dependent fibroblasts to OXPHOS-dependent iNs. Indeed, OXPHOS-induced old fibroblasts show increased mitochondrial aging features similar to iNs. Our data indicate that iNs are a valuable tool for studying mitochondrial aging and support a bioenergetic explanation for the high susceptibility of the brain to aging., (Copyright © 2018 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2018

11. Human neurons to model aging: A dish best served old.

Author

Böhnke L, Traxler L, Herdy JR, and Mertens J

Abstract

With the advancing age of humans and with it, growing numbers of age-related diseases, aging has become a major focus in recent research. The lack of fitting aging models, especially in neurological diseases where access to human brain samples is limited, has highlighted direct conversion into induced neurons (iN) as an important method to overcome this challenge. Contrary to iPSC reprogramming and its corresponding cell rejuvenation, the generation of iNs enables us to retain aging signatures throughout the conversion process and beyond. In this review, we explore different cell reprogramming methods in light of age-associated neurodegenerative diseases and discuss different approaches, advances, and limitations.

Published

2018

12. Highly conserved molecular pathways, including Wnt signaling, promote functional recovery from spinal cord injury in lampreys.

Author

Herman PE, Papatheodorou A, Bryant SA, Waterbury CKM, Herdy JR, Arcese AA, Buxbaum JD, Smith JJ, Morgan JR, and Bloom O

Subjects

Animals, Brain physiology, Gene Expression Profiling, Sequence Analysis, RNA, Spinal Cord Injuries pathology, Gene Regulatory Networks, Lampreys, Signal Transduction, Spinal Cord physiology, Spinal Cord Injuries veterinary, Spinal Cord Regeneration

Abstract

In mammals, spinal cord injury (SCI) leads to dramatic losses in neurons and synaptic connections, and consequently function. Unlike mammals, lampreys are vertebrates that undergo spontaneous regeneration and achieve functional recovery after SCI. Therefore our goal was to determine the complete transcriptional responses that occur after SCI in lampreys and to identify deeply conserved pathways that promote regeneration. We performed RNA-Seq on lamprey spinal cord and brain throughout the course of functional recovery. We describe complex transcriptional responses in the injured spinal cord, and somewhat surprisingly, also in the brain. Transcriptional responses to SCI in lampreys included transcription factor networks that promote peripheral nerve regeneration in mammals such as Atf3 and Jun. Furthermore, a number of highly conserved axon guidance, extracellular matrix, and proliferation genes were also differentially expressed after SCI in lampreys. Strikingly, ~3% of differentially expressed transcripts belonged to the Wnt pathways. These included members of the Wnt and Frizzled gene families, and genes involved in downstream signaling. Pharmacological inhibition of Wnt signaling inhibited functional recovery, confirming a critical role for this pathway. These data indicate that molecular signals present in mammals are also involved in regeneration in lampreys, supporting translational relevance of the model.

Published

2018

13. Corrigendum: L1-associated genomic regions are deleted in somatic cells of the healthy human brain.

Author

Erwin JA, Paquola ACM, Singer T, Gallina I, Novotny M, Quayle C, Bedrosian TA, Alves FIA, Butcher CR, Herdy JR, Sarkar A, Lasken RS, Muotri AR, and Gage FH

Published

2017

14. L1-associated genomic regions are deleted in somatic cells of the healthy human brain.

Author

Erwin JA, Paquola AC, Singer T, Gallina I, Novotny M, Quayle C, Bedrosian TA, Alves FI, Butcher CR, Herdy JR, Sarkar A, Lasken RS, Muotri AR, and Gage FH

Subjects

Cells, Cultured, Gene Dosage, Genome-Wide Association Study methods, Genomics methods, Humans, Sequence Deletion, Brain metabolism, Long Interspersed Nucleotide Elements genetics, Neurons metabolism

Abstract

The healthy human brain is a mosaic of varied genomes. Long interspersed element-1 (LINE-1 or L1) retrotransposition is known to create mosaicism by inserting L1 sequences into new locations of somatic cell genomes. Using a machine learning-based, single-cell sequencing approach, we discovered that somatic L1-associated variants (SLAVs) are composed of two classes: L1 retrotransposition insertions and retrotransposition-independent L1-associated variants. We demonstrate that a subset of SLAVs comprises somatic deletions generated by L1 endonuclease cutting activity. Retrotransposition-independent rearrangements in inherited L1s resulted in the deletion of proximal genomic regions. These rearrangements were resolved by microhomology-mediated repair, which suggests that L1-associated genomic regions are hotspots for somatic copy number variants in the brain and therefore a heritable genetic contributor to somatic mosaicism. We demonstrate that SLAVs are present in crucial neural genes, such as DLG2 (also called PSD93), and affect 44-63% of cells of the cells in the healthy brain.

Published

2016

15. Characterization of Somatically-Eliminated Genes During Development of the Sea Lamprey (Petromyzon marinus).

Author

Bryant SA, Herdy JR, Amemiya CT, and Smith JJ

Subjects

Animals, DNA blood, DNA genetics, Embryonic Development genetics, Evolution, Molecular, Genome, Germ Cells, Male, Petromyzon blood, Phylogeny, Sequence Analysis, DNA, Petromyzon embryology, Petromyzon genetics

Abstract

The sea lamprey (Petromyzon marinus) is a basal vertebrate that undergoes developmentally programmed genome rearrangements (PGRs) during early development. These events facilitate the elimination of ∼20% of the genome from the somatic cell lineage, resulting in distinct somatic and germline genomes. Thus far only a handful of germline-specific genes have been definitively identified within the estimated 500 Mb of DNA that is deleted during PGR, although a few thousand germline-specific genes are thought to exist. To improve our understanding of the evolutionary/developmental logic of PGR, we generated computational predictions to identify candidate germline-specific genes within a new transcriptomic dataset derived from adult germline and the early embryonic stages during which PGR occurs. Follow-up validation studies identified 44 germline-specific genes and further characterized patterns of transcription and DNA loss during early embryogenesis. Expression analyses reveal that many of these genes are differentially expressed during early embryogenesis and presumably function in the early development of the germline. Ontology analyses indicate that many of these germline-specific genes play known roles in germline development, pluripotency, and oncogenesis (when misexpressed). These studies provide support for the theory that PGR serves to segregate molecular functions related to germline development/pluripotency in order to prevent their potential misexpression in somatic cells. This larger set of eliminated genes also allows us to extend the evolutionary/developmental breadth of this theory, as some deleted genes (or their gnathostome homologs) appear to be associated with the early development of somatic lineages, perhaps through the evolution of novel functions within gnathostome lineages., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2016

16. Cellular and Molecular Features of Developmentally Programmed Genome Rearrangement in a Vertebrate (Sea Lamprey: Petromyzon marinus).

Author

Timoshevskiy VA, Herdy JR, Keinath MC, and Smith JJ

Subjects

Animals, Cell Division genetics, Chromatin genetics, Chromosomes genetics, DNA genetics, DNA Methylation genetics, Embryonic Development genetics, Epigenesis, Genetic genetics, Evolution, Molecular, Genomic Instability genetics, Gene Rearrangement genetics, Genome genetics, Petromyzon genetics, Vertebrates genetics

Abstract

The sea lamprey (Petromyzon marinus) represents one of the few vertebrate species known to undergo large-scale programmatic elimination of genomic DNA over the course of its normal development. Programmed genome rearrangements (PGRs) result in the reproducible loss of ~20% of the genome from somatic cell lineages during early embryogenesis. Studies of PGR hold the potential to provide novel insights related to the maintenance of genome stability during the cell cycle and coordination between mechanisms responsible for the accurate distribution of chromosomes into daughter cells, yet little is known regarding the mechanistic basis or cellular context of PGR in this or any other vertebrate lineage. Here we identify epigenetic silencing events that are associated with the programmed elimination of DNA and describe the spatiotemporal dynamics of PGR during lamprey embryogenesis. In situ analyses reveal that the earliest DNA methylation (and to some extent H3K9 trimethylation) events are limited to specific extranuclear structures (micronuclei) containing eliminated DNA. During early embryogenesis a majority of micronuclei (~60%) show strong enrichment for repressive chromatin modifications (H3K9me3 and 5meC). These analyses also led to the discovery that eliminated DNA is packaged into chromatin that does not migrate with somatically retained chromosomes during anaphase, a condition that is superficially similar to lagging chromosomes observed in some cancer subtypes. Closer examination of "lagging" chromatin revealed distributions of repetitive elements, cytoskeletal contacts and chromatin contacts that provide new insights into the cellular mechanisms underlying the programmed loss of these segments. Our analyses provide additional perspective on the cellular and molecular context of PGR, identify new structures associated with elimination of DNA and reveal that PGR is completed over the course of several successive cell divisions.

Published

2016

17. Directly Reprogrammed Human Neurons Retain Aging-Associated Transcriptomic Signatures and Reveal Age-Related Nucleocytoplasmic Defects.

Author

Mertens J, Paquola ACM, Ku M, Hatch E, Böhnke L, Ladjevardi S, McGrath S, Campbell B, Lee H, Herdy JR, Gonçalves JT, Toda T, Kim Y, Winkler J, Yao J, Hetzer MW, and Gage FH

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Cell Separation, Child, Child, Preschool, Fibroblasts cytology, Flow Cytometry, Humans, Infant, Infant, Newborn, Middle Aged, Neural Cell Adhesion Molecules metabolism, Transcriptome, Young Adult, ran GTP-Binding Protein metabolism, Aging, Cell Nucleus metabolism, Cellular Reprogramming, Cytoplasm metabolism, Induced Pluripotent Stem Cells cytology, Neurons cytology

Abstract

Aging is a major risk factor for many human diseases, and in vitro generation of human neurons is an attractive approach for modeling aging-related brain disorders. However, modeling aging in differentiated human neurons has proved challenging. We generated neurons from human donors across a broad range of ages, either by iPSC-based reprogramming and differentiation or by direct conversion into induced neurons (iNs). While iPSCs and derived neurons did not retain aging-associated gene signatures, iNs displayed age-specific transcriptional profiles and revealed age-associated decreases in the nuclear transport receptor RanBP17. We detected an age-dependent loss of nucleocytoplasmic compartmentalization (NCC) in donor fibroblasts and corresponding iNs and found that reduced RanBP17 impaired NCC in young cells, while iPSC rejuvenation restored NCC in aged cells. These results show that iNs retain important aging-related signatures, thus allowing modeling of the aging process in vitro, and they identify impaired NCC as an important factor in human aging., (Copyright © 2015 Elsevier Inc. All rights reserved.)

Published

2015

18. Modifiers of C9orf72 dipeptide repeat toxicity connect nucleocytoplasmic transport defects to FTD/ALS.

Author

Jovičić A, Mertens J, Boeynaems S, Bogaert E, Chai N, Yamada SB, Paul JW 3rd, Sun S, Herdy JR, Bieri G, Kramer NJ, Gage FH, Van Den Bosch L, Robberecht W, and Gitler AD

Subjects

Active Transport, Cell Nucleus physiology, Amyotrophic Lateral Sclerosis genetics, Animals, C9orf72 Protein, Cell Nucleus genetics, Cells, Cultured, Dipeptides genetics, Frontotemporal Dementia genetics, Gene Deletion, Humans, Mice, Proteins genetics, Yeasts, Amyotrophic Lateral Sclerosis metabolism, Cell Nucleus metabolism, DNA Repeat Expansion physiology, Dipeptides metabolism, Frontotemporal Dementia metabolism, Proteins metabolism

Abstract

C9orf72 mutations are the most common cause of amyotrophic lateral sclerosis (ALS) and frontotemporal dementia (FTD). Dipeptide repeat proteins (DPRs) produced by unconventional translation of the C9orf72 repeat expansions cause neurodegeneration in cell culture and in animal models. We performed two unbiased screens in Saccharomyces cerevisiae and identified potent modifiers of DPR toxicity, including karyopherins and effectors of Ran-mediated nucleocytoplasmic transport, providing insight into potential disease mechanisms and therapeutic targets.

Published

2015