Abstract
ARX/Arx is a homeodomain-containing transcription factor necessary for the specification and early maintenance of pancreatic endocrine α-cells. Many transcription factors important to pancreas development, including ARX/Arx, are also crucial for proper brain development. Although null mutations of ARX in human patients result in the severe neurologic syndrome XLAG (X-linked lissencephaly associated with abnormal genitalia), the most common mutation is the expansion of the first polyalanine tract of ARX, which results primarily in the clinical syndrome ISSX (infantile spasms). Mouse models of XLAG, ISSX and other human ARX mutations demonstrate a direct genotype-phenotype correlation in ARX-related neurologic disorders. Furthermore, mouse models utilizing a polyalanine tract expansion mutation have illustrated critical developmental differences between null mutations and expansion mutations in the brain, revealing context-specific defects. Although Arx is known to be required for the specification and early maintenance of pancreatic glucagon-producing α-cells, the consequences of the Arx polyalanine expansion on pancreas development remain unknown. Here we report that mice with an expansion mutation in the first polyalanine tract of Arx exhibit impaired α-cell specification and maintenance, with gradual α-cell loss due to apoptosis. This is in contrast to the re-specification of α-cells into β- and δ-cells that occurs in mice null for Arx. Overall, our analysis of an Arx polyalanine expansion mutation on pancreatic development suggests that impaired α-cell function might also occur in ISSX patients.
Highlights
Aristaless-related homeobox gene (Arx) encodes a homeodomain containing transcription factor that is expressed in the brain, testis, muscle, pancreas, and digestive tract [1,2,3]
Arx expanded mouse model (ArxE) mice retain a subset of glucagon-producing a-cells at embryonic day (E) 15.5 To determine the effect of an Arx expansion mutation on a-cell specification and maintenance, hemizygous ArxExpanded/Y mutant mice were obtained by crossing heterozygous ArxExpanded/+ females to wild-type Arx+/Y males
This study demonstrates that expansion of the first polyalanine tract of Arx results in impaired specification and maintenance of endocrine a-cells through a mechanism of programmed cell death, as opposed to a-cell fate re-specification
Summary
Aristaless-related homeobox gene (Arx) encodes a homeodomain containing transcription factor that is expressed in the brain, testis, muscle, pancreas, and digestive tract [1,2,3]. Arx is essential for the proper development and migration of GABAergic interneurons and has a role in cortical ventricular zone proliferation [4,5]. Mutations of ARX result in a spectrum of neurologic disorders, the most severe clinical presentation being X-linked lissencephaly associated with abnormal genitalia (XLAG) [5]. XLAG, which has been linked to null and missense mutations in ARX, is characterized by a severe brain malformation, termed lissencephaly, corpus callosum agenesis, neonatal-onset intractable epilepsy, and early death [6]. Arx null mice phenocopy the clinical presentation of XLAG patients, displaying cortical brain malformations and agenesis with lethality within 24-hours of birth [4,5]. Histological and molecular analyses reveal a dual function for Arx in radial and tangential migration of GABA-ergic interneurons in mice [7]
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