Xueyi Chen’s research while affiliated with First Affiliated Hospital of China Medical University and other places

Background Paternal preconception alcohol exposure affects fetal development; however, it is largely unknown about the influences on offspring vasculature and mechanisms. Methods Offspring born form paternal rats treated with alcohol or water before pregnant was raised until 3 months of age. Vessel tone of mesenteric arteries was detected using myograph system; whole-cell calcium channel current in smooth muscle cells was tested using patch-clamp; molecule expressions were detected with real-time PCR, western blotting, and Dihydroethidium (DHE); DNA methylations were determined using targeted bisulfate sequencing assay. Following 5-aza-2′-deoxycytidine incubation, vessel tone in offspring mesenteric artery and Cacna1c expression in A7r5 was tested. Results When comparing with the control, stress–strain curve was left-shifted in alcohol. There was lower incremental distensibility and endothelium-dependent dilation associated with endothelial nitric oxide synthase. Agonists-induced constrictions were greater in alcohol offspring than that in control, associated with higher expression of AT1R, Cacna1c, and reactive oxygen species (ROS). Baseline and Ang II-stimulated calcium channel currents were higher in alcohol group. Tempol and apocynin could restore Ang II-increased constriction and calcium channel current in alcohol offspring. When comparing with the control, there was lower DNA methylation of Cacna1c promotor in alcohol offspring mesenteric artery and in paternal sperm. 5-aza-2′-deoxycytidine increased contraction in control offspring mesenteric artery and Cacna1c expression in A7r5. Conclusion Paternal preconception alcohol exposure-affected offspring mesenteric artery was via ROS-Cacna1c. Abnormal offspring vascular functions might be inherited via DNA hypomethylation of Cacna1c promotor from paternal sperm exposed to alcohol. These data gained provided important clues for cardiovascular disorders at germ cell origin.

Aims Prenatal hypoxia (PH) could affect peripheral vascular tone of the offspring, thus increasing the risk of cardiovascular diseases in adult. However, it's still unknown whether functions of coronary arteries (COA) in adult offspring would be influenced by PH. The present study aimed at effects of PH on vascular tone of COA and its related mechanisms. Methods Coronary arteries of adult offspring exposed to hypoxic or normoxic circumstances during gestational day 5 to 21 were collected. Wire myograph system, whole-cell patch clamp technique, IonOptix MyoCam system, PCR, and western blot were used to detect vascular function of adult offspring COA. Key findings PH significantly attenuated serotonin- and phorbol 12, 13-dibutyrate (PDBu)-induced constriction. Iberiotoxin potentiated PDBu-induced constriction and the effect was augmented by PH, however, no significant differences were found in whole-cell BKCa channel currents and its protein expression. Nifedipine inhibited PDBu-mediated constriction and the inhibitory effect was reduced in PH group, and whole-cell calcium channel current was decreased in offspring COA. Besides, PH reduced the capability of calcium release from the endoplasmic reticulum in COA. The phosphorylated PKCβ protein expression at Ser⁶⁶⁰ site, not Thr⁶⁴¹ site, was significantly decreased in PH offspring. Chronic hypoxia during pregnancy attenuated PDBu-mediated constriction in offspring COA, presumably through decreased phosphorylated PKCβ at serine⁶⁶⁰ sites and decreased intracellular calcium-related weaker PKC activation. Significance The findings provided new information on the influence of prenatal hypoxia on COA, and suggested potential use of PKCβ-serine⁶⁶⁰ for early prevention of coronary heart diseases in developmental origins.

Background/aims: The current study investigated the long-term effects of prenatal caffeine (Caf) exposure on cerebral vessels of old offspring rats. Methods: Pregnant rats were treated with Caf (20 mg/kg, twice daily) or 0.9% normal saline during gestational days 3.5-19.5, and offspring were tested at 24 months old. Vascular functions of middle cerebral arteries and ion channel activities in smooth muscle cells were examined using myograph system and patch-clamp. Results: Prenatal Caf exposure decreased isoprenaline (β-adrenergic agonist)-induced dilatation of the middle cerebral artery in the offspring. Treatment with protein kinase A (PKA) inhibitor reduced isoprenaline-mediated vasodilatation to a greater extent in the control. Forskolin-mediated vasodilatation and membrane hyperpolarization were reduced in the Caf group. Large-conductance Ca-activated K (BKCa) channel inhibitor iberiotoxin significantly attenuated forskolin-induced vasodilatation and reduced depolarization in the control, not in the Caf group. The PKA agonist-activated cell-attached single BKCa currents to a greater extent in the control. The mRNA and protein expression levels of PKA-Cα were decreased. The sensitivity of ryanodine receptors to the PKA agonist was blunted in the Caf group, whereas the mRNA expression of ryanodine receptor 2 subunit was reduced. Voltage/Ca sensitivity of BKCa was decreased accompanied by reduced mRNA and protein expression of BKCa-β1 subunits in the Caf group. PKA agonist-stimulated inside-out BKCa currents were weaker in the Caf group. Conclusion: Prenatal exposure to Caf-affected isoprenaline/forskolin-mediated vascular functions in aged cerebral arteries, related to dysfunction of the PKA/ryanodine receptors/BKCa signaling pathway.

Cerebral circulation is important in fetal brain development, and angiotensin II (Ang II) plays vital roles in regulation of adult cerebral circulation. However, functions of Ang II in fetal cerebral vasculature and influences of in utero hypoxia on Ang II-mediated fetal cerebral vascular responses are largely unknown. This study investigated the effects and mechanisms of in utero hypoxia on fetal middle cerebral artery (MCA) via Ang II. Near-term ovine fetuses were exposed to in utero hypoxia, and fetal MCA responses to Ang II were tested for vascular tension, calcium transient, and molecular analysis. Ang II caused significant dose-dependent contraction in control fetal MCA. Ang II-induced MCA constriction was decreased significantly in hypoxic fetuses. Neither losartan (AT1R antagonist, 10-5 mol/L) nor PD123,319 (AT2R antagonist, 10-5 mol/L) altered Ang II-mediated contraction in fetal MCA. Phenylephrine-mediated constriction was also significantly weaker in hypoxic fetuses. Bay K8644 caused similar contractions between the two groups. Protein expression of L-type voltage-dependent calcium channels was unchanged. There were no differences in caffeine-mediated vascular tension or calcium transients. Contraction induced by PDBu (PKC agonist) was obviously weaker in hypoxic MCA. Protein expression of PKCβ was reduced in the hypoxic compared with the control, along with no differences in phosphorylation levels. The results showed that fetal MCA was functionally responsive to Ang II near term. Intrauterine hypoxia reduced the vascular agonist-mediated contraction in fetal MCA, probably via decreasing PKCβ and its phosphorylation, which might play protective effects on fetal cerebral circulation against transient hypoxia.

Aims: Assisted reproductive technologies (ART) have been widely used to treat infertility, which may impact on fetuses and offspring. This study investigated the effects of in vitro fertilization-embryo transfer (IVF-ET) on angiotensin II (AII)-mediated vasoconstrictions in umbilical cord vein, and explored possible reprogrammed methylation mechanism. Materials and methods: Human umbilical cords were randomly divided into ordinary pregnancy and IVF-ET pregnancy. Vascular studies with AII as well as its specific receptor antagonists losartan and PD123,319 were conducted. Real-time quantitative PCR, Western blotting, and methylation analysis by bisulfite sequencing were performed with the cord vessel samples. Key findings: In IVF-ET group, the maximal response to AII in umbilical vessels was significantly greater than that in the ordinary pregnancy. Using losartan and PD123,319, angiotensin receptor subtype 1 (AT1R) was found mainly responsible for the enhanced contraction in the umbilical vein of IVF-ET pregnancy. Decreased mRNA expression of DNMT3A was found in umbilical vein of IVF-ET group. Hypomethylation of the AGTR1 gene (gene encoding AT1R) in the umbilical veins of the IVF group was found. The data suggested that the IVF-ET treatments altered AII-mediated vasoconstrictions in umbilical veins, which could be partially attributed to the increased expression of AT1R. Significance: The hypo-methylation of the AGTR1 gene caused by IVF-ET might play important roles in altered vasoconstrictions, impacting on cardiovascular systems in the long run.

Background: Pre-eclampsia is a leading cause of maternal mortality and morbidity. Although the exact mechanisms that cause pre-eclampsia remain unclear, it is undeniable that abnormal placental function and circulation are a center for initiation pre-eclampsia. As a potent vasoconstrictor, arginine vasopressin (AVP) has long been implicated in controlling placental vascular tone and circulation; its secretion is grossly elevated in pre-eclamptic circulation. However, little is known about the reactivity of AVP in pre-eclamptic placental vasculature. Methods: To reveal the special features of placental vascular regulations with placental pathophysiological changes, as well as the corresponding molecular mechanisms under pre-eclamptic conditions, vascular function and molecular assays were conducted with placental vessel samples from normal and pre-eclamptic pregnancies. Findings: The present study found that vasoconstriction responses of placental vessels to AVP were attenuated in pre-eclampsia as compared to in normal pregnancy. The insensitivity of AVP was correlated with the down-regulated AVP receptor 1a (AVPR1A, AVPR1A gene) and protein kinase C isoform β (PKCβ, PKCΒ gene), particularly the hyper-methylation-mediated AVPR1A and PKCΒ gene down-regulation, respectively. Interpretation: The findings collectively revealed that aberrant DNA methylation-mediated gene expressions are correlated with vascular dysfunction in pre-eclamptic placental circulation. FUND: This work was supported by National Nature & Science Foundation of China. "333 Project", "Six one project", "Shuang Chuang Tuan Dui" and Key Discipline "Fetal medicine" of Jiangsu Province, and the Suzhou city "Wei Sheng Ren Cai" program.

Prenatal hypoxia can induce cardiovascular diseases in the offspring. This study determined whether and how prenatal hypoxia may cause malignant hypertension and impaired vascular functions in spontaneous hypertension rat (SHR) offspring at adolescent stage. Pregnant SHR were placed in a hypoxic chamber (11% O2) or normal environment (21% O2) from gestational day 6 until birth. Body weight and blood pressure (BP) of SHR offspring were measured every week from 5 weeks old. Mesenteric arteries were tested. Gestational hypoxia resulted in growth restriction during 6–12 weeks and a significant elevation in systolic pressure in adolescent offspring at 12 weeks old. Notably, endothelial vasodilatation of mesenteric arteries was impaired in SHR adolescent offspring exposed to prenatal hypoxia, vascular responses to acetylcholine (ACh) and sodium nitroprusside (SNP) were reduced, as well as plasma nitric oxide levels and expression of endothelial nitric oxide synthase (eNOS) in vessels were decreased. Moreover, mesenteric arteries in SHR offspring following prenatal hypoxia showed enhanced constriction responses to phenylephrine (PE), associated with up-regulated activities of L-type calcium channel (Ca²⁺-dependent), RhoA/Rock pathway signaling (Ca²⁺-sensitization), and intracellular Ca²⁺ flow. Pressurized myograph demonstrated altered mechanical properties with aggravated stiffness in vessels, while histological analysis revealed vascular structural disorganization in prenatal hypoxia offspring. The results demonstrated that blood pressure and vascular function in young SHR offspring were affected by prenatal hypoxia, providing new information on development of hypertension in adolescent offspring with inherited hypertensive backgrounds.

Pre‐eclampsia is associated with inadequate placental blood flow and placental ischaemia. Placental vascular tone is essential for maintaining adequate placental blood flow. Oxytocin is increased in placental system at late pregnancy and onset of labour, and presented strongly concentration‐dependent contractions in placental vascular, suggesting that oxytocin could be involved in regulating placental vascular tone and circulation. However, information about the reactivity of oxytocin in pre‐eclamptic placental vasculature is limited. This study used a large number of human placentas to reveal the pathophysiological changes and its underlying mechanisms of oxytocin‐induced vasoconstrictions in placental vessels under pre‐eclamptic condition. Present study found that oxytocin‐induced contractions were significantly decreased in human pre‐eclamptic placental vasculature, associated with a deactivated transcription of oxytocin receptor gene. The deactivated oxytocin receptor gene transcription was ascribed to a relatively higher DNA methylation status of CpG islands in oxytocin receptor gene promoter. This study was first to reveal that a hyper‐methylation of CpG islands in oxytocin receptor gene promoter, leading to a relatively low pattern of oxytocin receptor expression, was responsible for the decreased sensitivity of oxytocin in pre‐eclamptic placental vessels.

Prenatal hypoxia can affect vascular functions in young offspring. However, there is limited knowledge regarding whether and how prenatal hypoxia influences vascular functions in aged offspring. This study compared the effects of prenatal hypoxia on the mesenteric arteries (MA) between a young adult and aged offspring and investigated the underlying mechanisms. Pregnant rats were randomly divided into the control and prenatal hypoxia groups. The vascular functions and molecular levels were assessed in 5-month-old (5 M) or 20-month-old (20 M) offspring. Prenatal hypoxia decreased acetylcholine-mediated vascular relaxations in 20-M but not 5-M offspring. Sodium nitroprusside-mediated relaxation curves were not altered by prenatal hypoxia in 5- and 20-M offspring. Prenatal hypoxia enhanced the contractile responses caused by phenylephrine, phorbol 12,13-dibutyrate, and 5-hydroxytryptamine only in 5-M offspring. The endothelial NO synthase (eNOS) activities were decreased along with downregulated eNOS mRNA expression and phosphorylated eNOS/total eNOS protein expression in 20-M offspring with prenatal hypoxia. The NADPH oxidase (NOX) inhibitor apocynin and superoxide dismutase (SOD) mimetic tempol restored the acetylcholine-mediated weaker relaxations in 20-M offspring with prenatal hypoxia. Enzyme-linked immunosorbent and dihydroethidium assay showed that prenatal hypoxia enhanced oxidative stress in 20-M offspring. Transmission electron microscopy showed that prenatal hypoxia damaged mitochondrial structures in the MA endothelial cells of 20-M offspring. Increased NOX2 protein expression and decreased SOD3 expression were found in 20-M offspring. The results demonstrated that endothelial dysfunction induced by intrauterine hypoxia occurred with aging via enhanced oxidative stress and decreased nitric oxide activities in aged offspring.