PURPOSE OF REVIEW: This article reviews clinical, genetic, and therapeutic advances in spinal muscular atrophies (SMAs), inherited disorders characterized by motor neuron loss and muscle weakness. RECENT FINDINGS: There has been progress in defining the clinical and genetic features of at least 16 distinct forms of SMA. The genes associated with 14 of these disorders have been identified in the last decade, including four within the last year: TRPV4, ATP7A, VRK1, and HSPB3. Genetic testing is now available for many SMAs, providing important diagnostic and prognostic information. Cell and animal models of SMAs have been used to further understand how mutations in SMA-associated genes, which code for proteins involved in diverse functions such as transcriptional regulation, RNA processing, and cytoskeletal dynamics, lead to motor neuron dysfunction and loss. In the last year, there has also been remarkable progress in preclinical therapeutics development for proximal SMA using gene therapy, antisense oligonucleotides, and small molecules. SUMMARY: The advances in the clinical and genetic characterization of different forms of SMAs have important implications for clinical evaluation and management of patients. The identification of multiple, novel SMA-causing genes will lead to an improved understanding of motor neuron disease biology and may provide novel targets for therapeutics development.
PURPOSE OF REVIEW: This article reviews clinical, genetic, and therapeutic advances in spinal muscular atrophies (SMAs), inherited disorders characterized by motor neuron loss and muscle weakness. RECENT FINDINGS: There has been progress in defining the clinical and genetic features of at least 16 distinct forms of SMA. The genes associated with 14 of these disorders have been identified in the last decade, including four within the last year: TRPV4, ATP7A, VRK1, and HSPB3. Genetic testing is now available for many SMAs, providing important diagnostic and prognostic information. Cell and animal models of SMAs have been used to further understand how mutations in SMA-associated genes, which code for proteins involved in diverse functions such as transcriptional regulation, RNA processing, and cytoskeletal dynamics, lead to motor neuron dysfunction and loss. In the last year, there has also been remarkable progress in preclinical therapeutics development for proximal SMA using gene therapy, antisense oligonucleotides, and small molecules. SUMMARY: The advances in the clinical and genetic characterization of different forms of SMAs have important implications for clinical evaluation and management of patients. The identification of multiple, novel SMA-causing genes will lead to an improved understanding of motor neuron disease biology and may provide novel targets for therapeutics development.
Authors: Anne Rietz; Hongxia Li; Kevin M Quist; Jonathan J Cherry; Christian L Lorson; Barrington G Burnett; Nicholas L Kern; Alyssa N Calder; Melanie Fritsche; Hrvoje Lusic; Patrick J Boaler; Sungwoon Choi; Xuechao Xing; Marcie A Glicksman; Gregory D Cuny; Elliot J Androphy; Kevin J Hodgetts Journal: J Med Chem Date: 2017-05-19 Impact factor: 7.446
Authors: Randall S Prather; Monique Lorson; Jason W Ross; Jeffrey J Whyte; Eric Walters Journal: Annu Rev Anim Biosci Date: 2013-01-03 Impact factor: 8.923
Authors: Zhenxi Zhang; Anna Maria Pinto; Lili Wan; Wei Wang; Michael G Berg; Isabela Oliva; Larry N Singh; Christopher Dengler; Zhi Wei; Gideon Dreyfuss Journal: Proc Natl Acad Sci U S A Date: 2013-11-04 Impact factor: 11.205
Authors: Kornelia Neveling; Lilian A Martinez-Carrera; Irmgard Hölker; Angelien Heister; Aad Verrips; Seyyed Mohsen Hosseini-Barkooie; Christian Gilissen; Sascha Vermeer; Maartje Pennings; Rowdy Meijer; Margot te Riele; Catharina J M Frijns; Oksana Suchowersky; Linda MacLaren; Sabine Rudnik-Schöneborn; Richard J Sinke; Klaus Zerres; R Brian Lowry; Henny H Lemmink; Lutz Garbes; Joris A Veltman; Helenius J Schelhaas; Hans Scheffer; Brunhilde Wirth Journal: Am J Hum Genet Date: 2013-05-09 Impact factor: 11.025