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LncRNA Tuna is activated in cadmium-induced placental insufficiency and drives the NRF2-mediated oxidative stress response
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LncRNA Tuna is activated in cadmium-induced placental insufficiency and drives the NRF2-mediated oxidative stress response
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LncRNA Tuna is activated in cadmium-induced placental insufficiency and drives the NRF2-mediated oxidative stress response
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Journal Article
LncRNA Tuna is activated in cadmium-induced placental insufficiency and drives the NRF2-mediated oxidative stress response
2023
Overview
Cadmium (Cd) is a toxic heavy metal found throughout the environment and one of the top ten toxicants of major public health concern identified by the World Health Organization.
In utero
Cd exposure causes fetal growth restriction, malformation, and spontaneous abortion; however, the mechanisms by which Cd impacts these outcomes are poorly understood. Cd accumulates in the placenta, suggesting that these negative outcomes may be a consequence of disrupted placental function and placental insufficiency. To understand the impact of Cd on gene expression within the placenta, we developed a mouse model of Cd-induced fetal growth restriction through maternal consumption of CdCl
2
and performed RNA-seq on control and CdCl
2
exposed placentae. The top differentially expressed transcript was the
Tcl1 Upstream Neuron-Associated
(
Tuna
) long non-coding RNA, which was upregulated over 25-fold in CdCl
2
exposed placentae.
Tuna
has been shown to be critical for neural stem cell differentiation. However, within the placenta, there is no evidence that
Tuna
is normally expressed or functional at any developmental stage. To determine the spatial expression of Cd-activated
Tuna
within the placenta, we used
in situ
hybridization as well as placental layer-specific RNA isolation and analysis. Both methods confirmed the absence of
Tuna
expression in control samples and determined that Cd-induced
Tuna
expression is specific to the junctional zone. Since many lncRNAs regulate gene expression, we hypothesized that
Tuna
forms part of the mechanism of Cd-induced transcriptomic changes. To test this, we over-expressed
Tuna
in cultured choriocarcinoma cells and compared gene expression profiles to those of control and CdCl
2
exposed cells. We demonstrate significant overlap between genes activated by
Tuna
overexpression and genes activated by CdCl
2
exposure, with enrichment in the NRF2-mediated oxidative stress response. Herein we analyze the NRF2 pathway and show that
Tuna
increases
NRF2
/NRF2 both at the transcript and protein levels.
Tuna
drives increased NRF2 target gene expression, a result that is abrogated with the use of an NRF2 inhibitor, confirming that
Tuna
activates oxidative stress response genes through this pathway. This work identifies the lncRNA
Tuna
as a potential novel player in Cd-induced placental insufficiency.
