HREM, RNAseq and cell-cycle analyses reveal the role of the G2/M-regulatory protein, Wee1, on the survivability of chicken embryos during diapause.

The IGF2BP family of RNA binding proteins consists of three paralogs that regulate intracellular RNA localization, RNA stability, and translational control. Although IGF2BP1 and 3 are oncofetal proteins, IGF2BP2 expression is maintained in many tissues, including the heart, into adulthood. Previous studies indicated that IGF2BP2 is upregulated in cardiomyocytes during cardiac stress and remodelling and returns to normal levels in recovering hearts. These results suggested that IGF2BP2 might play an adaptive role during cardiac stress and recovery. Using a conditional, inducible transgenic mouse line, we found that enhanced expression of the IGF2BP2 transgene in newborn or adult hearts leads to dilated cardiomyopathy (DCM), with remodelling, fibrosis, and death within 3-4 weeks. Downregulation of the transgene after 2 weeks, however, rescues these mice, with complete recovery by 12 weeks. Proteomic analysis identified a downregulation of sarcomeric and mitochondrial proteins in hearts overexpressing IGF2BP2, and electron microscopy revealed fragmented mitochondria and elongated, thinner sarcomeres. Consistent with these results, IGF2BP2 is upregulated in patients with DCM or after myocardial infarction. These results show that cardiac stress upregulates IGF2BP2, leading to remodelling and compensation of the heart. Prolonged expression, however, leads to heart failure and death, making it an attractive target for therapeutic intervention.

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IGF2BP2 is Induced by Stress in the Heart and Mediates Dilated Cardiomyopathy

Krumbein

Oberman

Cinnamon

et al. 2022

Preprint

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Maternal exposure to environmental levels of carbamazepine induces mild growth retardation in mouse embryos

Douek-Maba

Kalev-Altman

Mordehay

et al. 2023

Preprint

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As chemical pollution is constantly increasing, the impact on the environment and public health must be investigated. This study focuses on the anticonvulsant drug carbamazepine (CBZ), which is ubiquitously present in the environment. Due to its physicochemical properties and stability during wastewater treatment, CBZ is detected in reclaimed wastewater, surface water and groundwater. In water-scarce regions heavily relying on treated wastewater for crop irrigation, CBZ is detected in arable land, produce and even in humans consuming crops irrigated with recealimed wastewater. Although environmental levels of CBZ are very low, risks associated with unintentional exposure to CBZ are essential to be revealed. In perinatal medicine, CBZ is a teratogen; its prescription to pregnant women increases the risk for fetal malformations. This raises the concern of whether environmental exposure to CBZ may also impact embryogenesis. Studies in zebrafish and chick embryos or in cell culture have indicated negative outcomes upon exposure to low CBZ levels. Yet, these systems do not recapitulate the manner by which human fetuses are exposed to pharmaceuticals via maternal uptake. Here, we employed the mouse model to determine whether maternal exposure to environmental-relevant doses of CBZ will impact embryonic development. No effects on fertility, number of gestation sacs, gross embryonic malformations or fetal survival were detected. Yet, embryos were growth-delayed compared to controls (p=0.0011), as manifested in lower embryonic stage and somite number, earlier morphological features and reduction in mitotically-active cells. This study provides the first evidence for the effect of environmental concentration of CBZ on the developmental kinetics of maternally-exposed mammalian embryos. While the developmental delay was relatively modest, its consistency in high number of biological replicates, together with the known implication of developmental delay on post-natal health, calls for further in-depth risk analyses to reveal the effects of pharmaceuticals released to the environment on public health.

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