Early-Onset Movement Disorder Syndrome Caused by Biallelic Variants in PDE1B Encoding Phosphodiesterase 1B.

IF 7.6

Movement disorders : official journal of the Movement Disorder Society Pub Date : 2025-06-10 DOI:10.1002/mds.30249

Tomer Poleg, Noam Hadar, Eyal Kristal, Nicola Y Roberts, Vadim Dolgin, Ilana Aminov, Amit Safran, Nadav Agam, Matan Jean, Ofek Freund, Eamonn G Sheridan, James A Poulter, Michelle L Thompson, Yusra Algoos, Salma Al-Qahtani, Lama AlAbdi, Sateesh Maddirevula, Verity Hartill, Henry Houlden, Reza Maroofian, Amit Nahum, Ohad S Birk

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Abstract

Background: Breakdown of cyclic adenosine monophosphate (cAMP) and cyclic guanosine monophosphate (cGMP) in basal ganglia cells through hydrolysis of diesteric bonds, primarily by PDE10A and PDE1B, is essential for normal human movement. While biallelic loss-of-function variants in PDE10A are known to cause hyperkinetic movement disorders, the role of PDE1B in human disease has not been characterized.

Objectives: We aimed to define the phenotypic and molecular characteristics of a novel autosomal recessive disorder caused by biallelic PDE1B variants.

Methods: Clinical phenotyping by senior geneticists and neurologists, followed by whole exome sequencing, segregation analysis (Sanger sequencing), and molecular studies, including mini-gene splicing assays and protein studies in transfected HEK293 cells.

Results: Seven affected individuals from five unrelated pedigrees presented with an apparently autosomal recessive disorder characterized by hypotonia in infancy, progressing to ataxia and dystonia in early childhood, with developmental delay and intellectual disability. Biallelic PDE1B variants were identified in all affected individuals: three truncating (p.Q45*, p.Q86*, p.S298Afs*6) and three splicing variants (c.594 + 2 T>G, c.735 + 5G>A, c.837-1G>C). Functional studies confirmed that the truncating variants caused loss of the catalytic domain, resulting in truncated or absent functional protein. Splicing variants led to exon skipping, frameshifts, and catalytic domain disruption. These findings establish a causative link between biallelic PDE1B variants and the observed clinical phenotype.

Conclusions: Biallelic loss-of-function variants in PDE1B underlie a novel early-onset movement disorder resembling the phenotype associated with PDE10A deficiency. © 2025 The Author(s). Movement Disorders published by Wiley Periodicals LLC on behalf of International Parkinson and Movement Disorder Society.

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编码磷酸二酯酶1B的PDE1B双等位基因变异引起的早发性运动障碍综合征。

背景：环腺苷单磷酸（cAMP）和环鸟苷单磷酸（cGMP）在基底节节细胞中主要由PDE10A和PDE1B水解二酯键，对人体正常运动至关重要。虽然已知PDE10A的双等位基因功能丧失变异会导致多动运动障碍，但PDE1B在人类疾病中的作用尚未被描述。目的：我们旨在确定由双等位基因PDE1B变异引起的一种新型常染色体隐性遗传病的表型和分子特征。方法：由资深遗传学家和神经学家进行临床表型分析，然后进行全外显子组测序、分离分析（Sanger测序）和分子研究，包括转染HEK293细胞的小基因剪接试验和蛋白质研究。结果：来自5个不相关家系的7例患者表现出明显的常染色体隐性遗传病，其特征是婴儿期张力低下，儿童早期发展为共济失调和张力障碍，并伴有发育迟缓和智力障碍。在所有受影响个体中均鉴定出PDE1B双等位基因变异：3个截断型变异（p.Q45*, p.Q86*, p.S298Afs*6）和3个剪接型变异（c.594 + 2t b> G, c.735 + 5G>A, c.837-1G>C）。功能研究证实，截断变异体导致催化结构域丢失，导致功能蛋白被截断或缺失。剪接变异体导致外显子跳跃、帧移和催化结构域破坏。这些发现建立了双等位基因PDE1B变异与观察到的临床表型之间的因果关系。结论：PDE1B的双等位基因功能丧失变异是一种新型早发性运动障碍的基础，类似于PDE10A缺乏症的表型。©2025作者。Wiley期刊有限责任公司代表国际帕金森和运动障碍学会出版的《运动障碍》。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Movement disorders : official journal of the Movement Disorder Society

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