The contribution of a suboptimal reproductive tract environment or maternal adaptations to pregnancy may be critical to inheritance of programming effects via the maternal line. As the effects of age exacerbate the programmed metabolic phenotype, advancing maternal age may increase the likelihood of developmental programming effects being transmitted to further generations. We suggest that developmental programming effects could be propagated through the maternal line de novo in generations beyond F2 as a consequence of development in a suboptimally developed intrauterine tract and not necessarily though directly transmitted epigenetic mechanisms.
Low birth weight and accelerated postnatal growth lead to increased risk of cardiovascular disease. We reported previously that rats exposed to a low-protein diet in utero and postnatal catch-up growth (recuperated) develop metabolic dysfunction and have reduced life span. Here we explored the hypothesis that cardiac oxidative and nitrosative stress leading to DNA damage and accelerated cellular aging could contribute to these phenotypes. Recuperated animals had a low birth weight (P<0.001) but caught up in weight to controls during lactation. At weaning, recuperated cardiac tissue had increased (P<0.05) protein nitrotyrosination and DNA single-stranded breaks. This condition was preceded by increased expression of DNA damage repair molecules 8-oxoguanine-DNA-glycosylase-1, nei-endonuclease-VIII-like, X-ray-repair-complementing-defective-repair-1, and Nthl endonuclease III-like-1 on d 3. These differences were maintained on d 22 and became more pronounced in the case of 8-oxoguanine-DNA-glycosylase-1 and nei-endonuclease-VIII-like. This was accompanied by increases in xanthine oxidase (P<0.001) and NADPH oxidase (P<0.05), major sources of reactive oxygen species (ROS). The detrimental effects of increased ROS in recuperated offspring may be exaggerated at 22 d by reductions (P<0.001) in the antioxidant enzymes peroxiredoxin-3 and CuZn-superoxide-dismutase. We conclude that poor fetal nutrition followed by accelerated postnatal growth results in increased cardiac nitrosative and oxidative-stress and DNA damage, which could contribute to age-associated disease risk.
Maternal diet during pregnancy influences the later life reproductive potential of female offspring. We investigate the molecular mechanisms underlying the depletion of ovarian follicular reserve in young adult females following exposure to obesogenic diet in early life. Furthermore, we explore the interaction between adverse maternal diet and postweaning diet in generating reduced ovarian reserve. Female mice were exposed to either maternal obesogenic (high fat/high sugar) or maternal control diet in utero and during lactation, then weaned onto either obesogenic or control diet. At 12 wk of age, the offspring ovarian reserve was depleted following exposure to maternal obesogenic diet (P < 0.05), but not postweaning obesogenic diet. Maternal obesogenic diet was associated with increased mitochondrial DNA biogenesis (copy number P < 0.05; transcription factor A, mitochondrial expression P < 0.05), increased mitochondrial antioxidant defenses [manganese superoxide dismutase (MnSOD) P < 0.05; copper/zinc superoxide dismutase P < 0.05; glutathione peroxidase 4 P < 0.01] and increased lipoxygenase expression (arachidonate 12-lipoxygenase P < 0.05; arachidonate 15-lipoxygenase P < 0.05) in the ovary. There was also significantly increased expression of the transcriptional regulator NF-κB (P < 0.05). There was no effect of postweaning diet on any measured ovarian parameters. Maternal diet thus plays a central role in determining follicular reserve in adult female offspring. Our observations suggest that lipid peroxidation and mitochondrial biogenesis are the key intracellular pathways involved in programming of ovarian reserve.—Aiken, C. E., Tarry-Adkins, J. L., Penfold, N. C., Dearden, L., Ozanne, S. E. Decreased ovarian reserve, dysregulation of mitochondrial biogenesis, and increased lipid peroxidation in female mouse offspring exposed to an obesogenic maternal diet.
Early life exposure to adverse environments can lead to a variety of metabolic and cardiovascular diseases in offspring. We hypothesize that female reproductive function may also be affected, with subsequent implications for fertility. We used an established maternal low-protein model where animals are born small but undergo rapid postnatal catch-up growth by suckling a control-fed dam (recuperated offspring). Markers of oxidative stress and cellular aging in reproductive tract tissues were assessed at 3 and 6 mo of age. Recuperated offspring had lower birth weight than controls (P<0.01) but caught up during lactation. 4-Hydroxynonenal (4HNE; an indicator of oxidative stress) was increased in recuperated animals compared with controls in both ovaries and oviducts at 6 mo. At 3 and 6 mo, ovaries and oviducts of recuperated offspring had increased mitochondrial (mt)DNA copy number (P<0.01). By contrast, germ-line cells showed no difference in mtDNA copy number, suggesting they were protected from suboptimal maternal nutrition. Oviduct and somatic ovarian telomere length declined more rapidly with age in recuperated animals. This accelerated cellular aging was associated with a declined ovarian reserve in developmentally programmed animals. These findings have significant clinical implications in light of worldwide trends to delayed childbearing.
Background: It is well established that low birth weight and accelerated postnatal growth increase the risk of liver dysfunction in later life. However, molecular mechanisms underlying such developmental programming are not well characterized, and potential intervention strategies are poorly defined.Objectives: We tested the hypotheses that poor maternal nutrition and accelerated postnatal growth would lead to increased hepatic fibrosis (a pathological marker of liver dysfunction) and that postnatal supplementation with the antioxidant coenzyme Q10 (CoQ10) would prevent this programmed phenotype.Design: A rat model of maternal protein restriction was used to generate low-birth-weight offspring that underwent accelerated postnatal growth (termed “recuperated”). These were compared with control rats. Offspring were weaned onto standard feed pellets with or without dietary CoQ10 (1 mg/kg body weight per day) supplementation. At 12 mo, hepatic fibrosis, indexes of inflammation, oxidative stress, and insulin signaling were measured by histology, Western blot, ELISA, and reverse transcriptase–polymerase chain reaction.Results: Hepatic collagen deposition (diameter of deposit) was greater in recuperated offspring (mean ± SEM: 12 ± 2 μm) than in controls (5 ± 0.5 μm) (P < 0.001). This was associated with greater inflammation (interleukin 6: 38% ± 24% increase; P < 0.05; tumor necrosis factor α: 64% ± 24% increase; P < 0.05), lipid peroxidation (4-hydroxynonenal, measured by ELISA: 0.30 ± 0.02 compared with 0.19 ± 0.05 μg/mL per μg protein; P < 0.05), and hyperinsulinemia (P < 0.05). CoQ10 supplementation increased (P < 0.01) hepatic CoQ10 concentrations and ameliorated liver fibrosis (P < 0.001), inflammation (P < 0.001), some measures of oxidative stress (P < 0.001), and hyperinsulinemia (P < 0.01).Conclusions: Suboptimal in utero nutrition combined with accelerated postnatal catch-up growth caused more hepatic fibrosis in adulthood, which was associated with higher indexes of oxidative stress and inflammation and hyperinsulinemia. CoQ10 supplementation prevented liver fibrosis accompanied by downregulation of oxidative stress, inflammation, and hyperinsulinemia.
ABSTRACT‘Developmental programming’, which occurs as a consequence of suboptimal in utero and early environments, can be associated with metabolic dysfunction in later life, including an increased incidence of cardiovascular disease and type 2 diabetes, and predisposition of older men to sarcopenia. However, the molecular mechanisms underpinning these associations are poorly understood. Many conditions associated with developmental programming are also known to be associated with the aging process. We therefore utilized our well-established rat model of low birth weight and accelerated postnatal catch-up growth (termed ‘recuperated’) in this study to establish the effects of suboptimal maternal nutrition on age-associated factors in skeletal muscle. We demonstrated accelerated telomere shortening (a robust marker of cellular aging) as evidenced by a reduced frequency of long telomeres (48.5-8.6 kb) and an increased frequency of short telomeres (4.2-1.3 kb) in vastus lateralis muscle from aged recuperated offspring compared to controls. This was associated with increased protein expression of the DNA-damage-repair marker 8-oxoguanine-glycosylase (OGG1) in recuperated offspring. Recuperated animals also demonstrated an oxidative stress phenotype, with decreased citrate synthase activity, increased electron-transport-complex activities of complex I, complex II-III and complex IV (all markers of functional mitochondria), and increased xanthine oxidase (XO), p67phox and nuclear-factor kappa-light-chain-enhancer of activated B-cells (NF-κB). Recuperated offspring also demonstrated increased antioxidant defense capacity, with increased protein expression of manganese superoxide dismutase (MnSOD), copper-zinc superoxide dismutase (CuZnSOD), catalase and heme oxygenase-1 (HO1), all of which are known targets of NF-κB and can be upregulated as a consequence of oxidative stress. Recuperated offspring also had a pro-inflammatory phenotype, as evidenced by increased tumor necrosis factor-α (TNFα) and interleukin-1β (IL1β) protein levels. Taken together, we demonstrate, for the first time to our knowledge, an accelerated aging phenotype in skeletal muscle in the context of developmental programming. These findings may pave the way for suitable interventions in at-risk populations.
Mitochondria are inherited maternally via the oocyte, which in the mouse contains 150-250 x 10(3) copies of mitochondrial DNA (mtDNA). The number of mtDNA copies/embryo is thought to be stable during cleavage, being progressively diluted/cell with each round of cell division, until replication begins at an undefined time post-implantation. Post-natally, tissues differ in copy number of mtDNA/cell, but when and how these differences arise is unclear. A ratiometric quantitative real-time polymerase chain reaction assay of the levels of a single mitochondrial gene against a single copy nuclear gene was used to estimate the average copy value of mtDNA/per cell from zygote to birth. A novel Bayesian statistical model was used to identify day 5.15-6.15 as the time at which replication recommences, consistent with the viability patterns of embryos carrying mitochondrial mutations. Mitochondrial DNA copy number/cell in a range of post-day 9.5 fetal and placental tissues showed tissue-specific temporal expression patterns. Western blotting was used to quantify post-day 9.5 tissue markers for oxidative stress and manganese superoxide dismutase, and revealed correlations with the changes in mtDNA copy number. These findings have potential implications for fetal programming, in-vitro embryo culture, and the mechanism underlying the mitochondrial bottleneck.
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