Abstract
myo-Inositol (Ins) and its polyphosphoinositide derivatives that are important in membrane signaling have long been held to play a special role in brain metabolism. As polyphosphoinositides turn over rapidly and are exceptionally abundant in nervous tissue, high Ins levels in the range of 2-15 mm that have been observed in brain may be necessary to maintain the rates of phosphoinositide synthesis in diverse membrane locations within neurons. Cellular concentration gradients of this magnitude indicate a dependence on active Ins transport, especially at the time of growth and differentiation. The Na(+)/myo-inositol cotransporter (SMIT1 or SLC5A3) gene is highly expressed prenatally in the central nervous system and placenta. To gain more insight into brain Ins metabolism, while ascertaining the importance of SMIT1 as a transporter, we generated mice with a homozygous targeted deletion of this gene. Newborn SMIT1(-/-) animals have no evidence of SMIT1 mRNA, a 92% reduction in the level of brain Ins, an 84% reduction in whole body Ins, and expire shortly after birth due to hypoventilation. Gross pathologic and light microscopic examinations of each organ, as well as the placenta, of embryonic day 18.5 fetuses at near term gestation were normal. Based on [(3)H]acetate incorporation into phospholipids of lung tissue explants, immunostaining of lung tissue for surfactant protein A, B, and C, and electron microscopic examination of alveolar cells, there was no evidence of abnormal pulmonary surfactant production by type 2 pneumocytes in lung. Although no histologic lesions were detected in the nervous system, electrophysiological studies of the brainstem pre-Bötzinger respiratory control center demonstrated an abnormal rhythm discharge with periods of central apnea. The cause of death can be explained by the regulatory defect in brainstem control of ventilation. This model demonstrates the critical importance of SMIT1 in the developing nervous system. The high affinity SMIT1 transporter is responsible for the Ins concentration gradient in the murine fetal-placental unit.
Highlights
Myo-Inositol (Ins)1 and its polyphosphoinositide derivatives that are important in membrane signaling have long been held to play a special role in brain metabolism [1,2,3,4]
Our study shows that the SMIT1 transporter is the primary murine transporter for the maintenance of an Ins concentration gradient during embryonic and fetal life
This high affinity active transport system is responsible for the Ins concentration gradient in the fetal-placental unit
Summary
Myo-inositol; PtdIns, phosphatidylinositol; SMIT1, Naϩ/myo-inositol cotransporter; GC/MS, gas chromatography/mass spectrometry; SP, surfactant protein; PL, phospholipid; PBS, phosphate-buffered saline; TMS, trimethysilylation; PGK, phosphoglycerokinase; BSTFA, N,O-bis(trimethylsilyl)trifluoroacetamide; TMCS, trimethylchlorosilane; E, embryonic day. The trapping of ϳ2–15 mM levels of Ins within a neuron through active transport, restricted efflux, and relatively high extracellular Ins levels as in cerebrospinal fluid may be essential to its homeostasis [4]. Concentration gradients of this magnitude indicate a dependence on active Ins transport, especially at the time of growth and differentiation [28]. To gain more insight into brain Ins metabolism, while ascertaining the importance of SMIT1 as a transporter, we generated mice with a homozygous targeted deletion of this gene and studied their phenotype
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