Your search keyword '"Morini, Elisabetta"' showing total 5 results

1. Development of an oral treatment that rescues gait ataxia and retinal degeneration in a phenotypic mouse model of familial dysautonomia.

Author

Morini, Elisabetta, Chekuri, Anil, Logan, Emily M., Bolduc, Jessica M., Kirchner, Emily G., Salani, Monica, Krauson, Aram J., Narasimhan, Jana, Gabbeta, Vijayalakshmi, Grover, Shivani, Dakka, Amal, Mollin, Anna, Jung, Stephen P., Zhao, Xin, Zhang, Nanjing, Zhang, Sophie, Arnold, Michael, Woll, Matthew G., Naryshkin, Nikolai A., and Weetall, Marla

Subjects

*DYSAUTONOMIA, *RETINAL degeneration, *ORAL drug administration, *LABORATORY mice, *PERIPHERAL nervous system

Abstract

Familial dysautonomia (FD) is a rare neurodegenerative disease caused by a splicing mutation in elongator acetyltransferase complex subunit 1 (ELP1). This mutation leads to the skipping of exon 20 and a tissue-specific reduction of ELP1, mainly in the central and peripheral nervous systems. FD is a complex neurological disorder accompanied by severe gait ataxia and retinal degeneration. There is currently no effective treatment to restore ELP1 production in individuals with FD, and the disease is ultimately fatal. After identifying kinetin as a small molecule able to correct the ELP1 splicing defect, we worked on its optimization to generate novel splicing modulator compounds (SMCs) that can be used in individuals with FD. Here, we optimize the potency, efficacy, and bio-distribution of second-generation kinetin derivatives to develop an oral treatment for FD that can efficiently pass the blood-brain barrier and correct the ELP1 splicing defect in the nervous system. We demonstrate that the novel compound PTC258 efficiently restores correct ELP1 splicing in mouse tissues, including brain, and most importantly, prevents the progressive neuronal degeneration that is characteristic of FD. Postnatal oral administration of PTC258 to the phenotypic mouse model TgFD9;Elp1 Δ20/flox increases full-length ELP1 transcript in a dose-dependent manner and leads to a 2-fold increase in functional ELP1 in the brain. Remarkably, PTC258 treatment improves survival, gait ataxia, and retinal degeneration in the phenotypic FD mice. Our findings highlight the great therapeutic potential of this novel class of small molecules as an oral treatment for FD. Morini et al. describe the optimization of an oral treatment for familial dysautonomia (FD), a rare neurodegenerative disease caused by a splicing mutation in ELP1. Their compound restores correct ELP1 splicing in every tissue, including brain, and prevents gait ataxia and retinal degeneration in a mouse model of FD. [ABSTRACT FROM AUTHOR]

Published

2023

2. ELP1 Splicing Correction Reverses Proprioceptive Sensory Loss in Familial Dysautonomia.

Author

Morini, Elisabetta, Gao, Dadi, Montgomery, Connor M., Salani, Monica, Mazzasette, Chiara, Krussig, Tobias A., Swain, Brooke, Dietrich, Paula, Narasimhan, Jana, Gabbeta, Vijayalakshmi, Dakka, Amal, Hedrick, Jean, Zhao, Xin, Weetall, Marla, Naryshkin, Nikolai A., Wojtkiewicz, Gregory G., Ko, Chien-Ping, Talkowski, Michael E., Dragatsis, Ioannis, and Slaugenhaupt, Susan A.

Subjects

*DYSAUTONOMIA, *NEMALINE myopathy, *PERIPHERAL nervous system, *SMALL molecules, *ETIOLOGY of diseases

Abstract

Familial dysautonomia (FD) is a recessive neurodegenerative disease caused by a splice mutation in Elongator complex protein 1 (ELP1 , also known as IKBKAP); this mutation leads to variable skipping of exon 20 and to a drastic reduction of ELP1 in the nervous system. Clinically, many of the debilitating aspects of the disease are related to a progressive loss of proprioception; this loss leads to severe gait ataxia, spinal deformities, and respiratory insufficiency due to neuromuscular incoordination. There is currently no effective treatment for FD, and the disease is ultimately fatal. The development of a drug that targets the underlying molecular defect provides hope that the drastic peripheral neurodegeneration characteristic of FD can be halted. We demonstrate herein that the FD mouse TgFD9 ; Ikbkap Δ20/flox recapitulates the proprioceptive impairment observed in individuals with FD, and we provide the in vivo evidence that postnatal correction, promoted by the small molecule kinetin, of the mutant ELP1 splicing can rescue neurological phenotypes in FD. Daily administration of kinetin starting at birth improves sensory-motor coordination and prevents the onset of spinal abnormalities by stopping the loss of proprioceptive neurons. These phenotypic improvements correlate with increased amounts of full-length ELP1 mRNA and protein in multiple tissues, including in the peripheral nervous system (PNS). Our results show that postnatal correction of the underlying ELP1 splicing defect can rescue devastating disease phenotypes and is therefore a viable therapeutic approach for persons with FD. [ABSTRACT FROM AUTHOR]

Published

2019

3. Tissue- and cell-type-specific molecular and functional signatures of 16p11.2 reciprocal genomic disorder across mouse brain and human neuronal models.

Author

Tai, Derek J.C., Razaz, Parisa, Erdin, Serkan, Gao, Dadi, Wang, Jennifer, Nuttle, Xander, de Esch, Celine E., Collins, Ryan L., Currall, Benjamin B., O'Keefe, Kathryn, Burt, Nicholas D., Yadav, Rachita, Wang, Lily, Mohajeri, Kiana, Aneichyk, Tatsiana, Ragavendran, Ashok, Stortchevoi, Alexei, Morini, Elisabetta, Ma, Weiyuan, and Lucente, Diane

Subjects

*BROWN adipose tissue, *RNA metabolism, *GABAERGIC neurons, *CELL physiology, *WHITE adipose tissue, *NEURAL stem cells, *AUTISM spectrum disorders

Abstract

Chromosome 16p11.2 reciprocal genomic disorder, resulting from recurrent copy-number variants (CNVs), involves intellectual disability, autism spectrum disorder (ASD), and schizophrenia, but the responsible mechanisms are not known. To systemically dissect molecular effects, we performed transcriptome profiling of 350 libraries from six tissues (cortex, cerebellum, striatum, liver, brown fat, and white fat) in mouse models harboring CNVs of the syntenic 7qF3 region, as well as cellular, transcriptional, and single-cell analyses in 54 isogenic neural stem cell, induced neuron, and cerebral organoid models of CRISPR-engineered 16p11.2 CNVs. Transcriptome-wide differentially expressed genes were largely tissue-, cell-type-, and dosage-specific, although more effects were shared between deletion and duplication and across tissue than expected by chance. The broadest effects were observed in the cerebellum (2,163 differentially expressed genes), and the greatest enrichments were associated with synaptic pathways in mouse cerebellum and human induced neurons. Pathway and co-expression analyses identified energy and RNA metabolism as shared processes and enrichment for ASD-associated, loss-of-function constraint, and fragile X messenger ribonucleoprotein target gene sets. Intriguingly, reciprocal 16p11.2 dosage changes resulted in consistent decrements in neurite and electrophysiological features, and single-cell profiling of organoids showed reciprocal alterations to the proportions of excitatory and inhibitory GABAergic neurons. Changes both in neuronal ratios and in gene expression in our organoid analyses point most directly to calretinin GABAergic inhibitory neurons and the excitatory/inhibitory balance as targets of disruption that might contribute to changes in neurodevelopmental and cognitive function in 16p11.2 carriers. Collectively, our data indicate the genomic disorder involves disruption of multiple contributing biological processes and that this disruption has relative impacts that are context specific. [Display omitted] The 16p11.2 genomic disorder involves deletion and duplication of a contiguous set of genes, resulting in neurodevelopmental and other abnormalities. On the basis of comparisons of mouse models and human neuronal cells, the effects of these lesions on genome-wide gene expression and cellular function are highly dependent on cellular context. [ABSTRACT FROM AUTHOR]

Published

2022

4. Rescue of a familial dysautonomia mouse model by AAV9-Exon-specific U1 snRNA.

Author

Romano, Giulia, Riccardi, Federico, Bussani, Erica, Vodret, Simone, Licastro, Danilo, Ragone, Isabella, Ronzitti, Giuseppe, Morini, Elisabetta, Slaugenhaupt, Susan A., and Pagani, Franco

Subjects

*DYSAUTONOMIA, *LABORATORY mice, *SMALL nuclear RNA, *ANIMAL disease models, *DORSAL root ganglia, *RNA splicing

Abstract

Familial dysautonomia (FD) is a currently untreatable, neurodegenerative disease caused by a splicing mutation (c.2204+6T>C) that causes skipping of exon 20 of the elongator complex protein 1 (ELP1) pre-mRNA. Here, we used adeno-associated virus serotype 9 (AAV9-U1-FD) to deliver an exon-specific U1 (ExSpeU1) small nuclear RNA, designed to cause inclusion of ELP1 exon 20 only in those cells expressing the target pre-mRNA, in a phenotypic mouse model of FD. Postnatal systemic and intracerebral ventricular treatment in these mice increased the inclusion of ELP1 exon 20. This also augmented the production of functional protein in several tissues including brain, dorsal root, and trigeminal ganglia. Crucially, the treatment rescued most of the FD mouse mortality before one month of age (89% vs 52%). There were notable improvements in ataxic gait as well as renal (serum creatinine) and cardiac (ejection fraction) functions. RNA-seq analyses of dorsal root ganglia from treated mice and human cells overexpressing FD-ExSpeU1 revealed only minimal global changes in gene expression and splicing. Overall then, our data prove that AAV9-U1-FD is highly specific and will likely be a safe and effective therapeutic strategy for this debilitating disease. Familial dysautonomia (FD) is a currently untreatable neurodegenerative disease. We evaluated the therapeutic efficacy of a new class of RNA molecules in an FD mouse model. The treatment, recovering most of the mortality and neuromuscular function, holds promise for clinical application. [ABSTRACT FROM AUTHOR]

Published

2022

5. Tissue- and cell-type-specific molecular and functional signatures of 16p11.2 reciprocal genomic disorder across mouse brain and human neuronal models.

Author

Tai, Derek J.C., Razaz, Parisa, Erdin, Serkan, Gao, Dadi, Wang, Jennifer, Nuttle, Xander, de Esch, Celine E., Collins, Ryan L., Currall, Benjamin B., O'Keefe, Kathryn, Burt, Nicholas D., Yadav, Rachita, Wang, Lily, Mohajeri, Kiana, Aneichyk, Tatsiana, Ragavendran, Ashok, Stortchevoi, Alexei, Morini, Elisabetta, Ma, Weiyuan, and Lucente, Diane

Subjects

*MICE, *HUMAN beings

Published

2024