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Intergenerational effects of prenatal hypoxia exposure on uterine artery adaptations to pregnancies in the female offspring

Published online by Cambridge University Press:  26 May 2022

Amy L. Wooldridge Open the ORCID record for Amy L. Wooldridge [Opens in a new window] ,
Nataliia Hula ,
Raven Kirschenman ,
Floor Spaans ,
Christy-Lynn M. Cooke  and
Sandra T. Davidge Open the ORCID record for Sandra T. Davidge [Opens in a new window]
Amy L. Wooldridge
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada
Nataliia Hula
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada Department of Physiology, University of Alberta, Edmonton, Canada
Raven Kirschenman
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada
Floor Spaans
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada
Christy-Lynn M. Cooke
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada
Sandra T. Davidge*
Affiliation:
Department of Obstetrics and Gynaecology, Women and Children’s Health Research Institute, University of Alberta, Edmonton, Canada Department of Physiology, University of Alberta, Edmonton, Canada
*
Address for correspondence: Sandra T. Davidge, PhD, FCAHS, FRSC, Distinguished University Professor, University of Alberta, 232 Heritage Medical Research Centre (HMRC), 11207-87 Ave, Edmonton, Alberta, Canada T6G 2S2. Email: sandra.davidge@ualberta.ca
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Abstract

Prenatal hypoxia is a common complication of pregnancy and is associated with detrimental health outcomes, such as impaired cardiac and vascular function, in adult offspring. Exposure to prenatal hypoxia reportedly impacts the reproductive system of female offspring. Whether exposure to prenatal hypoxia influences pregnancy adaptations and outcomes in these female offspring is unknown. We hypothesised that prenatal hypoxia impairs uterine artery adaptations in pregnancies of the adult offspring. Pregnancy outcomes and uterine artery function were assessed in 14–16 weeks old non-pregnant and late pregnant (gestational day 20; term = 22 days) adult female offspring born to rats exposed to prenatal normoxia (21% oxygen) or hypoxia (11% oxygen, between days 15–21 of gestation). Compared with normoxia controls, prenatal hypoxia was associated with pregnant adult offspring having reduced placental weights in their litters, and uterine artery circumferential stress that increased with pregnancy. Overall, prenatal hypoxia adversely, albeit mildly, compromised pregnancies of adult offspring.

Keywords

Prenatal hypoxiaF1 offspringdevelopmental programminguterine arteryvascular endothelial function
Type
Brief Reports
Information
Journal of Developmental Origins of Health and Disease , Volume 13 , Issue 6 , December 2022 , pp. 794 - 799
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2022. Published by Cambridge University Press in association with International Society for Developmental Origins of Health and Disease

Introduction

Prenatal hypoxia represents an adverse intrauterine environment, and occurs with many pregnancy complications. Prenatal hypoxia is a major cause of intrauterine growth restriction and contributes to adverse developmental programming, Reference Giussani and Davidge1 such as impaired cardiovascular function in the adult offspring. Reference Rueda-Clausen, Morton, Lopaschuk and Davidge2,Reference Reyes, Morton, Kirschenman, DeLorey and Davidge3 The reproductive system of female offspring was also reported to be adversely affected Reference Aiken, Tarry-Adkins and Spiroski4Reference Giussani, Camm and Niu6 ; however, it is unknown whether this extends to the arteries supplying the reproductive system.

Pregnancy requires substantial maternal haemodynamic adaptations, including increased blood volume, cardiac output and decreased peripheral vascular resistance. Reference Thornburg, Jacobson, Giraud and Morton7 Extensive remodelling of the uteroplacental vasculature is critical to increase artery diameter, which facilitates sufficient blood supply to transport nutrients and oxygen to the placenta and developing fetus. Reference Osol, Ko and Mandalà8 Maternal vascular function during pregnancy appears to be altered with maternal hypoxia. For instance, pregnant mice exposed to hypoxic conditions (chronic intermittent hypoxia during the light cycle of 12 h, 12% oxygen) throughout pregnancy from gestational day (GD) 0.5 had reduced maximal uterine artery endothelium-dependent vasodilation on GD14.5 (term = 19 days) compared to normoxia-exposed (21% oxygen) pregnant mice. Reference Badran, Abuyassin, Ayas and Laher9 Pregnant rats exposed to hypoxia (11% oxygen, continuously) from GD6–20 (term = 22 days) had uterine arteries with impaired endothelium-dependent vasodilation compared to uterine arteries from control pregnant rats. Reference Aljunaidy, Morton, Cooke and Davidge10 Moreover, at GD45 (term = 63 days), guinea pigs directly exposed to chronic hypoxia (continuously, via a simulated altitude of 3960 m that resulted in an inspired pO2 of 90 Torr) from within 3 days of conception had uterine arteries with greater distensibility, decreased stiffness, and lower elastin levels than normoxia-exposed controls (continuously, via the laboratory altitude of 1600 m that resulted in an inspired pO2 of 125 Torr). Reference Mateev, Mouser, Young, Mecham and Moore11

In addition to the maternal impacts, prenatal exposure to hypoxia clearly affects progeny cardiovascular health. For instance, we showed that imposing maternal hypoxia during late pregnancy (11.5% oxygen, continuously from GD15 to term) in rats reduced offspring tolerance to ischaemia-reperfusion injury and reduced cardiac efficiency. Reference Rueda-Clausen, Morton, Lopaschuk and Davidge2 In the same model, we showed that nitric oxide (NO)-dependent relaxation in mesenteric and gastrocnemius muscle arteries was impaired in female offspring. Reference Reyes, Morton, Kirschenman, DeLorey and Davidge3 Moreover, adult rat offspring exposed to maternal hypoxia from early pregnancy (GD6) to term had markedly impaired NO-dependent relaxation in femoral resistance arteries and aortic thickening with increased peroxynitrite generation, which can lead to endothelial dysfunction. Reference Giussani, Camm and Niu6 Vascular endothelial dysfunction in adult offspring prenatally exposed to hypoxic conditions has also been shown in mice, guinea pigs, chickens, sheep and humans (reviewed in Giussani Reference Giussani12 ). Despite this evidence of widespread effects of prenatal hypoxia on endothelium-dependent arterial function in adult offspring, the effects on reproductive outcomes in female offspring require further study. Specifically, it remains unknown whether exposure of dams (F0) to hypoxia also impairs endothelium-dependent vascular function of uterine arteries of the female progeny (F1), and whether this affects pregnancy-induced adaptations. We hypothesised that female rat offspring exposed in utero to maternal hypoxia have impaired vascular adaptations to pregnancy, leading to adverse pregnancy outcomes. To test this, we used a rat model of prenatal hypoxia and assessed endothelium-dependent vasodilation and passive circumferential stress–strain properties of uterine arteries from first generation non-pregnant and pregnant rats exposed to normoxia or hypoxia prenatally.

Methods

Animal model

This study took into account guidelines on designing DOHaD studies. Reference Dickinson, Moss and Gatford13 Sprague Dawley rats were housed in the Animal Care Facility at the University of Alberta, which maintains an ambient temperature of 22 ± 1°C and a 14:10 h (light:dark) lighting schedule. The rats had ad libitum access to standard rat chow and water. All experiments were done in the female offspring (F1) of dams (F0) that had been exposed to hypoxia during late pregnancy, an established model of fetal hypoxia. Reference Ganguly, Aljunaidy and Kirschenman14 For the F0 rats, 14–16 week-old females (Charles River, Canada) were mated overnight. Pregnancy was confirmed the next morning by the presence of a plug or sperm in a vaginal smear (designated as GD0), and pregnant dams were single-housed. From GD15, the F0 dams were then exposed to hypoxia (11% O2) by placing their cage into a hypoxic chamber, or they continued to be housed in standard atmospheric oxygen conditions (21% O2) as normoxia controls. Dams were removed from the hypoxic chamber on GD21 (term = GD22) and delivered naturally at atmospheric oxygen conditions. Upon delivery, litter size was reduced to 8 pups/litter (four males and four females) to standardise postnatal conditions. Male F1 offspring were used in another study, Reference Hula, Spaans and Vu15 while the female F1 offspring (F1 rats that had been prenatally exposed to either normoxia or hypoxia, respectively, and then studied as adults, termed F1-pNormoxia and F1-pHypoxia, respectively) were used in the current study. The F1 females were weaned on postnatal day 21 and were housed in pairs until 14–16 weeks of age. At 14–16 weeks of age, the F1 females were randomly allocated to either non-pregnant or pregnant groups. Rats allocated to the pregnant group were mated, as described above. Pregnant F1 females at GD20 and age-matched, non-pregnant F1 females were humanely killed via exsanguination under isoflurane-induced anaesthesia. The uterine vasculature was excised and placed into ice-cold HEPES-buffered physiological saline solution (PSS; in mmol/L: 142 NaCl, 4.7 KCl, 1.17 MgSO4, 4.7 CaCl2, 1.18 K2PO4, 10 HEPES, 5.5 glucose, pH 7.4) for vascular experiments. Pregnancy outcomes of the F1 dams (litter size, numbers of reabsorptions, placental weight, and fetal sex, weight, crown-rump length and abdominal girth) were recorded.

Ex vivo vascular function

A segment of the right main uterine artery was isolated from adipose tissue and mounted on two glass cannulas in a pressure myograph (Living Systems, Burlington, US) containing PSS at 37°C. Intravascular pressure was controlled throughout the experiment using a pressure servo control PS/200 and perfusion pressure monitor. Vessel and wall diameters were measured using a digital filar eyepiece (Lasico, model 1602E-10) and processor, attached to a stereo microscope (Olympus, model SZH10). Arteries were equilibrated for 40 min, during which they were exposed to a stepwise increase in pressure from 60 to 80 mmHg. Reference Morton, Rueda-Clausen and Davidge16 The intraluminal pressure was then adjusted to 50 mmHg for a further 10 min prior to cumulative concentration response testing. For this, vessels were pre-constricted by adding an ∼pEC80 dose (the mean effective concentration that produces 80% of the maximal response) of phenylephrine (PE, Millipore Sigma #P6126) to the bath. Arteries were pre-constricted for at least 5 min (with stable internal diameter), after which a cumulative concentration response curve to superfused methylcholine (MCh; range 0.0001–100 µm; Millipore Sigma #A2251) was generated. Passive artery characteristics were assessed in relaxed arteries, which was done using Ca2+-free solution containing EGTA (in mmol/L: 142 NaCl, 4.7 KCl, 1.17 MgSO4, 1.18 KH2PO4, 10 HEPES, 2 EGTA). The myograph bath solution was changed at least four times before the addition of superfused papaverine (0.1 µmol/l; Sigma). Following a 20 min equilibration at 50 mmHg, passive characteristics (arterial diameters and wall thicknesses) were assessed across 4–160 mmHg, with intervals of ≥ 1 min between each step.

Dose-response data were analysed as pEC75 (75% of the dose required to produce the maximum vasodilation response to MCh) and Emax (the maximum vessel response to MCh) using Prism (v9.0.0, GraphPad Software, San Diego, US). Circumferential wall stress and wall strain were calculated as described previously Reference Care, Bourque, Morton, Hjartarson and Davidge17 using the initial vessel diameter measured at 4 mmHg. Circumferential stress-strain data were analysed as area under the curve (AUC).

Statistical Analyses

Data were analysed using GraphPad Prism (v9.2.0, San Diego, US). The effect of F0 dam exposure on F1 dam pregnancy outcomes was analysed by t-test (or Mann Whitney U-test for reabsorptions), pregnancy outcomes were assessed by two-way ANOVA with Sidak post-hoc test (prenatal hypoxia and fetal sex as the two factors) and vascular outcomes were assessed by two-way ANOVA with Sidak post-hoc test (prenatal hypoxia and F1 pregnancy status as the two factors). Data are mean ± SEM; p < 0.05 was considered statistically significant; n = number of F1 female offspring, 1–2 offspring was used per F0 dam, with n = 4–6 F0 dams per group represented in each outcome.

Results

Pregnancy outcomes (F1)

F1-pNormoxia and F1-pHypoxia dams at GD20 had similar body weights, litter sizes, reabsorptions, fetal weights (Table 1) and fetal sex ratios (data not shown). The F1-pHypoxia dams had litters with lower placental weights than F1-pNormoxia dams (p = 0.042, Table 1). Litters from F1-pNormoxia and F1-pHypoxia dams had similar placental efficiency (fetal:placental weight ratio), fetal abdominal girth, fetal crown-rump length, and fetal crown-rump length:abdominal girth ratio (Table 1), none of which were affected by fetal sex (Table 1).

Table 1. Pregnancy outcomes of F1 dams

Number of viable fetuses and reabsorptions, and body weight, placental weight, fetal:placental weight ratio, abdominal girth, and crown-rump length on gestational day 20 from adult F1 dams that were exposed before birth to maternal normoxia or hypoxia. Data presented as mean ± SEM unless otherwise stated; n = represents litter average; n = 5–6 F1 dams/group. Data from F1 pregnancies are sex-specific means of litter outcomes. Number of viable fetuses were compared using a t-test and reabsorptions were compared using a Mann Whitney U-test. Fetal outcomes were compared using a two-way ANOVA (F1 treatment vs. fetal sex) followed by Sidak’s post hoc test.

* p < 0.042 main effect of pHypoxia vs pNormoxia (sexes combined).

Uterine artery endothelial function and mechanical properties

Arteries from non-pregnant F1-pHypoxia offspring were less sensitive to MCh than those from non-pregnant F1-pNormoxia rats (p = 0.0391, Fig. 1A, 1B). Sensitivity to MCh was similar between arteries of non-pregnant and pregnant rats in both groups (Fig. 1A, 1B).

Fig. 1. Uterine artery function and mechanical properties. MCh-induced (A) vasodilation responses and (B) summary of MCh sensitivity (pEC75), and (C) circumferential stress-strain curves, and the summary data (area under the curve; AUC) of circumferential (D) stress and (E) strain from main uterine arteries of adult pregnant (closed circles) and non-pregnant (open circles) F1 offspring exposed to in utero to prenatal normoxia (pNormoxia; red) or hypoxia (pHypoxia; blue). Data are presented as mean ± SEM; n = 4–6 F1 offspring/group; from n = 4–6 F0 dams; 1–2 offspring/dam. All groups were compared using a two-way ANOVA followed by Sidak’s post hoc test. *p < 0.05; **p < 0.01; ***p < 0.001.

Circumferential stress was similar between arteries of F1-pNormoxia non-pregnant and pregnant rats, but within the F1-pHypoxia rats, arteries from pregnant rats had greater circumferential stress than those from non-pregnant rats (Fig. 1C, 1D, p = 0.0046; interaction p = 0.0431). Arteries from pregnant rats had greater circumferential strain (Fig. 1C, 1E, p = 0.0003) and absolute diameter (AUC Non-pregnant 690 ± 12, Pregnant 1010 ± 17; p < 0.0001) than non-pregnant rats, and pHypoxia did not affect circumferential strain or absolute diameter. Pregnancy adaptations of main uterine arteries from F1-pHypoxia offspring did not significantly differ from F1-pNormoxia offspring in circumferential strain (Fig. 1C, 1E) or unconstricted (passive) artery diameters over a pressure range of 4–160 mmHg (data not shown). Wall thickness (AUC, data not shown) did not differ between the groups.

Discussion

Overall, the effects of in utero exposure to prenatal hypoxia on adult offspring pregnancies were adverse, albeit mild of the parameters that we assessed. Pregnancies in adult F1-pHypoxia female offspring were not associated with greatly impaired main uterine artery function (endothelium-dependent vasodilation and structural properties) or reduced fetal weights at GD20, although we did observe reduced placental weights. It may be suggested that the impaired endothelium-dependent vasodilation observed in uterine arteries from non-pregnant F1-pHypoxia offspring was able to be negated by GD20 by other, compensatory, adaptations against the effects of in utero hypoxia in the pregnant F1-pHypoxia offspring.

Against our expectations, we saw no differences in fetal outcomes as the result of F1 in utero exposure to maternal hypoxia; however, the placental weights of litters from F1-pHypoxia dams were significantly lower than those of F1-pNormoxia dams. This did not translate to a difference in placental efficiency, possibly due to low n numbers. Others have reported no difference in placental weight or efficiency in the pregnancies of F1 female rats that had been born to an F0 dam whose pregnancy had been compromised via bilateral uterine vessel ligation on GD18. Reference Mangwiro, Cuffe and Briffa18 A smaller placenta may indicate impaired early placental development and growth, and while fetal weights were similar between the groups, the smaller placental size may have had other detrimental effects on fetal development that were not assessed. Additionally, the smaller placentas may not adapt to compounded pregnancy challenges Reference Eskild, Strøm-Roum and Haavaldsen19 such as advanced maternal age. Moreover, as we only collected data at GD20, it is possible that impaired placental and fetal development may have differed between groups at earlier or later time points that were not assessed in the present study.

Our finding that in utero exposure to hypoxia impairs MCh-induced vasodilation of uterine arteries of non-pregnant rats is consistent with reports of impaired MCh-induced relaxation of arteries from different vascular beds of adult rats born to pregnancies compromised by hypoxia. Reference Reyes, Morton, Kirschenman, DeLorey and Davidge3,Reference Giussani, Camm and Niu6 Others have reported changes in the reproductive organs of adult females previously exposed in utero to maternal hypoxia. Exposure to chronic hypoxia during fetal development resulted in offspring with accelerated biological ageing of the oviduct Reference Aiken, Tarry-Adkins and Spiroski4 and ovaries, including a reduced ovarian reserve. Reference Aiken, Tarry-Adkins and Spiroski5 The reduced sensitivity to MCh may indicate a more constrictive vascular phenotype. Overall, these data add to the literature on the effects of in utero exposure to maternal hypoxia on offspring reproductive health, by confirming that this impaired endothelium-dependent vasodilation exists in another vascular bed, at least in non-pregnant offspring.

Prenatal exposure to maternal (F0) hypoxia resulted in greater F1 uterine artery circumferential stress, albeit only in the pregnant state. This was not due to differences in wall thickness, which was not different with pHypoxia and which contributes to the calculation of circumferential stress. The subtle structural differences in the present study suggests that some direct effects of hypoxia that have been reported on F0 uterine arteries, such as (in guinea pigs) a 4-fold greater distensibility, decreased stiffness, and 50% reduction in elastin levels Reference Mateev, Mouser, Young, Mecham and Moore11 appear to be less prominent in the F1 generation. Non-pregnant 18-month-old adult rats that had been growth-restricted in utero (bilateral uterine artery and vein ligation from GD18) had uterine arteries with increased arterial wall stiffness and smaller outer diameters over the pressurisation range compared with uterine arteries from rats that were born to sham control dams. Reference Mazzuca, Wlodek, Dragomir, Parkington and Tare20 It is possible that with age, the effects of an adverse intrauterine environment becomes apparent. Regardless, it would be interesting to assess whether the F2 generation may still display an adverse uterine artery phenotype during their own later pregnancy due to the F0 exposure, as observed with other pregnancy complication models. Reference Aiken, Tarry-Adkins and Ozanne21

The timing of hypoxia exposure within the present study (11% O2, GD15–21) was focused on the period of most rapid fetal growth (GD13–20), Reference Knox and Lister-Rosenoer22 whereas other studies (13% O2, GD6–20) Reference Aiken, Tarry-Adkins and Spiroski4,Reference Aiken, Tarry-Adkins and Spiroski5 may have exposed dams across a wider range of fetal organ developmental periods. Subsequently, the F1-pHypoxia dams may not have been affected in a manner most likely to adversely affect the subsequent F2 fetuses. Fetal growth restriction of F1 rats can contribute to fetal growth restriction in the F2 generation, as others have shown using a bilateral uterine artery and vein ligation (from GD18) rat model. Reference Gallo, Tran and Moritz23 However, this may have been indirectly caused by an altered F1 adult offspring phenotype that affected the F1 pregnancy, such as impaired glucose regulation, rather than direct programming effects from the F2 (as oocytes) insult of uterine artery and vein ligation. Reference Gallo, Tran and Moritz23

Prenatal hypoxia can be caused by many pregnancy complications, including placental insufficiency, maternal cardiac disease and preeclampsia. The uterine arteries of non-pregnant female F1 offspring exposed prenatal hypoxia demonstrated impaired endothelium-dependent vasodilation, though these differences were not observed in arteries of F1 pregnant offspring. This implies, at least for young females born to compromised pregnancies themselves, that their pregnancy adaptations may be able to overcome impairments to achieve pregnancies with normal fetal weights. The smaller placental size observed in the pregnancies of F1 offspring exposed to prenatal hypoxia may reflect impaired early placental development and growth, which may affect developmental programming of F2 adult offspring health. Additionally, a smaller placental size in the presence of additional maternal risk factors (such as maternal ageing or obesity) could have a greater impact on pregnancy outcomes for an F1-pHypoxia than an F1-pNormoxia pregnancy. Overall, prenatal hypoxia adversely affects pregnancies in adult offspring. Further studies are needed to assess the full impact of prenatal hypoxia on subsequent pregnancies in the offspring.

Acknowledgements

The authors thank the staff of Health Sciences Laboratory Animal Services for animal care.

Financial support

AW is supported by postdoctoral fellowships from the Canadian Institutes of Health Research (CIHR), Alberta Innovates, and the Women and Children’s Health Research Institute (WCHRI). This WCHRI postdoctoral fellowship award is funded by the generosity of the Stollery Children’s Hospital Foundation and the Alberta Women’s Health Foundation through WCHRI. This work was supported by a CIHR Foundation Grant (FS154313) and by the generosity of the Stollery Children’s Hospital Foundation and the Alberta Women’s Health Foundation through WCHRI. Dr Sandra Davidge is a former Tier 1 Canada Research Chair in Maternal and Perinatal Cardiovascular Health and a Distinguished University Professor at the University of Alberta.

Conflicts of interest

None.

Ethical standards

The authors assert that all procedures contributing to this work comply with the ethical standards of the relevant national guides on the care and use of laboratory animals (Canadian Council on Animal Care guidelines) and were approved by the institutional committee University of Alberta Health Sciences Animal Policy and Welfare Committee (AUPs #242 and #3693).

References

Giussani, DA, Davidge, ST. Developmental programming of cardiovascular disease by prenatal hypoxia. J Dev Orig Health Dis. 2013; 4(5), 328337.CrossRefGoogle ScholarPubMed
Rueda-Clausen, CF, Morton, JS, Lopaschuk, GD, Davidge, ST. Long-term effects of intrauterine growth restriction on cardiac metabolism and susceptibility to ischaemia/reperfusion. Cardiovasc Res. 2011; 90(2), 285294.CrossRefGoogle ScholarPubMed
Reyes, LM, Morton, JS, Kirschenman, R, DeLorey, DS, Davidge, ST. Vascular effects of aerobic exercise training in rat adult offspring exposed to hypoxia-induced intrauterine growth restriction. J Physiol. 2015; 593(8), 19131929.CrossRefGoogle ScholarPubMed
Aiken, CE, Tarry-Adkins, JL, Spiroski, AM, et al. Chronic fetal hypoxia disrupts the peri-conceptual environment in next-generation adult female rats. J Physiol. 2019; 597(9), 23912401.CrossRefGoogle ScholarPubMed
Aiken, CE, Tarry-Adkins, JL, Spiroski, AM, et al. Chronic gestational hypoxia accelerates ovarian aging and lowers ovarian reserve in next-generation adult rats. FASEB J. 2019; 33(6), 77587766.CrossRefGoogle ScholarPubMed
Giussani, DA, Camm, EJ, Niu, Y, et al. Developmental programming of cardiovascular dysfunction by prenatal hypoxia and oxidative stress. PLoS One. 2012; 7(2), e31017.CrossRefGoogle ScholarPubMed
Thornburg, KL, Jacobson, SL, Giraud, GD, Morton, MJ. Hemodynamic changes in pregnancy. Semin Perinatol. 2000; 24(1), 1114.CrossRefGoogle ScholarPubMed
Osol, G, Ko, NL, Mandalà, M. Plasticity of the maternal vasculature during pregnancy. Annu Rev Physiol. 2019; 81(1), 89111.CrossRefGoogle ScholarPubMed
Badran, M, Abuyassin, B, Ayas, N, Laher, I. Intermittent hypoxia impairs uterine artery function in pregnant mice. J Physiol. 2019; 597(10), 26392650.CrossRefGoogle ScholarPubMed
Aljunaidy, MM, Morton, JS, Cooke, CL, Davidge, ST. Maternal vascular responses to hypoxia in a rat model of intrauterine growth restriction. Am J Physiol Regul Integr Comp Physiol. 2016; 311(6), R1068r1075.CrossRefGoogle Scholar
Mateev, SN, Mouser, R, Young, DA, Mecham, RP, Moore, LG. Chronic hypoxia augments uterine artery distensibility and alters the circumferential wall stress-strain relationship during pregnancy. J Appl Physiol. 2006; 100(6), 18421850.CrossRefGoogle ScholarPubMed
Giussani, DA. Breath of life: heart disease link to developmental hypoxia. Circulation. 2021; 144(17), 14291443.CrossRefGoogle ScholarPubMed
Dickinson, H, Moss, TJ, Gatford, KL, et al. A review of fundamental principles for animal models of DOHaD research: an Australian perspective. J Dev Orig Hlth Dis. 2016; 7(5), 449472.CrossRefGoogle Scholar
Ganguly, E, Aljunaidy, MM, Kirschenman, R, et al. Sex-specific effects of nanoparticle-encapsulated MitoQ (nMitoQ) delivery to the placenta in a rat model of fetal hypoxia. Front Physiol. 2019; 10(562), 1699.CrossRefGoogle Scholar
Hula, N, Spaans, F, Vu, J, et al. Placental treatment improves cardiac tolerance to ischemia/reperfusion insult in adult male and female offspring exposed to prenatal hypoxia. Pharmacol Res. 2021; 165(9), 105461.CrossRefGoogle ScholarPubMed
Morton, JS, Rueda-Clausen, CF, Davidge, ST. Flow-mediated vasodilation is impaired in adult rat offspring exposed to prenatal hypoxia. J Appl Physiol. 2011; 110(4), 10731082.CrossRefGoogle ScholarPubMed
Care, AS, Bourque, SL, Morton, JS, Hjartarson, EP, Davidge, ST. Effect of advanced maternal age on pregnancy outcomes and vascular function in the rat. Hypertension. 2015; 65(6), 13241330.CrossRefGoogle ScholarPubMed
Mangwiro, YTM, Cuffe, JSM, Briffa, JF, et al. Maternal exercise in rats upregulates the placental insulin-like growth factor system with diet- and sex-specific responses: minimal effects in mothers born growth restricted. J Physiol. 2018; 596(23), 59475964.CrossRefGoogle ScholarPubMed
Eskild, A, Strøm-Roum, EM, Haavaldsen, C. Does the biological response to fetal hypoxia involve angiogenesis, placental enlargement and preeclampsia? Paediatr Perinat Epidemiol. 2016; 30(3), 305309.CrossRefGoogle ScholarPubMed
Mazzuca, MQ, Wlodek, ME, Dragomir, NM, Parkington, HC, Tare, M. Uteroplacental insufficiency programs regional vascular dysfunction and alters arterial stiffness in female offspring. J Physiol. 2010; 588(11), 19972010.CrossRefGoogle ScholarPubMed
Aiken, CE, Tarry-Adkins, JL, Ozanne, SE. Transgenerational developmental programming of ovarian reserve. Sci Rep. 2015; 5(1), 16175.CrossRefGoogle ScholarPubMed
Knox, WE, Lister-Rosenoer, LM. Timing of gestation in rats by fetal and maternal weights. Growth. 1978; 42(1), 4353.Google ScholarPubMed
Gallo, LA, Tran, M, Moritz, KM, et al. Cardio-renal and metabolic adaptations during pregnancy in female rats born small: implications for maternal health and second generation fetal growth. J Physiol. 2012; 590(3), 617630.CrossRefGoogle ScholarPubMed
Figure 0

Table 1. Pregnancy outcomes of F1 dams

Figure 1

Fig. 1. Uterine artery function and mechanical properties. MCh-induced (A) vasodilation responses and (B) summary of MCh sensitivity (pEC75), and (C) circumferential stress-strain curves, and the summary data (area under the curve; AUC) of circumferential (D) stress and (E) strain from main uterine arteries of adult pregnant (closed circles) and non-pregnant (open circles) F1 offspring exposed to in utero to prenatal normoxia (pNormoxia; red) or hypoxia (pHypoxia; blue). Data are presented as mean ± SEM; n = 4–6 F1 offspring/group; from n = 4–6 F0 dams; 1–2 offspring/dam. All groups were compared using a two-way ANOVA followed by Sidak’s post hoc test. *p < 0.05; **p < 0.01; ***p < 0.001.