Progesterone and HMOX-1 promote fetal growth by CD8+ T cell modulation
María Emilia Solano, … , Khalil Karimi, Petra Clara Arck
María Emilia Solano, … , Khalil Karimi, Petra Clara Arck
Published March 16, 2015
Citation Information: J Clin Invest. 2015;125(4):1726-1738. https://doi.org/10.1172/JCI68140.
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Research Article Reproductive biology Article has an altmetric score of 8

Progesterone and HMOX-1 promote fetal growth by CD8+ T cell modulation

Abstract

Intrauterine growth restriction (IUGR) affects up to 10% of pregnancies in Western societies. IUGR is a strong predictor of reduced short-term neonatal survival and impairs long-term health in children. Placental insufficiency is often associated with IUGR; however, the molecular mechanisms involved in the pathogenesis of placental insufficiency and IUGR are largely unknown. Here, we developed a mouse model of fetal-growth restriction and placental insufficiency that is induced by a midgestational stress challenge. Compared with control animals, pregnant dams subjected to gestational stress exhibited reduced progesterone levels and placental heme oxygenase 1 (Hmox1) expression and increased methylation at distinct regions of the placental Hmox1 promoter. These stress-triggered changes were accompanied by an altered CD8+ T cell response, as evidenced by a reduction of tolerogenic CD8+CD122+ T cells and an increase of cytotoxic CD8+ T cells. Using progesterone receptor– or Hmox1-deficient mice, we identified progesterone as an upstream modulator of placental Hmox1 expression. Supplementation of progesterone or depletion of CD8+ T cells revealed that progesterone suppresses CD8+ T cell cytotoxicity, whereas the generation of CD8+CD122+ T cells is supported by Hmox1 and ameliorates fetal-growth restriction in Hmox1 deficiency. These observations in mice could promote the identification of pregnancies at risk for IUGR and the generation of clinical interventional strategies.

Authors

María Emilia Solano, Mirka Katharina Kowal, Greta Eugenia O’Rourke, Andrea Kristina Horst, Kathrin Modest, Torsten Plösch, Roja Barikbin, Chressen Catharina Remus, Robert G. Berger, Caitlin Jago, Hoang Ho, Gabriele Sass, Victoria J. Parker, John P. Lydon, Francesco J. DeMayo, Kurt Hecher, Khalil Karimi, Petra Clara Arck

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Figure 2

Progesterone levels and placental Hmox1 expression are reduced in fetal-growth restriction.

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Progesterone levels and placental Hmox1 expression are reduced in fetal-...
(A) Levels of serum progesterone in control and stress-challenged dams on gd16.5, as analyzed by RIA. (B) Fetal weight and (C) placental L/Jz ratio in gd13.5 placentas resulting from Pgr+/– × Pgr+/– mating combinations. The fetal/placental Pgr genotypes are provided under the respective bars. (D) Fold change (FC) in Hmox1 mRNA expression quantified by RT-PCR in placental samples from control and stress-challenged pregnancies on gd16.5. (E) Photomicrographs showing detail of the labyrinth and junctional zone areas of representative placental tissue sections upon immunohistochemical detection of HMOX-1 (appears brown). Tissue was counterstained with hematoxylin. Scale bar: 0.1 mm. (F) Pyrosequencing methylation analysis of a CpG island in the Hmox1 promoter region in placenta samples from control and stress-challenged dams on gd16.5 (n ≥ 7). The CpG island locates 110-bp upstream and 172-bp downstream from the transcriptional start site, which is denoted as 1. (G) Fetal weight in offspring arising from Hmox1+/– × Hmox1+/– mating combinations. The fetal/placental Hmox1 genotypes are provided under the respective bars. (H) L/Jz ratio obtained from analyses of Masson-stained placental tissue sections taken on gd16.5 from Hmox1+/– × Hmox1+/– mating combinations. The n used in each group and experiment is depicted inside the bars (AD and GH). Data are presented as mean ± SEM per respective group. *P ≤ 0.05; **P ≤ 0.01. Analyses were performed using Mann-Whitney U test (A, D, and F) and the Kruskal-Wallis test (B, C, G, and H).