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Neuroscience

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A translatable RNAi-driven gene therapy silences PMP22/Pmp22 genes and improves neuropathy in CMT1A mice
Marina Stavrou, … , Scott Q. Harper, Kleopas A. Kleopa
Marina Stavrou, … , Scott Q. Harper, Kleopas A. Kleopa
Published May 17, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI159814.
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A translatable RNAi-driven gene therapy silences PMP22/Pmp22 genes and improves neuropathy in CMT1A mice

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Abstract

Charcot-Marie-Tooth disease type 1A (CMT1A), the most common inherited demyelinating peripheral neuropathy, is caused by PMP22 gene duplication. Over-expression of wild-type PMP22 in Schwann cells destabilizes the myelin sheath, leading to demyelination and ultimately to secondary axonal loss and disability. No treatments currently exist that modify the disease course. The most direct route to CMT1A therapy will involve reducing PMP22 to normal levels. To accomplish this, we developed a gene therapy strategy to reduce PMP22 using novel artificial microRNAs targeting human and mouse PMP22/Pmp22 mRNAs. Our lead therapeutic microRNA, miR871, was packaged into an AAV9 vector and delivered by lumbar intrathecal injection into C61-het mice, a model of CMT1A. AAV9-miR871 efficiently transduced Schwann cells in C61-het peripheral nerves and reduced human and mouse PMP22/Pmp22 mRNA and protein levels. Treatment at early and late stages of the disease significantly improved multiple functional outcome measures and nerve conduction velocities. Furthermore, myelin pathology in lumbar roots and femoral motor nerves was ameliorated. Treated mice also showed reductions in circulating biomarkers of CMT1A. Taken together, our data demonstrate that AAV9-miR871-driven silencing of PMP22 rescues a CMT1A model and provides proof of principle for treating CMT1A using a translatable gene therapy approach.

Authors

Marina Stavrou, Alexia Kagiava, Sarah G. Choudury, Matthew J. Jennings, Lindsay M. Wallace, Allison M. Fowler, Amanda Heslegrave, Jan Richter, Christina Tryfonos, Christina Christodoulou, Henrik Zetterberg, Rita Horvath, Scott Q. Harper, Kleopas A. Kleopa

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mTORC2 mediates structural plasticity in distal nociceptive endings that contributes to pain hypersensitivity following inflammation
Calvin Wong, … , Alexander M. Binshtok, Arkady Khoutorsky
Calvin Wong, … , Alexander M. Binshtok, Arkady Khoutorsky
Published May 17, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI152635.
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mTORC2 mediates structural plasticity in distal nociceptive endings that contributes to pain hypersensitivity following inflammation

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Abstract

The encoding of noxious stimuli into action potential firing is largely mediated by nociceptive free nerve endings. Tissue inflammation, by changing the intrinsic properties of the nociceptive endings, leads to nociceptive hyperexcitability, and thus to the development of inflammatory pain. Here, we showed that tissue inflammation-induced activation of the mammalian target of rapamycin complex 2 (mTORC2) triggers changes in the architecture of nociceptive terminals and leads to inflammatory pain. Pharmacological activation of mTORC2 induced elongation and branching of nociceptor peripheral endings and caused long-lasting pain hypersensitivity. Conversely, nociceptor-specific deletion of the mTORC2 regulatory protein, Rictor, prevented inflammation-induced elongation and branching of cutaneous nociceptive fibers and attenuated inflammatory pain hypersensitivity. Computational modelling demonstrated that mTORC2-mediated structural changes in the nociceptive terminal tree are sufficient to increase the excitability of nociceptors. Targeting mTORC2 using a single injection of antisense oligonucleotide against Rictor provided long-lasting alleviation of inflammatory pain hypersensitivity. Collectively, we showed that tissue inflammation-induced activation of mTORC2 causes structural plasticity of nociceptive free nerve endings in the epidermis and inflammatory hyperalgesia, representing a therapeutic target for inflammatory pain.

Authors

Calvin Wong, Omer Barkai, Feng Wang, Carolina Thörn Pérez, Shaya Lev, Weihua Cai, Shannon Tansley, Noosha Yousefpour, Mehdi Hooshmandi, Kevin C. Lister, Mariam Latif, A. Claudio Cuello, Masha Prager-Khoutorsky, Jeffrey S. Mogil, Philippe Séguéla, Yves De Koninck, Alfredo Ribeiro-da-Silva, Alexander M. Binshtok, Arkady Khoutorsky

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Caffeine intake exerts dual genome-wide effects on hippocampal metabolism and learning-dependent transcription
Isabel Paiva, … , Anne-Laurence Boutillier, David Blum
Isabel Paiva, … , Anne-Laurence Boutillier, David Blum
Published May 10, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI149371.
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Caffeine intake exerts dual genome-wide effects on hippocampal metabolism and learning-dependent transcription

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Abstract

Caffeine is the most consumed psychoactive substance worldwide. Strikingly, molecular pathways engaged by its regular consumption remain unclear. We herein addressed the mechanisms associated with habitual (chronic) caffeine consumption in the mouse hippocampus using untargeted orthogonal-omics techniques. Our results revealed that chronic caffeine exerts concerted pleiotropic effects in the hippocampus, at the epigenomic, proteomic and metabolomic levels. Caffeine lowers metabolic-related processes in the bulk tissue, while it induces neuronal-specific epigenetic changes at synaptic transmission/plasticity-related genes and increased experience-driven transcriptional activity. Altogether, these findings suggest that regular caffeine intake improves the signal-to-noise ratio during information encoding, in part through a fine-tuning of metabolic genes while boosting the salience of information processing during learning in neuronal circuits.

Authors

Isabel Paiva, Lucrezia Cellai, Céline Meriaux, Lauranne Poncelet, Ouada Nebie, Jean-Michel Saliou, Anne-Sophie Lacoste, Anthony Papegaey, Hervé Drobecq, Stéphanie Le Gras, Marion Schneider, Enas M. Malik, Christa E. Müller, Emilie Faivre, Kevin Carvalho, Victoria Gomez-Murcia, Didier Vieau, Bryan Thiroux, Sabiha Eddarkaoui, Thibaud Lebouvier, Estelle Schueller, Laura Tzeplaeff, Iris Grgurina, Jonathan Seguin, Jonathan Stauber, Luisa V. Lopes, Luc Buee, Valerie Buée-Scherrer, Rodrigo A. Cunha, Rima Ait-Belkacem, Nicolas Sergeant, Jean-Sébastien Annicotte, Anne-Laurence Boutillier, David Blum

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Peripheral monocyte-derived cells counter amyloid plaque pathogenesis in a mouse model of Alzheimer’s disease
Ping Yan, … , Jin-Moo Lee, Abhinav Diwan
Ping Yan, … , Jin-Moo Lee, Abhinav Diwan
Published May 5, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI152565.
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Peripheral monocyte-derived cells counter amyloid plaque pathogenesis in a mouse model of Alzheimer’s disease

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Abstract

Microglia, the parenchymal tissue macrophages in the brain, surround amyloid plaques in Alzheimer’s disease (AD) but are ineffective at clearing amyloid to mitigate disease progression. Recent studies in mice indicate that microglia are exclusively derived from primitive yolk-sac hematopoiesis and self-renew without contribution from ontogenically-distinct monocytes/macrophages of definitive ‘adult’ hematopoietic origin. Using genetic fate-mapping to label cells of definitive hematopoietic-origin throughout the life-span, we discovered that circulating monocytes contribute 6% of plaque-associated macrophages in aged AD mice. Moreover, peripheral monocytes contributed to a higher fraction of macrophages in the choroid plexus, meninges and perivascular spaces of aged AD mice versus wild-type controls, indicating enrichment at potential sites for entry into the brain parenchyma. Splenectomy, which markedly reduced circulating Ly6Chi monocytes, also reduced abundance of plaque-associated macrophages of definitive-hematopoietic origin, resulting in increased amyloid plaque load. Together, these results indicate that peripherally-derived monocytes invade the brain parenchyma, targeting amyloid plaques to reduce plaque load.

Authors

Ping Yan, Ki-Wook Kim, Qingli Xiao, Xiucui Ma, Leah R. Czerniewski, Haiyan Liu, David R. Rawnsley, Yan Yan, Gwendalyn J. Randolph, Slava Epelman, Jin-Moo Lee, Abhinav Diwan

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Cross-species genetic screens identify transglutaminase 5 as a regulator of polyglutamine-expanded ataxin-1
Won-Seok Lee, … , Juan Botas, Huda Y. Zoghbi
Won-Seok Lee, … , Juan Botas, Huda Y. Zoghbi
Published May 2, 2022
Citation Information: J Clin Invest. 2022;132(9):e156616. https://doi.org/10.1172/JCI156616.
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Cross-species genetic screens identify transglutaminase 5 as a regulator of polyglutamine-expanded ataxin-1

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Abstract

Many neurodegenerative disorders are caused by abnormal accumulation of misfolded proteins. In spinocerebellar ataxia type 1 (SCA1), accumulation of polyglutamine-expanded (polyQ-expanded) ataxin-1 (ATXN1) causes neuronal toxicity. Lowering total ATXN1, especially the polyQ-expanded form, alleviates disease phenotypes in mice, but the molecular mechanism by which the mutant ATXN1 is specifically modulated is not understood. Here, we identified 22 mutant ATXN1 regulators by performing a cross-species screen of 7787 and 2144 genes in human cells and Drosophila eyes, respectively. Among them, transglutaminase 5 (TG5) preferentially regulated mutant ATXN1 over the WT protein. TG enzymes catalyzed cross-linking of ATXN1 in a polyQ-length–dependent manner, thereby preferentially modulating mutant ATXN1 stability and oligomerization. Perturbing Tg in Drosophila SCA1 models modulated mutant ATXN1 toxicity. Moreover, TG5 was enriched in the nuclei of SCA1-affected neurons and colocalized with nuclear ATXN1 inclusions in brain tissue from patients with SCA1. Our work provides a molecular insight into SCA1 pathogenesis and an opportunity for allele-specific targeting for neurodegenerative disorders.

Authors

Won-Seok Lee, Ismael Al-Ramahi, Hyun-Hwan Jeong, Youjin Jang, Tao Lin, Carolyn J. Adamski, Laura A. Lavery, Smruti Rath, Ronald Richman, Vitaliy V. Bondar, Elizabeth Alcala, Jean-Pierre Revelli, Harry T. Orr, Zhandong Liu, Juan Botas, Huda Y. Zoghbi

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Long-term male-specific chronic pain via telomere- and p53‑mediated spinal cord cellular senescence
Arjun Muralidharan, … , Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil
Arjun Muralidharan, … , Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil
Published April 15, 2022
Citation Information: J Clin Invest. 2022;132(8):e151817. https://doi.org/10.1172/JCI151817.
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Long-term male-specific chronic pain via telomere- and p53‑mediated spinal cord cellular senescence

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Abstract

Mice with experimental nerve damage can display long‑lasting neuropathic pain behavior. We show here that 4 months and later after nerve injury, male but not female mice displayed telomere length (TL) reduction and p53‑mediated cellular senescence in the spinal cord, resulting in maintenance of pain and associated with decreased lifespan. Nerve injury increased the number of p53‑positive spinal cord neurons, astrocytes, and microglia, but only in microglia was the increase male‑specific, matching a robust sex specificity of TL reduction in this cell type, which has been previously implicated in male‑specific pain processing. Pain hypersensitivity was reversed by repeated intrathecal administration of a p53‑specific senolytic peptide, only in male mice and only many months after injury. Analysis of UK Biobank data revealed sex-specific relevance of this pathway in humans, featuring male‑specific genetic association of the human p53 locus (TP53) with chronic pain and a male-specific effect of chronic pain on mortality. Our findings demonstrate the existence of a biological mechanism maintaining pain behavior, at least in males, occurring much later than the time span of virtually all extant preclinical studies.

Authors

Arjun Muralidharan, Susana G. Sotocinal, Noosha Yousefpour, Nur Akkurt, Lucas V. Lima, Shannon Tansley, Marc Parisien, Chengyang Wang, Jean-Sebastien Austin, Boram Ham, Gabrielle M.G.S. Dutra, Philippe Rousseau, Sioui Maldonado-Bouchard, Teleri Clark, Sarah F. Rosen, Mariam R. Majeed, Olivia Silva, Rachel Nejade, Xinyu Li, Stephania Donayre Pimentel, Christopher S. Nielsen, G. Gregory Neely, Chantal Autexier, Luda Diatchenko, Alfredo Ribeiro-da-Silva, Jeffrey S. Mogil

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Aberrant miR-339-5p/neuronatin signaling causes prodromal neuronal calcium dyshomeostasis in mutant presenilin mice
Hao-Yu Zou, … , Nan-Jie Xu, Suya Sun
Hao-Yu Zou, … , Nan-Jie Xu, Suya Sun
Published April 15, 2022
Citation Information: J Clin Invest. 2022;132(8):e149160. https://doi.org/10.1172/JCI149160.
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Aberrant miR-339-5p/neuronatin signaling causes prodromal neuronal calcium dyshomeostasis in mutant presenilin mice

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Abstract

Mushroom spine loss and calcium dyshomeostasis are early hallmark events of age-related neurodegeneration, such as Alzheimer’s disease (AD), that are connected with neuronal hyperactivity in early pathology of cognitive brain areas. However, it remains elusive how these key events are triggered at the molecular level for the neuronal abnormality that occurs at the initial stage of disease. Here, we identify downregulated miR-339-5p and its upregulated target protein, neuronatin (Nnat), in cortex neurons from the presenilin-1 M146V knockin (PSEN1-M146V KI) mouse model of familial AD (FAD). Inhibition of miR-339-5p or overexpression of Nnat recapitulates spine loss and endoplasmic reticulum calcium overload in cortical neurons with the PSEN1 mutation. Conversely, either overexpression of miR-339-5p or knockdown of Nnat restores spine morphogenesis and calcium homeostasis. We used fiber photometry recording during the object-cognitive process to further demonstrate that the PSEN1 mutant causes defective habituation in neuronal reaction in the retrosplenial cortex and that this can be rescued by restoring the miR-339-5p/Nnat pathway. Our findings thus reveal crucial roles of the miR-339-5p/Nnat pathway in FAD that may serve as potential diagnostic and therapeutic targets for early pathogenesis.

Authors

Hao-Yu Zou, Lin Guo, Bei Zhang, Si Chen, Xin-Rong Wu, Xian-Dong Liu, Xin-Yu Xu, Bin-Yin Li, Shengdi Chen, Nan-Jie Xu, Suya Sun

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MicroRNAs signatures associated with vulnerability to food addiction in mice and humans
Alejandra García-Blanco, … , Elena Martín-García, Rafael Maldonado
Alejandra García-Blanco, … , Elena Martín-García, Rafael Maldonado
Published March 29, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI156281.
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MicroRNAs signatures associated with vulnerability to food addiction in mice and humans

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Abstract

Food addiction is characterized by a loss of behavioral control over food intake and is associated with obesity and other eating disorders. The mechanisms underlying this behavioral disorder are largely unknown. We aim to investigate the changes in miRNAs expression promoted by food addiction in animals and humans and their involvement in the mechanisms underlying the behavioral hallmarks of this disorder. Sharp similitudes were found between the miRNAs signatures in the medial prefrontal cortex (mPFC) of our animal cohort and the miRNAs circulating levels in our human cohort allowing to identify several miRNAs of potential interest for the development of this disorder. TuD inhibition of miRNA-29c-3p in the mouse mPFC promotes persistence to response and enhances the vulnerability to develop food addiction, whereas miRNA-665-3p inhibition promotes compulsive-like behavior and also enhances food addiction vulnerability. In contrast, miRNA-137-3p inhibition in the mPFC does not affect the development of food addiction. Therefore, miRNA-29c-3p and miRNA-665-3p could be acting as protective factors towards food addiction. The elucidation of these novel epigenetic mechanisms provides advances toward innovative biomarkers and possible future interventions for food addiction and related disorders based on the strategies now available to modify miRNA activity and expression.

Authors

Alejandra García-Blanco, Laura Domingo-Rodriguez, Judit Cabana-Domínguez, Noèlia Fernàndez-Castillo, Laura Pineda-Cirera, Jordi Mayneris-Perxachs, Aurelijus Burokas, Jose Espinosa-Carrasco, Silvia Arboleya, Jessica Latorre, Catherine Stanton, Bru Cormand, Jose-Manuel Fernández-Real, Elena Martín-García, Rafael Maldonado

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The Eph receptor A4 plays a role in demyelination and depression-related behavior
Yuan Li, … , Albert H.C. Wong, Fang Liu
Yuan Li, … , Albert H.C. Wong, Fang Liu
Published March 10, 2022
Citation Information: J Clin Invest. 2022. https://doi.org/10.1172/JCI152187.
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The Eph receptor A4 plays a role in demyelination and depression-related behavior

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Abstract

Proper myelination of axons is crucial for normal sensory, motor and cognitive function. Abnormal myelination is seen in brain disorders such as major depressive disorder (MDD), but the molecular mechanisms connecting demyelination with the pathobiology remain largely unknown. We observed demyelination and synaptic deficits in mice exposed to either chronic unpredictable mild stress (CUMS) or lipopolysaccharide (LPS), two paradigms for inducing depression-like states. Pharmacologically restoring myelination normalized both synaptic deficits and depression-related behaviours. Furthermore, we found increased EphA4 expression in the excitatory neurons of CUMS mice and shRNA knockdown of EphA4 prevented demyelination and depression-like behaviours. These animal data are consistent with the decreased myelin basic protein and increased EphA4 levels we observed in post-mortem brain from patients with MDD. Our results provide novel insights into the etiology of depressive symptoms in some patients and suggest that inhibiting EphA4 or promoting myelination could be a promising and novel strategy for treating depression.

Authors

Yuan Li, Ping Su, Yuxiang Chen, Jing Nie, Ti-Fei Yuan, Albert H.C. Wong, Fang Liu

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USP25 inhibition ameliorates Alzheimer’s pathology through the regulation of APP processing and Aβ generation
Qiuyang Zheng, … , Weihong Song, Xin Wang
Qiuyang Zheng, … , Weihong Song, Xin Wang
Published March 1, 2022
Citation Information: J Clin Invest. 2022;132(5):e152170. https://doi.org/10.1172/JCI152170.
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USP25 inhibition ameliorates Alzheimer’s pathology through the regulation of APP processing and Aβ generation

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Abstract

Down syndrome (DS), or trisomy 21, is one of the critical risk factors for early-onset Alzheimer’s disease (AD), implicating key roles for chromosome 21–encoded genes in the pathogenesis of AD. We previously identified a role for the deubiquitinase USP25, encoded on chromosome 21, in regulating microglial homeostasis in the AD brain; however, whether USP25 affects amyloid pathology remains unknown. Here, by crossing 5×FAD AD and Dp16 DS mice, we observed that trisomy 21 exacerbated amyloid pathology in the 5×FAD brain. Moreover, bacterial artificial chromosome (BAC) transgene–mediated USP25 overexpression increased amyloid deposition in the 5×FAD mouse brain, whereas genetic deletion of Usp25 reduced amyloid deposition. Furthermore, our results demonstrate that USP25 promoted β cleavage of APP and Aβ generation by reducing the ubiquitination and lysosomal degradation of both APP and BACE1. Importantly, pharmacological inhibition of USP25 ameliorated amyloid pathology in the 5×FAD mouse brain. In summary, we identified the DS-related gene USP25 as a critical regulator of AD pathology, and our data suggest that USP25 serves as a potential pharmacological target for AD drug development.

Authors

Qiuyang Zheng, Beibei Song, Guilin Li, Fang Cai, Meiling Wu, Yingjun Zhao, LuLin Jiang, Tiantian Guo, Mingyu Shen, Huan Hou, Ying Zhou, Yini Zhao, Anjie Di, Lishan Zhang, Fanwei Zeng, Xiu-Fang Zhang, Hong Luo, Xian Zhang, Hongfeng Zhang, Zhiping Zeng, Timothy Y. Huang, Chen Dong, Hong Qing, Yun Zhang, Qing Zhang, Xu Wang, Yili Wu, Huaxi Xu, Weihong Song, Xin Wang

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TREM2 keeps myelinated axons under wraps
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Synergy among Parkinson’s disease-associated genes
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A model of periventricular leukomalacia
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