The Lhx9 homeobox gene controls pineal gland development and prevents postnatal hydrocephalus

F Yamazaki, M Møller, C Fu, SJ Clokie… - Brain Structure and …, 2015 - Springer
F Yamazaki, M Møller, C Fu, SJ Clokie, A Zykovich, SL Coon, DC Klein, MF Rath
Brain Structure and Function, 2015Springer
Lhx9 is a member of the LIM homeobox gene family. It is expressed during mammalian
embryogenesis in the brain including the pineal gland. Deletion of Lhx9 results in sterility
due to failure of gonadal development. The current study was initiated to investigate Lhx9
biology in the pineal gland. Lhx9 is highly expressed in the developing pineal gland of the
rat with transcript abundance peaking early in development; transcript levels decrease
postnatally to nearly undetectable levels in the adult, a temporal pattern that is generally …
Abstract
Lhx9 is a member of the LIM homeobox gene family. It is expressed during mammalian embryogenesis in the brain including the pineal gland. Deletion of Lhx9 results in sterility due to failure of gonadal development. The current study was initiated to investigate Lhx9 biology in the pineal gland. Lhx9 is highly expressed in the developing pineal gland of the rat with transcript abundance peaking early in development; transcript levels decrease postnatally to nearly undetectable levels in the adult, a temporal pattern that is generally similar to that reported for Lhx9 expression in other brain regions. Studies with C57BL/6J Lhx9 −/− mutant mice revealed marked alterations in brain and pineal development. Specifically, the superficial pineal gland is hypoplastic, being reduced to a small cluster of pinealocytes surrounded by meningeal and vascular tissue. The deep pineal gland and the pineal stalk are also reduced in size. Although the brains of neonatal Lhx9 −/− mutant mice appear normal, severe hydrocephalus develops in about 70 % of the Lhx9 / mice at 5–8 weeks of age; these observations are the first to document that deletion of Lhx9 results in hydrocephalus and as such indicate that Lhx9 contributes to the maintenance of normal brain structure. Whereas hydrocephalus is absent in neonatal Lhx9 −/−mutant mice, the neonatal pineal gland in these animals is hypoplastic. Accordingly, it appears that Lhx9 is essential for early development of the mammalian pineal gland and that this effect is not secondary to hydrocephalus.
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