Your search keyword '"Meghan T. Miller"' showing total 7 results

1. Enabling endpoint development for interventional clinical trials in individuals with Angelman syndrome: a prospective, longitudinal, observational clinical study (FREESIAS)

Author

Jorrit Tjeertes, Carlos A. Bacino, Terry Jo Bichell, Lynne M. Bird, Mariana Bustamante, Rebecca Crean, Shafali Jeste, Robert W. Komorowski, Michelle L. Krishnan, Meghan T. Miller, David Nobbs, Cesar Ochoa-Lubinoff, Kimberly A. Parkerson, Alexander Rotenberg, Anjali Sadhwani, Mark D. Shen, Lisa Squassante, Wen-Hann Tan, Brenda Vincenzi, Anne C. Wheeler, Joerg F. Hipp, and Elizabeth Berry-Kravis

Subjects

Angelman syndrome, Endpoint development, EEG, Sleep, Digital health technology, Clinical outcome assessments, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Background Angelman syndrome (AS) is a rare neurodevelopmental disorder characterized by the absence of a functional UBE3A gene, which causes developmental, behavioral, and medical challenges. While currently untreatable, comprehensive data could help identify appropriate endpoints assessing meaningful improvements in clinical trials. Herein are reported the results from the FREESIAS study assessing the feasibility and utility of in-clinic and at-home measures of key AS symptoms. Methods Fifty-five individuals with AS (aged

Published

2023

2. AntimiR targeting of microRNA-134 reduces seizures in a mouse model of Angelman syndrome

Author

Aoife Campbell, Gareth Morris, Albert Sanfeliu, Joana Augusto, Elena Langa, Jaideep C. Kesavan, Ngoc T. Nguyen, Ronan M. Conroy, Jesper Worm, Lukasz Kielpinski, Mads Aaboe Jensen, Meghan T. Miller, Thomas Kremer, Cristina R. Reschke, and David C. Henshall

Subjects

MT: Oligonucleotides: Therapies and Applications, microRNAs, Angelman syndrome, epilepsy, seizures, miR-134, Therapeutics. Pharmacology, RM1-950

Abstract

Angelman syndrome (AS) is a severe neurodevelopmental disorder featuring ataxia, cognitive impairment, and drug-resistant epilepsy. AS is caused by mutations or deletion of the maternal copy of the paternally imprinted UBE3A gene, with current precision therapy approaches focusing on re-expression of UBE3A. Certain phenotypes, however, are difficult to rescue beyond early development. Notably, a cluster of microRNA binding sites was reported in the untranslated Ube3a1 transcript, including for miR-134, suggesting that AS may be associated with microRNA dysregulation. Here, we report levels of miR-134 and key targets are normal in the hippocampus of mice carrying a maternal deletion of Ube3a (Ube3am−/p+). Nevertheless, intracerebroventricular injection of an antimiR oligonucleotide inhibitor of miR-134 (Ant-134) reduced audiogenic seizure severity over multiple trials in 21- and 42-day-old AS mice. Interestingly, Ant-134 also improved distance traveled and center crossings of AS mice in the open-field test. Finally, we show that silencing miR-134 can upregulate targets of miR-134 in neurons differentiated from Angelman patient-derived induced pluripotent stem cells. These findings indicate that silencing miR-134 and possibly other microRNAs could be useful to treat clinically relevant phenotypes with a later developmental window in AS.

Published

2022

3. Antagomir-mediated suppression of microRNA-134 reduces kainic acid-induced seizures in immature mice

Author

Aoife Campbell, Gareth Morris, Janosch P. Heller, Elena Langa, Elizabeth Brindley, Jesper Worm, Mads Aaboe Jensen, Meghan T. Miller, David C. Henshall, and Cristina R. Reschke

Subjects

Medicine, Science

Abstract

Abstract MicroRNAs are short non-coding RNAs that negatively regulate protein levels and perform important roles in establishing and maintaining neuronal network function. Previous studies in adult rodents have detected upregulation of microRNA-134 after prolonged seizures (status epilepticus) and demonstrated that silencing microRNA-134 using antisense oligonucleotides, termed antagomirs, has potent and long-lasting seizure-suppressive effects. Here we investigated whether targeting microRNA-134 can reduce or delay acute seizures in the immature brain. Status epilepticus was induced in 21 day-old (P21) male mice by systemic injection of 5 mg/kg kainic acid. This triggered prolonged electrographic seizures and select bilateral neuronal death within the CA3 subfield of the hippocampus. Expression of microRNA-134 and functional loading to Argonaute-2 was not significantly changed in the hippocampus after seizures in the model. Nevertheless, when levels of microRNA-134 were reduced by prior intracerebroventricular injection of an antagomir, kainic acid-induced seizures were delayed and less severe and mice displayed reduced neuronal death in the hippocampus. These studies demonstrate targeting microRNA-134 may have therapeutic applications for the treatment of seizures in children.

Published

2021

4. Antisense oligonucleotide treatment rescues UBE3A expression and multiple phenotypes of an Angelman syndrome mouse model

Author

Claudia Milazzo, Edwin J. Mientjes, Ilse Wallaard, Søren Vestergaard Rasmussen, Kamille Dumong Erichsen, Tejaswini Kakunuri, A.S. Elise van der Sman, Thomas Kremer, Meghan T. Miller, Marius C. Hoener, and Ype Elgersma

Subjects

Development, Neuroscience, Medicine

Abstract

Angelman syndrome (AS) is a severe neurodevelopmental disorder for which only symptomatic treatment with limited benefits is available. AS is caused by mutations affecting the maternally inherited ubiquitin protein ligase E3A (UBE3A) gene. Previous studies showed that the silenced paternal Ube3a gene can be activated by targeting the antisense Ube3a-ATS transcript. We investigated antisense oligonucleotide–induced (ASO-induced) Ube3a-ATS degradation and its ability to induce UBE3A reinstatement and rescue of AS phenotypes in an established Ube3a mouse model. We found that a single intracerebroventricular injection of ASOs at postnatal day 1 (P1) or P21 in AS mice resulted in potent and specific UBE3A reinstatement in the brain, with levels up to 74% of WT levels in the cortex and a full rescue of sensitivity to audiogenic seizures. AS mice treated with ASO at P1 also showed rescue of established AS phenotypes, such as open field and forced swim test behaviors, and significant improvement on the reversed rotarod. Hippocampal plasticity of treated AS mice was comparable to WT but not significantly different from PBS-treated AS mice. No rescue was observed for the marble burying and nest building phenotypes. Our findings highlight the promise of ASO-mediated reactivation of UBE3A as a disease-modifying treatment for AS.

Published

2021

5. Loss of Tsc1 in cerebellar Purkinje cells induces transcriptional and translation changes in FMRP target transcripts

Author

Jasbir Singh Dalal, Kellen Diamond Winden, Catherine Lourdes Salussolia, Maria Sundberg, Achint Singh, Truc Thanh Pham, Pingzhu Zhou, William T Pu, Meghan T Miller, and Mustafa Sahin

Subjects

Tuberous Sclerosis, mTOR, FMRP, translation, ribosome, autism, Medicine, Science, Biology (General), QH301-705.5

Abstract

Tuberous sclerosis complex (TSC) is a genetic disorder that is associated with multiple neurological manifestations. Previously, we demonstrated that Tsc1 loss in cerebellar Purkinje cells (PCs) can cause altered social behavior in mice. Here, we performed detailed transcriptional and translational analyses of Tsc1-deficient PCs to understand the molecular alterations in these cells. We found that target transcripts of the Fragile X Mental Retardation Protein (FMRP) are reduced in mutant PCs with evidence of increased degradation. Surprisingly, we observed unchanged ribosomal binding for many of these genes using translating ribosome affinity purification. Finally, we found that multiple FMRP targets, including SHANK2, were reduced, suggesting that compensatory increases in ribosomal binding efficiency may be unable to overcome reduced transcript levels. These data further implicate dysfunction of FMRP and its targets in TSC and suggest that treatments aimed at restoring the function of these pathways may be beneficial.

Published

2021

6. Agonist-mediated switching of ion selectivity in TPC2 differentially promotes lysosomal function

Author

Susanne Gerndt, Cheng-Chang Chen, Yu-Kai Chao, Yu Yuan, Sandra Burgstaller, Anna Scotto Rosato, Einar Krogsaeter, Nicole Urban, Katharina Jacob, Ong Nam Phuong Nguyen, Meghan T Miller, Marco Keller, Angelika M Vollmar, Thomas Gudermann, Susanna Zierler, Johann Schredelseker, Michael Schaefer, Martin Biel, Roland Malli, Christian Wahl-Schott, Franz Bracher, Sandip Patel, and Christian Grimm

Subjects

TPC2, two-pore channel 2, lysosome, NAADP, PI(3,5)P2, TPC, Medicine, Science, Biology (General), QH301-705.5

Abstract

Ion selectivity is a defining feature of a given ion channel and is considered immutable. Here we show that ion selectivity of the lysosomal ion channel TPC2, which is hotly debated (Calcraft et al., 2009; Guo et al., 2017; Jha et al., 2014; Ruas et al., 2015; Wang et al., 2012), depends on the activating ligand. A high-throughput screen identified two structurally distinct TPC2 agonists. One of these evoked robust Ca2+-signals and non-selective cation currents, the other weaker Ca2+-signals and Na+-selective currents. These properties were mirrored by the Ca2+-mobilizing messenger, NAADP and the phosphoinositide, PI(3,5)P2, respectively. Agonist action was differentially inhibited by mutation of a single TPC2 residue and coupled to opposing changes in lysosomal pH and exocytosis. Our findings resolve conflicting reports on the permeability and gating properties of TPC2 and they establish a new paradigm whereby a single ion channel mediates distinct, functionally-relevant ionic signatures on demand.

Published

2020

7. Proteomic analyses reveal misregulation of LIN28 expression and delayed timing of glial differentiation in human iPS cells with MECP2 loss-of-function.

Author

Jean J Kim, Jeffrey N Savas, Meghan T Miller, Xindao Hu, Cassiano Carromeu, Mathieu Lavallée-Adam, Beatriz C G Freitas, Alysson R Muotri, John R Yates, and Anirvan Ghosh

Subjects

Medicine, Science

Abstract

Rett syndrome (RTT) is a pervasive developmental disorder caused by mutations in MECP2. Complete loss of MECP2 function in males causes congenital encephalopathy, neurodevelopmental arrest, and early lethality. Induced pluripotent stem cell (iPSC) lines from male patients harboring mutations in MECP2, along with control lines from their unaffected fathers, give us an opportunity to identify some of the earliest cellular and molecular changes associated with MECP2 loss-of-function (LOF). We differentiated iPSC-derived neural progenitor cells (NPCs) using retinoic acid (RA) and found that astrocyte differentiation is perturbed in iPSC lines derived from two different patients. Using highly stringent quantitative proteomic analyses, we found that LIN28, a gene important for cell fate regulation and developmental timing, is upregulated in mutant NPCs compared to WT controls. Overexpression of LIN28 protein in control NPCs suppressed astrocyte differentiation and reduced neuronal synapse density, whereas downregulation of LIN28 expression in mutant NPCs partially rescued this synaptic deficiency. These results indicate that the pathophysiology of RTT may be caused in part by misregulation of developmental timing in neural progenitors, and the subsequent consequences of this disruption on neuronal and glial differentiation.

Published

2019