更新于：2024-05-01

ATP1A3

Na + K + ATP酶α亚基3

更新于：2024-05-01

基本信息

别名

ATP1A3、ATPase Na+/K+ transporting subunit alpha 3、ATPase, Na+/K+ transporting, alpha 3 polypeptide

+ [7]

简介

This is the catalytic component of the active enzyme, which catalyzes the hydrolysis of ATP coupled with the exchange of sodium and potassium ions across the plasma membrane. This action creates the electrochemical gradient of sodium and potassium ions, providing the energy for active transport of various nutrients.

关联

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100 项与 ATP1A3 相关的转化医学

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0 项与 ATP1A3 相关的专利（医药）

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388

项与 ATP1A3 相关的文献（医药）

2024-01-19·Genes & genomics

Childhood-related neural genotype-phenotype in ATP1A3 mutations: comprehensive analysis.

Article

作者: Osama Y Muthaffar ; Asma Alqarni ; Jumana A Shafei ; Sarah Y Bahowarth ; Anas S Alyazidi ; Muhammad Imran Naseer

BACKGROUND:

ATP1A3 is a gene that encodes the ATPase Na + /K + transporting subunit alpha-3 isoenzyme that is widely expressed in GABAergic neurons. It maintains metabolic balance and neurotransmitter movement. These pathways are essential for the proper functioning of the nervous system. A mutation in the ATP1A3 gene demonstrates remarkable genotype-phenotype heterogeneity.

OBJECTIVES:

To provide insight into patients with ATP1A3 mutation.

MATERIAL AND METHODS:

These cases were identified using next generation sequencing. The patients' clinical and genetic data were retrieved. Detailed revision of the literature was conducted to illustrate and compare findings. The clinical, genetical, neuroimaging, and electrophysiological data of all pediatric patients were extracted.

RESULTS:

The study included 14 females and 12 males in addition to two novel females cases. Their mean current age is 6.3 ± 4.24 years. There were 11.54% preterm pregnancies with 5 cases reporting pregnancy complications. Mean age of seizure onset was 1.07 ± 1.06 years. Seizure semiology included generalized tonic-clonic, staring spells, tonic-clonic, and others. Levetiracetam was the most frequently used Anti-seizure medication. The three most frequently reported classical symptoms included alternating hemiplegia of childhood (50%), cerebellar ataxia (50%), and optic atrophy (23.08%). Non-classical symptoms included dystonia (73.08%), paroxysmal dyskinesias (34.62%), and encephalopathy (26.92%). Developmental delay was reported among 84.62% in cognitive, 92.31% in sensorimotor, 80.77% in speech, and 76.92% in socioemotional. EEG and MRI were non-specific.

CONCLUSION:

Our study demonstrated high heterogeneity among patients with pathogenic variants in the ATP1A3 gene. Such variation is multifactorial and can be a predisposition of wide genetic and clinical variables. Many patients shared few similarities in their genetic map including repeatedly reported de novo, heterozygous, mutations in the gene. Clinically, higher females prevalence of atypical presentation was noted. These findings are validated with prior evidence and the comprehensive analysis in this study.

2024-01-01·Lin chuang er bi yan hou tou jing wai ke za zhi = Journal of clinical otorhinolaryngology, head, and neck surgery

[Clinical features of CAPOS syndrome caused by maternal ATP1A3 gene variation: a case report].

Article

作者: Yun Gao ; Fengjiao Li ; Rong Luo ; Guohui Chen ; Danyang Li ; Dayong Wang ; Qiuju Wang

CAPOS syndrome is an autosomal dominant neurological disorder caused by mutations in the ATP1A3 gene. Initial symptoms, often fever-induced, include recurrent acute ataxic encephalopathy in childhood, featuring cerebellar ataxia, optic atrophy, areflflexia, sensorineural hearing loss, and in some cases, pes cavus. This report details a case of CAPOS syndrome resulting from a maternal ATP1A3 gene mutation. Both the child and her mother exhibited symptoms post-febrile induction,including severe sensorineural hearing loss in both ears, ataxia, areflexia, and decreased vision. Additionally, the patient's mother presented with pes cavus. Genetic testing revealed a c. 2452G>A（Glu818Lys） heterozygous mutation in theATP1A3 gene in the patient . This article aims to enhance clinicians' understanding of CAPOS syndrome, emphasizing the case's clinical characteristics, diagnostic process, treatment, and its correlation with genotypeic findings.

2023-12-14·European journal of human genetics : EJHG

Exome sequencing of ATP1A3-negative cases of alternating hemiplegia of childhood reveals SCN2A as a novel causative gene.

Article

作者: Eleni Panagiotakaki ; Francesco D Tiziano ; Mohamad A Mikati ; Lisanne S Vijfhuizen ; Sophie Nicole ; Gaetan Lesca ; Emanuela Abiusi ; Agnese Novelli ; Lorena Di Pietro ; I.B.AHC Consortium ; IAHCRC Consortium ; Aster V E Harder ; Nicole M Walley ; Elisa De Grandis ; Anne-Lise Poulat ; Vincent Des Portes ; Anne Lépine ; Marie-Cecile Nassogne ; Alexis Arzimanoglou ; Rosaria Vavassori ; Jan Koenderink ; Christopher H Thompson ; Alfred L George ; Fiorella Gurrieri ; Arn M J M van den Maagdenberg ; Erin L Heinzen

Alternating hemiplegia of childhood (AHC) is a rare neurodevelopment disorder that is typically characterized by debilitating episodic attacks of hemiplegia, seizures, and intellectual disability. Over 85% of individuals with AHC have a de novo missense variant in ATP1A3 encoding the catalytic α3 subunit of neuronal Na^+/K⁺ ATPases. The remainder of the patients are genetically unexplained. Here, we used next-generation sequencing to search for the genetic cause of 26 ATP1A3-negative index patients with a clinical presentation of AHC or an AHC-like phenotype. Three patients had affected siblings. Using targeted sequencing of exonic, intronic, and flanking regions of ATP1A3 in 22 of the 26 index patients, we found no ultra-rare variants. Using exome sequencing, we identified the likely genetic diagnosis in 9 probands (35%) in five genes, including RHOBTB2 (n = 3), ATP1A2 (n = 3), ANK3 (n = 1), SCN2A (n = 1), and CHD2 (n = 1). In follow-up investigations, two additional ATP1A3-negative individuals were found to have rare missense SCN2A variants, including one de novo likely pathogenic variant and one likely pathogenic variant for which inheritance could not be determined. Functional evaluation of the variants identified in SCN2A and ATP1A2 supports the pathogenicity of the identified variants. Our data show that genetic variants in various neurodevelopmental genes, including SCN2A, lead to AHC or AHC-like presentation. Still, the majority of ATP1A3-negative AHC or AHC-like patients remain unexplained, suggesting that other mutational mechanisms may account for the phenotype or that cases may be explained by oligo- or polygenic risk factors.

项与 ATP1A3 相关的新闻（医药）

2021-04-14
·BioSpace

StrideBio Announces a Multi-technology License and Master SRA with Duke University to Advance Next-generation Gene Therapies

April 14, 2021 11:05 UTC StrideBio receives exclusive license to novel cross-species evolved AAV vectors and an enzymatic approach for neutralizing antibody evasion Master Sponsored Research Agreement will support collaborative research and development of multiple novel gene therapies with ability to expand First therapeutic program under the collaboration is a gene therapy targeting Alternating Hemiplegia of Childhood, a devastating pediatric neurological disorder with no effective treatment RESEARCH TRIANGLE PARK, N.C.--(BUSINESS WIRE)-- StrideBio, Inc., a leading developer of novel adeno-associated viral (AAV)-based gene therapies, today announced the signing of a multi-technology collaboration with Duke University that will enable novel next-generation gene therapies against a broad range of disorders. StrideBio is advancing multiple products incorporating these technologies with an initial program targeting a novel treatment for the pediatric neurological disorder Alternating Hemiplegia of Childhood (AHC). The agreements announced today provide StrideBio an exclusive license to multiple technologies that will enable best-in-class next-generation gene therapies developed at Duke University. Included are novel engineered AAV vectors which complement StrideBio’s existing STRIVETM capsid engineering platform, having been selected through a cross-species evolution that results in significantly enhanced tropism and potency versus AAV9 across a wide range of tissues such as CNS, skeletal and cardiac muscle. Data on these novel vectors were presented by Duke researcher and StrideBio co-founder, Aravind Asokan, Ph.D., at the American Society of Gene & Cell Therapy 23rd Annual Meeting in an abstract titled “Cross Species Evolution of Synthetic AAV Strains for Clinical Translation” (Gonzalez et al., ASGCT 2020, Abstract 24). In addition, StrideBio has licensed exclusive rights covering a novel use of IgG-degrading enzyme IdeZ to clear neutralizing antibodies in conjunction with AAV gene therapy administration. This innovative approach was recently published by members of the Asokan Lab in a manuscript titled “Rescuing AAV gene transfer from neutralizing antibodies with an IgG-degrading enzyme” (Elmore et al., JCI Insight, 2020, 5(19): e139881). Finally, StrideBio obtained license rights to a novel gene therapy approach for the treatment of AHC recently published by Duke researcher Mohamad Mikati, M.D., in a manuscript titled “AAV Mediated Gene Therapy in the Mashlool, Atp1a3Mashl/+, Mouse Model of Alternating Hemiplegia of Childhood” (Hunanyan et al., Human Gene Therapy, February 12, 2021). Under the Master Sponsored Research Agreement (SRA), StrideBio will fund collaborative work to advance novel gene therapies initially against AHC and other undisclosed targets. AHC is a devastating pediatric neurological disorder with mutations in a causative gene, ATP1A3, that was first identified by a team of Duke University researchers, including Dr. Mikati, in 2012. StrideBio will work closely with Dr. Mikati using a mouse model of AHC developed in his lab to select and rapidly advance a novel gene therapy candidate to the clinic, leveraging the engineered AAV vectors developed by StrideBio along with its manufacturing and translational development capabilities. The Master SRA between StrideBio and Duke University also provides a framework for additional new programs to be brought under the collaboration. These programs will aim to utilize novel engineered AAV capsids developed by StrideBio to improve potency, evade neutralizing antibodies and enhance specific tropism to tissues of interest. One additional undisclosed program targeting the CNS vasculature has been initiated. “We are very excited to partner with Duke University to advance these technologies that can improve and expand on the potential benefits of gene therapies for patients who desperately need them,” stated Sapan Shah, Ph.D., Chief Executive Officer, StrideBio, Inc. “We look forward to working together with a fantastic group of Duke researchers and clinicians to bring next-generation AAV-based gene therapies to patients with rare CNS diseases and beyond, starting with Alternating Hemiplegia of Childhood.” “This License and Master Sponsored Research Agreement will ensure that these innovative technologies receive the resources and expertise necessary to develop treatments that can ultimately benefit patients. We are delighted to have StrideBio as a partner on this important effort in the gene therapy area,” commented Robin Rasor, Executive Director of the Office of Licensing and Ventures, Duke University. Specific terms were not disclosed, but include equity, upfront and milestone-driven payments, and sponsored research commitments from StrideBio to Duke University, along with royalties on future product sales. About StrideBio Founded in 2015 based on the groundbreaking research of Mavis Agbandje-McKenna, Ph.D., and Aravind Asokan, Ph.D., StrideBio, Inc., is a fully integrated gene therapy company focused on creating best-in-class genetic medicines with life-changing or curative potential for children and adults. Our proprietary structure-inspired adeno-associated viral (AAV) vector engineering platform (STRIVE™) creates unique and differentiated capsids that overcome current limitations of first-generation gene therapies. Key targeted improvements include reduced seroprevalence, improved tropism for specific cell types, liver de-targeting and increased gene transfer efficiency, with the potential for improved safety and reduced doses in the clinic. StrideBio is advancing a robust pipeline of gene therapy candidates enabled by these novel engineered capsids, initially focused on genetically defined CNS and cardiovascular disorders. Combined with our genetic construct design expertise and in-house manufacturing capability at a 1000L scale, we are well positioned to advance novel best-in-class AAV gene therapies. StrideBio is based in a state-of-the-art 40,000-square-foot facility in Research Triangle Park, N.C., which houses our offices, research labs and in-house AAV manufacturing facilities. For more information, please visit or follow us on LinkedIn. View source version on businesswire.com: Contacts Carolyn Noyes or Susan Sharpe MacDougall 781-235-3060 cnoyes@macbiocom.com ssharpe@macbiocom.com Source: StrideBio, Inc. View this news release online at:

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