Project description:Offspring born to diabetic or obese mothers have a higher lifetime risk of heart disease. Previously, we found that rat offspring exposed to late-gestational diabetes mellitus (LGDM) and maternal high-fat (HF) diet develop mitochondrial dysfunction, impaired cardiomyocyte bioenergetics, and cardiac dysfunction at birth and again during aging. Here, we compared echocardiography, cardiomyocyte bioenergetics, oxidative damage, and mitochondria-mediated cell death among control, pregestational diabetes mellitus (PGDM)-exposed, HF-diet-exposed, and combination-exposed newborn offspring. We hypothesized that PGDM exposure, similar to LGDM, causes mitochondrial dysfunction to play a central, pathogenic role in neonatal cardiomyopathy. We found that PGDM-exposed offspring, similar to LGDM-exposed offspring, have cardiac dysfunction at birth, but their isolated cardiomyocytes have seemingly less bioenergetics impairment. This finding was due to confounding by impaired viability related to poorer ATP generation, more lipid peroxidation, and faster apoptosis under metabolic stress. To mechanistically isolate and test the role of mitochondria, we transferred mitochondria from normal rat myocardium to control and exposed neonatal rat cardiomyocytes. As expected, transfer provides a respiratory boost to cardiomyocytes from all groups. They also reduce apoptosis in PGDM-exposed males, but not in females. Findings highlight sex-specific differences in mitochondria-mediated mechanisms of developmentally programmed heart disease and underscore potential caveats of therapeutic mitochondrial transfer.

Project description:Objective: To evaluate the altered expression of genes due to hyperglycaemia during foetal development in heart. Methods: To understand the molecular defects in the two-days old neonatal rats, diabetic female rats were bred with healthy male rats and collected two days old hearts from neonates. Heart mRNA profiles of two-day-old neonatal rats were generated by RNA sequencing, in quadruplicate, using Illumina HiSeq. Results: Using an optimized data analysis workflow, we mapped about 27 million sequence reads per sample to the rat genome (build Rnor_6.0) and identified 25456 transcripts in the heart of the neonatal rats. Approximately 4% of the transcripts showed differential expression between the Control and PGDM (pregestational diabetes mellitus) heart, with a fold change ≥2 and p value <0.05. Conclusions: Transcriptomic profiling of the RNA-seq data revealed that several of the altered genes were associated with cardiac pathogenesis in neonatal heart during PGDM.

Project description:Pregestational Diabetes Alters Cardiac changes

Project description:Pregestational diabetes is a major risk factor of congenital heart defects (CHDs). Glutathione is depleted and reactive oxygen species (ROS) production is elevated in diabetes. In the present study, we aimed to examine whether treatment with N-acetylcysteine (NAC), which increases glutathione synthesis and inhibits ROS production, prevents CHDs induced by pregestational diabetes.Female mice were treated with streptozotocin (STZ) to induce pregestational diabetes prior to breeding with normal males to produce offspring. Some diabetic mice were treated with N-acetylcysteine (NAC) in drinking water from E0.5 to the end of gestation or harvesting of the embryos. CHDs were identified by histology. ROS levels, cell proliferation and gene expression in the fetal heart were analyzed.Our data show that pregestational diabetes resulted in CHDs in 58% of the offspring, including ventricular septal defect (VSD), atrial septal defect (ASD), atrioventricular septal defects (AVSD), transposition of great arteries (TGA), double outlet right ventricle (DORV) and tetralogy of Fallot (TOF). Treatment with NAC in drinking water in pregestational diabetic mice completely eliminated the incidence of AVSD, TGA, TOF and significantly diminished the incidence of ASD and VSD. Furthermore, pregestational diabetes increased ROS, impaired cell proliferation, and altered Gata4, Gata5 and Vegf-a expression in the fetal heart of diabetic offspring, which were all prevented by NAC treatment.Treatment with NAC increases GSH levels, decreases ROS levels in the fetal heart and prevents the development of CHDs in the offspring of pregestational diabetes. Our study suggests that NAC may have therapeutic potential in the prevention of CHDs induced by pregestational diabetes.

Project description:To study the functional differences between maternal and paternal genomes in mammalian development, embryos with only one parental genome are often used. Androgenetic embryos are produced by the removal of maternal chromosomes before or after fertilization by techniques that require specialized skills and are associated with high risk of cellular damage. Here, we developed a novel method for producing androgenetic mouse embryos without the invasive enucleation process. We found that during in vitro fertilization in the presence of low-dose nocodazole, a microtubule destabilizing drug, whole oocyte chromosomes were extruded into the second polar body resulting in the production of androgenetic embryos. We further demonstrated that low-dose nocodazole decreased the spindle size and prevented chromosome segregation but did not compromise oocyte meiotic resumption. This led to the formation of a protrusion around the chromosomes, accumulation of protein regulator of cytokinesis 1 (PRC1) to the microtubules around the chromosomes, and assembly of a contractile ring at the neck region of the protrusion. Our method uses the intrinsic cytokinetic mechanism to exclude maternal chromatin from zygotes and may be applicable to other mammals.

Project description:BackgroundPregestational diabetes is associated with fetal macrosomia, and umbilical perfusion of the fetal liver has a role in regulating fetal growth. We therefore hypothesized that pregestational diabetes alters fetal liver blood flow depending on degree of glycemic control.MethodsIn a prospective study, 49 women with pregestational diabetes underwent monthly ultrasound examinations during 24-36 gestational weeks. Blood flow was determined in the umbilical vein, ductus venosus and portal vein, and blood velocity was measured in the left portal vein, the latter reflecting the watershed between splanchnic and umbilical flow. The measurements were compared with reference values by z-score statistics, and the effect of HbA1c assessed.ResultsThe umbilical venous flow to the liver (z-score 0.36, p = 0.002), total venous liver flow (z-score 0.51, p<0.001) and left portal vein blood velocity (z-score 0.64, p<0.001), were higher in the study group. Normalized portal venous flow was lower (z-score -0.42, p = 0.002), and normalized total venous liver flow tended to be lower after 30 gestational weeks (z-score -0.54, p = 0.047) in the diabetic pregnancies compared with reference values from a low-risk population. The left portal vein blood velocity was positively, and the portal fraction of total venous liver flow negatively correlated with first trimester HbA1C.ConclusionsIn spite of increased umbilical blood distribution to the fetal liver, graded according to glycemic control, the total venous liver flow did not match third trimester fetal growth in pregnancies with pregestational diabetes, thus contributing towards increased perinatal risks and possibly altered liver function with long-term metabolic consequences.

Project description:The photochemistry of vision employs opsins and geometric isomerization of their covalently bound retinylidine chromophores. In different animal classes, these light receptors associate with distinct G proteins that either hyperpolarize or depolarize photoreceptor membranes. Vertebrates also use the acidic form of chromophore, retinoic acid, as the ligand of nuclear hormone receptors that orchestrate eye development. To establish and sustain these processes, animals must acquire carotenoids from the diet, transport them, and metabolize them to chromophore and retinoic acid. The understanding of carotenoid metabolism, however, lagged behind our knowledge about the biology of their receptor molecules. In the past decades, much progress has been made in identifying the genes encoding proteins that mediate the transport and enzymatic transformations of carotenoids and their retinoid metabolites. Comparative analysis in different animal classes revealed how evolutionary tinkering with a limited number of genes evolved different biochemical strategies to supply photoreceptors with chromophore. Mutations in these genes impair carotenoid metabolism and induce various ocular pathologies. This review summarizes this advancement and introduces the involved proteins, including the homeostatic regulation of their activities.

Project description:Background Tetrahydrobiopterin is a cofactor of endothelial NO synthase ( eNOS ), which is critical to embryonic heart development. We aimed to study the effects of sapropterin (Kuvan), an orally active synthetic form of tetrahydrobiopterin on eNOS uncoupling and congenital heart defects ( CHD s) induced by pregestational diabetes mellitus in mice. Methods and Results Adult female mice were induced to pregestational diabetes mellitus by streptozotocin and bred with normal male mice to produce offspring. Pregnant mice were treated with sapropterin or vehicle during gestation. CHD s were identified by histological analysis. Cell proliferation, eNOS dimerization, and reactive oxygen species production were assessed in the fetal heart. Pregestational diabetes mellitus results in a spectrum of CHD s in their offspring. Oral treatment with sapropterin in the diabetic dams significantly decreased the incidence of CHD s from 59% to 27%, and major abnormalities, such as atrioventricular septal defect and double-outlet right ventricle, were absent in the sapropterin-treated group. Lineage tracing reveals that pregestational diabetes mellitus results in decreased commitment of second heart field progenitors to the outflow tract, endocardial cushions, and ventricular myocardium of the fetal heart. Notably, decreased cell proliferation and cardiac transcription factor expression induced by maternal diabetes mellitus were normalized with sapropterin treatment. Furthermore, sapropterin administration in the diabetic dams increased eNOS dimerization and lowered reactive oxygen species levels in the fetal heart. Conclusions Sapropterin treatment in the diabetic mothers improves eNOS coupling, increases cell proliferation, and prevents the development of CHD s in the offspring. Thus, sapropterin may have therapeutic potential in preventing CHD s in pregestational diabetes mellitus.

Project description:Pregnancy poses significant metabolic challenges for women, yet the impact of repeated deliveries on overall glucose metabolism in females remains inadequately explored. In this study, we investigate alterations in female glucose metabolism following multiple deliveries using a comprehensive phenotyping mouse model that closely resembles humans. To establish a multiparty mouse model, a 9-week-old female mouse underwent three consecutive pregnancies. Three weeks post-pregnancy, multiparous mice exhibited improved glucose tolerance and enhanced glucose-stimulated insulin secretion (GSIS), without changes in insulin sensitivity compared to virgin mice. Histological analysis revealed an increased beta cell mass in multiparous mice at this stage of life. Intriguingly, 16 weeks after the last delivery, multiparous mice demonstrated impaired glucose tolerance, accompanied by compromised GSIS and increased basal insulin secretion both in vivo and ex vivo. These mice also developed insulin resistance at 16 weeks post-delivery, with no discernible difference in beta cell mass. To assess whether multiparous islets were impaired in their compensatory ability to meet increased insulin demand, multiparous and virgin islets (3 weeks after the last delivery) were transplanted to opposite sides of the kidney capsule in a single recipient mouse. Upon S-961 injection, multiparous mice were reduced in Ki-67 expressing cells compared with virgin mice. Bulk RNA sequencing (RNA-seq) analysis of S-961-injected multiparous islet genes revealed downregulation of cell cycle-related genes (Cenpi and Cenpf, Cdk1, Cdk2, and Cdkn2d). Single-cell RNA-seq analysis identified multiparous-specific beta cell clusters that displayed upregulation of stress-related genes (Ddit3, Fkbp11, Sdf2l1, Nupr1, Atf5, Atf3, Hspa1a, Hspa1b, and Dnajb1). Furthermore, multiparous mice beta cells exhibited shortened telomere lengths and increased expression of Cdkn2a, indicating an accelerated aging phenotype. In humans, women with higher parities (parity > 3 times) exhibited greater impairment in glucose tolerance and increased obesity compared to women with lower parities (parity < 3 times) at 2 months postpartum. Women with higher parity who experienced weight gain after delivery also demonstrated a greater decline in beta cell function (disposition index). Overall, our findings indicate that multiparty increases the risk of diabetes by impairing beta cells ability to compensate for the increased insulin demand.

Project description:Pregnancy poses significant metabolic challenges for women, yet the impact of repeated deliveries on overall glucose metabolism in females remains inadequately explored. In this study, we investigate alterations in female glucose metabolism following multiple deliveries using a comprehensive phenotyping mouse model that closely resembles humans. To establish a multiparty mouse model, a 9-week-old female mouse underwent three consecutive pregnancies. Three weeks post-pregnancy, multiparous mice exhibited improved glucose tolerance and enhanced glucose-stimulated insulin secretion (GSIS), without changes in insulin sensitivity compared to virgin mice. Histological analysis revealed an increased beta cell mass in multiparous mice at this stage of life. Intriguingly, 16 weeks after the last delivery, multiparous mice demonstrated impaired glucose tolerance, accompanied by compromised GSIS and increased basal insulin secretion both in vivo and ex vivo. These mice also developed insulin resistance at 16 weeks post-delivery, with no discernible difference in beta cell mass. To assess whether multiparous islets were impaired in their compensatory ability to meet increased insulin demand, multiparous and virgin islets (3 weeks after the last delivery) were transplanted to opposite sides of the kidney capsule in a single recipient mouse. Upon S-961 injection, multiparous mice were reduced in Ki-67 expressing cells compared with virgin mice. Bulk RNA sequencing (RNA-seq) analysis of S-961-injected multiparous islet genes revealed downregulation of cell cycle-related genes (Cenpi and Cenpf, Cdk1, Cdk2, and Cdkn2d). Single-cell RNA-seq analysis identified multiparous-specific beta cell clusters that displayed upregulation of stress-related genes (Ddit3, Fkbp11, Sdf2l1, Nupr1, Atf5, Atf3, Hspa1a, Hspa1b, and Dnajb1). Furthermore, multiparous mice beta cells exhibited shortened telomere lengths and increased expression of Cdkn2a, indicating an accelerated aging phenotype. In humans, women with higher parities (parity > 3 times) exhibited greater impairment in glucose tolerance and increased obesity compared to women with lower parities (parity < 3 times) at 2 months postpartum. Women with higher parity who experienced weight gain after delivery also demonstrated a greater decline in beta cell function (disposition index). Overall, our findings indicate that multiparty increases the risk of diabetes by impairing beta cells ability to compensate for the increased insulin demand.