Project description:Peripartum cardiomyopathy (PPCM) is a rare form of acute heart failure that develops in women towards the end of pregnancy or early in the postpartum period. Despite clinical similarities to dilated cardiomyopathy of other etiologies (non-peripartum cardiomyopathy; NPCM), the molecular mechanisms driving PPCM remain poorly understood. To characterize disease-specific proteomic remodeling, we conducted deep proteomic profiling of heart tissue from PPCM patients, NPCM patients, and healthy organ donors.

Project description:Peripartum depression can have severe impact on the mother’s and the infant’s health. Yet, its biological underpinnings are largely unknown. The present study sought to identify transcriptomic signatures of depressive symptoms during pregnancy and postpartum. Blood samples were collected during late pregnancy or early postpartum for mRNA isolation and sequencing, while depressive symptoms were assessed using the Edinburgh Postnatal Depression Scale. Stratifying according to the timepoint samples were collected, differentially expressed genes (DEGs) were identified by (1) comparing mRNA levels between the symptom trajectory groups, and (2) correlating with EPDS scores. DEGs for samples collected late pregnancy, but not postpartum, were associated with depressive symptoms occurring only during pregnancy or persisting postpartum, compared with controls. There were 16 upregulated and 109 downregulated DEGs significantly associated with changes in EPDS score at week 32 among samples collected late pregnancy. Gene Set Enrichment Analysis identified immune response and cell motility as processes linked to these DEGs. Hypothesis-based analysis on previously identified postpartum depressive symptoms-related DEGs, replicated a positive association between expression of immune-related genes ISG15 and RSAD2 with postpartum-onset depressive symptoms, both at samples taken during late pregnancy and postpartum. The present findings point to transcriptomic signatures associated with depressive symptoms, mostly related to immune system dysregulation.

Project description:We conducted transcriptomic profiling of PPCM patient and normal hearts to examine differential gene expression and identified the peptidyl-tRNA hydrolase 2 (PTRH2, Bit-1; BIT1) gene and protein were significantly downregulated in PPCM patient hearts.

Project description:Pregnancy imposes significant cardiovascular adaptations including progressive increases in plasma volume and cardiac output. For most women, this physiological adaptation resolves at the end of pregnancy, but some women develop pathological dilatation and ultimately heart failure late in pregnancy or in the postpartum period manifesting as peripartum cardiomyopathy (PPCM). Despite the mortality risk of this form of heart failure, the molecular mechanisms underlying PPCM have not been extensively examined in human hearts. We examined protein and metabolite expression in PPCM compared to familial dilated cardiomyopathy (DCM) and non-failing donors using unbiased quantitative mass spectrometry. Proteomics analysis identified uniquely downregulated proteins, such as SBSPON and TNS3, in PPCM relative to both DCM and donors. KEGG analysis of PPCM proteins identified key pathways associated with intracellular signalling cascades, protein folding and neurohormonal pathways that can directly impact the contractility of the heart. Metabolomics demonstrated uniquely expressed metabolites, such as upregulated homogentisate and deoxycholate, and downregulated lactate and alanine, along with reduced alanine, aspartate and glutamate metabolism are involved in the PPCM phenotype. Therefore, this study is the first to isolate unique molecular features underlying PPCM at the protein and metabolite level which may hold promise as future therapeutic candidate targets.

Project description:Metabolic challenges experienced by dairy cows during the transition between pregnancy and lactation (also known as peripartum), are of considerable interest from a nutrigenomic perspective. The mobilization of large amounts of non-esterified fatty acids (NEFA) leads to an increase in NEFA uptake in the liver, the excess of which can cause hepatic accumulation of lipids and ultimately fatty liver. Interestingly, peripartum NEFA activate the peroxisome proliferator-activated receptor (PPAR), a transcriptional regulator with known nutrigenomic properties. The study of PPAR activation in the liver of periparturient dairy cows is thus crucial; however, current in vitro models of the bovine liver are inadequate, and the isolation of primary hepatocytes is prohibitive and error-prone. The objective of the current study was to evaluate the use of precision-cut liver slices (PCLS) from liver biopsies as a model for PPAR activation in periparturient dairy cows. Four cows were enrolled in the experiment, and PCLS from each were prepared prepartum (-10 DIM) and postpartum (+10 DIM) and treated with a variety of PPAR agonists and antagonist. Gene expression was assayed through RT-qPCR and RNAseq, and intracellular triglyceride concentration was measured. PCLS treated with PPARγ agonist rosiglitazone displayed upregulation of canonical PPAR targets ACADVL and LIPC in the postpartum, while a PPARδ agonists increased expression of PPAR target PDK4; no gene expression changes were detected in the prepartum, and triglyceride concentrations were unchanged between treatments. Transcriptome sequencing revealed considerable differences in response to PPAR agonist, mainly related to pathways involved with lipid metabolism and the immune response. Among differentially expressed genes, a subset of 91 genes were identified as novel putative PPAR targets in the bovine liver, by cross-referencing our results with a publicly-available dataset of predicted PPAR target genes, and supplementing our finding with prior literature. Our results provide important insights on the use of PCLS as a model for assaying PPAR activation in the peripartum.

Project description:Using high-resolution single-cell RNA sequencing, we systematically characterized hepatocyte adaptations in mice across pregnancy and postpartum stages. We discovered a cyclical hepatocyte trajectory (“pregnancy clock”) governing metabolic changes during gestation and postpartum recovery, which reverted to pregestational states in non-lactating mice. Lactation induced a distinct branching trajectory characterized by elevated lipid synthesis and export. Deletion of gp130 disrupted hepatic adaptations during pregnancy, impairing fetal growth, whereas ACSS2 deficiency postpartum disrupted lipid export, affecting milk quality and offspring growth.

Project description:Using high-resolution single-cell RNA sequencing, we systematically characterized hepatocyte adaptations in mice across pregnancy and postpartum stages. We discovered a cyclical hepatocyte trajectory (“pregnancy clock”) governing metabolic changes during gestation and postpartum recovery, which reverted to pregestational states in non-lactating mice. Lactation induced a distinct branching trajectory characterized by elevated lipid synthesis and export. Deletion of gp130 disrupted hepatic adaptations during pregnancy, impairing fetal growth, whereas ACSS2 deficiency postpartum disrupted lipid export, affecting milk quality and offspring growth.

Project description:Using high-resolution single-cell RNA sequencing, we systematically characterized hepatocyte adaptations in mice across pregnancy and postpartum stages. We discovered a cyclical hepatocyte trajectory (“pregnancy clock”) governing metabolic changes during gestation and postpartum recovery, which reverted to pregestational states in non-lactating mice. Lactation induced a distinct branching trajectory characterized by elevated lipid synthesis and export. Deletion of gp130 disrupted hepatic adaptations during pregnancy, impairing fetal growth, whereas ACSS2 deficiency postpartum disrupted lipid export, affecting milk quality and offspring growth.

Project description:Pancreatic β-cell mass expands during pregnancy and regresses in the postpartum period in conjunction with dynamic metabolic demands on maternal glucose homeostasis. To understand transcriptional changes driving these adaptations in β-cells and other islet cell types, we performed single-cell RNA sequencing on islets from virgin, late gestation, and early postpartum mice. We identified transcriptional signatures unique to gestation and the postpartum in β-cells, including induction of the AP-1 transcription factor subunits and other genes involved in the immediate-early response (IEGs). Additionally, we found pregnancy and postpartum-induced changes differed within each endocrine cell type, and in endothelial cells and macrophages within islets. Together, our data reveal novel insights into cell-type specific transcriptional changes responsible for adaptations by islet cells to pregnancy and their resolution postpartum.

Project description:Biomolecules preserved in dental pulp are increasingly being used to identify individuals in the context of forensics and archaeology. Despite the vast amount of research into host and pathogen DNA, the potential use of physiologically informative proteins preserved in dental pulp has rarely been studied. Here, we hypothesized that pregnancy specific proteins circulating in the blood could be identified from the dental pulp of postpartum individuals and this was investigated using 8 human third molars extracted from 4 postpartum and 3 control individuals during clinical treatment. A total of 885 proteins were identified from these 8 dental pulp samples using liquid chromatography coupled tandem mass spectrometry, whose gene ontology compositions were similar to previous studies. However, despite our hypothesis, pregnancy specific proteins were not identified from the dental pulp of postpartum individuals (n = 5, 4–12 months postpartum). Although the dental pulp proteomes obtained from three individuals postpartum ≤6 months were distinct from those of other individuals by principal component analysis, their driving proteins were less evident. Although our hypothesis was not supported, sample collection, protein extraction, and mass spectrometry analysis could be improved to explore the forensic application of detecting pregnancy specific proteins in dental pulp.