Abstract
Amniotic fluid volume during mid-to-late gestation depends mainly on the urine excretion from the foetal kidneys and partly on the fluid secretion from the foetal lungs during foetal breathing-like movements. Urine is necessary for foetal breathing-like movements, which is critical for foetal lung development. Bilateral renal agenesis and/or obstruction of the urinary tract lead to oligohydramnios, which causes infant death within a short period after birth due to pulmonary hypoplasia. Lrp4, which functions as an agrin receptor, is essential for the formation of neuromuscular junctions. Herein, we report novel phenotypes of Lrp4 knockout (Lrp4−/−) mice. Most Lrp4−/− foetuses showed unilateral or bilateral kidney agenesis, and Lrp4 knockout resulted in polyhydramnios. The loss of Lrp4 compromised foetal swallowing and breathing-like movements and downregulated the expression of aquaporin-9 in the foetal membrane and aquaporin-1 in the placenta, which possibly affected the amniotic fluid clearance. These results suggest that amniotic fluid removal was compromised in Lrp4−/− foetuses, resulting in polyhydramnios despite the impairment of urine production. Our findings indicate that amniotic fluid removal plays an essential role in regulating the amniotic fluid volume.
Highlights
Movements, which is critical for foetal lung development, and it aids in supplying proline, a critical amino acid for lung maturation
We report the novel phenotypes of Lrp[4] knockout mice (Lrp4−/−) generated in this study
Among Lrp4−/− mice observed at E18.5 and E17.5, we found that 26% (77 of 295 Lrp4−/− foetuses) exhibited bilateral kidney agenesis, whereas 43% (126 of 295 Lrp4−/− foetuses) showed unilateral kidney agenesis (Fig. 2b)
Summary
Movements, which is critical for foetal lung development, and it aids in supplying proline, a critical amino acid for lung maturation. Bilateral renal agenesis and/or obstruction of the urinary tract cause oligohydramnios, resulting in the death of infants within a short period after birth due to pulmonary hypoplasia[4]. Mice bearing functional Lrp4-null mutations die at birth because it fails to form neuromuscular junctions[8]. We report the novel phenotypes of Lrp[4] knockout mice (Lrp4−/−) generated in this study. Lrp4−/− mice died at birth due to their inability to breathe, and 69% of Lrp4−/− mice displayed bilateral or unilateral kidney agenesis. The coexistence of polyhydramnios and bilateral kidney agenesis represented an unexpected finding, since foetal urine, a major source of amniotic fluid during the perinatal stage, is not produced by the kidneys. We investigated the mechanisms underlying polyhydramnios observed in Lrp4−/− mice with bilateral kidney agenesis
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