Splenectomy Delays Uterine Natural Killer Cell Recruitment to Implantation Sites and Prolongs Pregnancy in Mice

Amoxicillin-induced bacterial gut dysbiosis: A critical influence on mice reproduction and their offspring development

The use of antibiotics such as amoxicillin can induce intestinal dysbiosis leading to rupture the essential microbiota role in regulating immune, metabolic, and reproductive functions. This study assessed the effects of amoxicillin-induced intestinal dysbiosis on the female mice reproductive function and its repercussions on their offspring. Female mice were treated with amoxicillin for 15 days (AMOX) showed an increase in Proteobacteria and a decrease in Firmicutes and Bacteroidetes in feces and estrous cycle changes, with a predominance of the metestrus and diestrus phases in the treated mice. During gestation the AMOX group presented reduced number of implantations and decreased embryonic viability, resulting in a higher rate of resorption. Differential gene expression of reproductive hormones in AMOX-treated female mice suggested that intestinal dysbiosis interferes with hormonal regulation during pregnancy. The survival, body development, and intestinal microbiota composition of offspring showed significantly altered patterns in the AMOX mice. These findings indicate that amoxicillin-induced intestinal dysbiosis affects not only the estrous cycle and reproductive hormones but also has lasting impacts on offspring development. The study highlights the need for caution in the use of antibiotics during pregnancy to avoid potential harm to maternal and offspring health.

Alternative splicing of helicase-like transcription factor (Hltf): Intron retention-dependent activation of immune tolerance at the feto-maternal interface

Hltf is regulated by intron retention, and global Hltf-deletion causes perinatal lethality from hypoglycemia. In heart, full-length Hltf is a transcriptional regulator of Hif-1α that controls transport systems. Thus, we tested the hypothesis that Hltf deletion from placenta caused or exacerbated neonatal hypoglycemia via Hif-1α regulation of nutrient transporters. RNA-seq data analyses identified significant changes in transcript expression and alternative splicing (AS) in E18.5 placentome. iPathwayGuide was used for gene ontology (GO) analysis of biological processes, molecular functions and cellular components. Elim pruning algorithm identified hierarchical relationships. The methylome was interrogated by Methyl-MiniSeq Epiquest analysis. GO analysis identified gene enrichment within biological processes. Protein expression was visualized with immunohistochemistry. Although two Hltf mRNA isoforms are quantifiable in most murine tissues, only the truncated Hltf isoform is expressed in placenta. The responsible intron retention event occurs in the absence of DNA methylation. iPathwayGuide analysis identified 157 target genes of 11,538 total genes with measured expression. These were obtained using a threshold of 0.05 for statistical significance (p-value) and a long fold change of expression with absolute value of at least 0.6. Hltf deletion altered transcription of trophoblast lineage-specific genes, and increased transcription of the Cxcr7 (p = 0.004) gene whose protein product is a co-receptor for human and simian immunodeficiency viruses. Concomitant increased Cxcr7 protein was identified with immunolabeling. Hltf deletion had no effect on transcription or site-specific methylation patterns of Hif-1α, the major glucose transporters, or System A amino acid transporters. There was no measureable evidence of uteroplacental dysfunction or fetal compromise. iPathGuide analysis revealed Hltf suppresses cytolysis (10/21 genes; p-value 1.900e-12; p-value correction: Elim pruning; GO:019835) including the perforin-granzyme pathway in uterine natural killer cells. Our findings 1) prove the truncated Hltf protein isoform is a transcription factor, 2) establish a functional link between AS of Hltf and immunosuppression at the feto-maternal interface, 3) correlate intron retention with the absence of DNA methylation, and 4) underscore the importance of differential splicing analysis to identify Hltf's functional diversity.

Human extravillous trophoblast invasion: intrinsic and extrinsic regulation

During the establishment of pregnancy, a human blastocyst implants into the uterine endometrium to facilitate the formation of a functional placenta. Implantation involves the blastocyst adhering to the uterine luminal epithelium before the primitive syncytiotrophoblast and subsequently specialised cells, the extravillous trophoblast (EVT), invade into the decidua in order to engraft and remodel uterine spiral arteries, creating the placental blood supply at the end of the first trimester. Defects in EVT invasion lead to abnormal placentation and thus adverse pregnancy outcomes. The local decidual environment is thought to play a key role in regulating trophoblast invasion. Here we describe the major cell types present in the decidua during the first trimester of pregnancy and review what is known about their regulation of EVT invasion. Overall, the evidence suggests that in a healthy pregnancy almost all cell types in the decidua actively promote EVT invasion and, further, that reduced EVT invasion towards the end of the first trimester is regulated, in part, by the reduced invasive capacity of EVTs shown at this time.

alpha-actin down regulation and perforin loss in uterine natural killer cells from LPS-treated pregnant mice

One of the most abundant immunologic cell types in early decidua is the uterine natural killer (UNK) cell that despite the presence of cytoplasmic granules rich in perforin and granzymes does not degranulate in normal pregnancy. UNK cells are important producers of angiogenic factors that permit normal dilation of uterine arteries to provide increased blood flow for the growing feto-placental unit. Gram-negative bacteria lipopolysaccharide (LPS) administration can trigger an imbalance of pro-inflammatory and anti-inflammatory cytokines impairing the normal immune cells activity as well as uterine homeostasis. The present study aimed to evaluate by immunohistochemistry the reactivity of perforin and alpha-actin on UNK cell from LPS-treated pregnant mice. For the first time, we demonstrate that LPS injection in pregnant mice causes alpha-actin down regulation, concomitantly with perforin loss in UNK cells. This suggests that LPS alters UNK cell migration and activates cytotoxic granule release.

To serve and to protect: the role of decidual innate immune cells on human pregnancy

The maternal-fetal interface undergoes dynamic changes that promote successful development of the embryo/fetal allograft during pregnancy. This immune privilege of the conceptus is mediated through local and systemic cellular responses. In species in which endometrial decidualization accompanies pregnancy, unique immune cell niches are found. Many studies have addressed the enigmatic roles of uterine (u)NK cells as killers and helpers because they are frequently found in the uterine lining and decidua of normal and pathological pregnancies. Accumulating evidence indicates that uNK cells are induced and transformed by sensing signals within their microenvironment to both protect the mother from the fetal allograft and support the fetus during its development. Here, we review the mechanisms that modulate these functions of uNK cells during pregnancy. We suggest that uNK cells must be tightly regulated in order to serve these two roles and support a healthy pregnancy.

Inhibition of eIF5A results in aberrant uterine natural killer cell function and embryo loss in mice

PROBLEM

The role of eukaryotic initiation factor 5A (eIF5A) in feto-maternal immunotolerance is poorly understood.

METHODS OF STUDY

The effects of N1-guanyl-1,7-diaminoheptane (GC7), an inhibitor of eIF5A, on the proportion and function of natural killer (NK) cell subsets were investigated using flow cytometry, immunofluorescence, CCK8 assay, TUNEL assay, DNA fragmentation analysis, mitochondrial membrane potential assay, and Western blotting.

RESULTS

Inhibition of eIF5A by GC7 increased embryo loss and reduced the percentage of NK cells in the uterus and spleen. GC7 treatment caused inhibition of NK cell proliferation in a time- and dose-dependent manner. GC7 also induced apoptosis of NK cells. GC7 treatment increased the protein levels of FasL, bax, p53, and cleaved caspase-3. Moreover, GC7 caused loss of mitochondrial membrane potential in NK cells.

CONCLUSION

Inhibition of eIF5A results in aberrant NK cell function and increased embryo loss.