Multigenerational exposure to uranium changes morphometric parameters and global DNA methylation in rat sperm.

There is increasing evidence that environmental exposures early in fetal development influence phenotype and give rise to disease risk in the next generations. We previously found that lifelong exposure to uranium, an environmental contaminant, induced subtle testicular and hormonal defects; however, its impact on the reproductive system of multiple subsequent generations was unexplored. Herein, rats were exposed to a supra-environmental and non-nephrotoxic concentration of natural uranium (U, 40 mg·L-1 of drinking water) from postnatal life to adulthood (F0), during fetal life (F1), and only as the germ cells from the F1 generation (F2). General parameters (reproductive indices, epididymal weight) and sperm morphology were assessed in the three generations. In order to identify the epigenetic effects of U, we analyzed also the global DNA methylation profile and described for the first time the mRNA expression levels of markers involved in the (de)methylation system in rat epididymal spermatozoa. Our results showed that the F1 generation had a reduced pregnancy rate. Despite the sperm number being unmodified, sperm morphology was affected in the F0, F1 and F2 generations. Morphometric analysis for ten parameters was detailed for each generation. No common parameter was detected between the three generations, but the head and the middle-piece were always modified in the abnormal sperms. In the F1 U-exposed generation, the total number of abnormal sperm was significantly higher than in the F0 and F2 generations, suggesting that fetal exposure to uranium was more deleterious. This effect could be associated with the pregnancy rate to produce the F2 generation. Interestingly, global DNA methylation analysis showed also hypomethylation in the sperm DNA of the last F2 generation. In conclusion, our study demonstrates that uranium can induce morphological sperm defects and changes in the DNA methylation level after multigenerational exposure. The epigenetic transgenerational inheritance of U-induced reproductive defects should be assessed in further experiments.

Low dose of uranium induces multigenerational epigenetic effects in rat kidney.

PURPOSE: A protocol of chronic exposure to low dose of uranium was established in order to distinguish the sexual differences and the developmental process that are critical windows for epigenetic effects over generations. METHODS: Both male and female rats were contaminated through their drinking water with a non-toxic solution of uranyl nitrate for 9 months. The exposed generation (F0) and the following two generations (F1 and F2) were examined. Clinical monitoring, global DNA methylation profile and DNA methyltransferases (DNMTs) gene expression were analyzed in kidneys. RESULTS: While the body weight of F1 males increased, a small decrease in kidney and body weight was observed in F2 males. In addition, global DNA hypermethylation profile in kidney cells was observed in F1 and F2 males. qPCR results reveal a significant increase of methyltransferase genes expression (DNMT1 and DNMT3a) for F2 females. CONCLUSIONS: In the field of public health policy and to raise attention to generational effects for the risk assessment of the environmental exposures, low doses of uranium do not imply clinical effects on adult exposed rats. However, our results confirm the importance of the developmental windows' sensitivity in addition to the sexual dimorphisms of the offspring.

Inulin Supplementation Lowered the Metabolic Defects of Prolonged Exposure to Chlorpyrifos from Gestation to Young Adult Stage in Offspring Rats.

Increasing evidence indicates that chlorpyrifos (CPF), an organophosphorus insecticide, is involved in metabolic disorders. We assess the hypothesis whether supplementation with prebiotics from gestation to adulthood, through a modulation of microbiota composition and fermentative activity, alleviates CPF induced metabolic disorders of 60 days old offspring. 5 groups of Wistar rats, from gestation until weaning, received two doses of CPF pesticide: 1 mg/kg/day (CPF1) or 3.5 mg/kg/day (CPF3.5) with free access to inulin (10g/L in drinking water). Then male pups received the same treatment as dams. Metabolic profile, leptin sensitivity, insulin receptor (IR) expression in liver, gut microbiota composition and short chain fatty acid composition (SCFAs) in the colon, were analyzed at postnatal day 60 in the offspring (PND 60). CPF3.5 increased offspring's birth body weight (BW) but decreased BW at PND60. Inulin supplementation restored the BW at PND 60 to control levels. Hyperinsulinemia and decrease in insulin receptor ß in liver were seen in CPF1 exposed rats. In contrast, hyperglycemia and decrease in insulin level were found in CPF3.5 rats. Inulin restored the levels of some metabolic parameters in CPF groups to ranges comparable with the controls. The total bacterial population, short chain fatty acid (SCFA) production and butyrate levels were enhanced in CPF groups receiving inulin. Our data indicate that developmental exposure to CPF interferes with metabolism with dose related effects evident at adulthood. By modulating microbiota population and fermentative activity, inulin corrected adult metabolic disorders of rats exposed to CPF during development. Prebiotics supply may be thus considered as a novel nutritional strategy to counteract insulin resistance and diabetes induced by a continuous pesticide exposure.

Antioxidant properties of formula derived Maillard reaction products in colons of intrauterine growth restricted pigs.

OBJECTIVE: the present study has been conducted to evaluate the impact of the consumption of high MRP formula on changes in the microbiota and the oxidative status, during development, in the colons of intrauterine growth restricted (IUGR) juvenile pigs. METHODS: over a 3-week period, fifteen-day old piglets received formula with two different heat treatments. A formula heated at high temperature (HHF, n = 8) and another one heated at a low temperature (LHF, n = 8). After weaning, animals were fed, ad libitum, a solid diet until postnatal day 54 (PND54). The diversity and composition of the major microbiota were analyzed by CE SSCP and qPCR at postnatal day 36 (PND36) and PND54. Protein oxidation levels, glutathione peroxidase (GPX) activity, catalase (CAT), manganese dependent superoxide dismutase (Mn SOD), NFκB and inducible nitric oxide synthase (iNOS) gene expression were measured in the colon at the juvenile stage (PND54). RESULTS: HHF resulted in a significant decrease in bacterial diversity in the colon at PND36. An increase in the total count of Bifidobacteria, Lactobacillus, Bacteroidetes and Enterobacteria, without major changes in total microbiota was evidenced by qPCR, suggesting qualitative changes in the bacterial population of the HHF group. The imbalance of microbiota observed at PND36 was significantly modified at PND54, when animals received a solid diet. Colon GPX activity (p < 0.05) and gene expression of CAT and iNOS were significantly (p < 0.05) upregulated in the HHF group. No differences in the total protein oxidation and carbonyl score were found in the HHF group. Colon redox enzyme gene expression and pro-inflammatory factor NFκB negatively correlated (p < 0.05) with the bacterial population, suggesting the involvement of certain phyla in controlling the oxidative status of the IUGR piglets, fed on the high AGE formula. CONCLUSION: during development, consuming a high load MRP formula was associated with a major modification in the diversity and composition of the microbiota. The onset of an IUGR adaptive oxidant defense mechanism was found to counteract the oxidative stress induced by the presence of MRPs in formula.

Formula-derived advanced glycation end products are involved in the development of long-term inflammation and oxidative stress in kidney of IUGR piglets.

SCOPE: Formula-derived dietary advanced glycation end products (AGEs) may promote programming of inflammation and oxidative stress in the kidney of intrauterine growth retardation (IUGR) piglets. METHODS AND RESULTS: IUGR piglets received either a low temperature heated formula (n = 8) or a high temperature heated formula (HHF: n = 8) or suckled naturally for 3 wk postnatally. Then they were fed with normal ad libitum regular diet. N(ε)-carboxymethyllysine (CML) was measured in plasma, feces, and formula by HPLC/MS-MS. CML was detected by immunofluorescence in kidney cells. Target renin-angiotensin-apoptotic, pro-inflammatory genes-p62 NF-κB, and soluble receptor of AGE (sRAGE) levels were quantified. Compared with that in controls, free CML and plasma urea increased significantly in the HHF-fed group at PND36 (p < 0.05). CML was detected in the nuclei of renal tubular cells of formula-fed piglets but not in suckled ones. This presence of CML was associated with the activation of the soluble receptor of AGE. AT1, AT2, caspase 3, caspase 8, NF-κB, p62 NF-κB, and total protein oxidation in kidney were higher in HHF-fed group as compared to LHF-fed group (p < 0.05). CONCLUSION: Food processes aimed at reducing the concentration of AGEs in infant formula are urgently needed and may be therapeutically relevant for premature and/or IUGR babies.

Acute exposure to a precursor of advanced glycation end products induces a dual effect on the rat pancreatic islet function.

Aim. Chronic diseases are the leading cause of death worldwide. Advanced glycation end products, known as AGEs, are a major risk factor for diabetes onset and maintenance. Methylglyoxal (MG), a highly reactive metabolite of glucose, is a precursor for the generation of endogenous AGEs. Methods. In this current study we incubated in vitro pancreatic islets from adult rats in absence or presence of MG (10 µmol/l) with different concentrations of glucose and different metabolic components (acetylcholine, epinephrine, potassium, forskolin, and leucine). Results. Different effects of MG on insulin secretion were evidenced. In basal glucose stimulation (5.6 mM), MG induced a significant (P < 0.05) increase of insulin secretion. By contrast, in higher glucose concentrations (8.3 mM and 16.7 mM), MG significantly inhibited insulin secretion (P < 0.05). In the presence of potassium, forskolin, and epinephrine, MG enhanced insulin secretion (P < 0.05), while when it was incubated with acetylcholine and leucine, MG resulted in a decrease of insulin secretion (P < 0.05). Conclusion. We suggest that MG modulates the secretion activity of beta-cell depending on its level of stimulation by other metabolic factors. These results provide insights on a dual acute effect of MG on the pancreatic cells.

Low-protein diet in adult male rats has long-term effects on metabolism.

Nutritional insults during developmental plasticity have been linked with metabolic diseases such as diabetes in adulthood. We aimed to investigate whether a low-protein (LP) diet at the beginning of adulthood is able to program metabolic disruptions in rats. While control rats ate a normal-protein (23%; NP group) diet, treated rats were fed a LP (4%; LP group) diet from 60 to 90 days of age, after which an NP diet was supplied until they were 150 days old. Plasma levels of glucose and insulin, autonomous nervous system (ANS), and pancreatic islet function were then evaluated. Compared with the NP group, LP rats exhibited unchanged body weight and reduced food intake throughout the period of protein restriction; however, after the switch to the NP diet, hyperphagia of 10% (P<0.05), and catch-up growth of 113% (P<0.0001) were found. The LP rats showed hyperglycemia, insulin resistance, and higher fat accretion than the NP rats. While the sympathetic tonus from LP rats reduced by 28%, the vagus tonus increased by 21% (P<0.05). Compared with the islets from NP rats, the glucose insulinotropic effect as well as cholinergic and adrenergic actions was unaltered in the islets from LP rats. Protein restriction at the beginning of adulthood induced unbalanced ANS activity and fat tissue accretion later in life, even without functional disturbances in the pancreatic islets.

Maternal diet, bioactive molecules, and exercising as reprogramming tools of metabolic programming.

Nutrition and lifestyle, particularly over-nutrition and lack of exercise, promote the progression and pathogenesis of obesity and metabolic diseases. Nutrition is likely the most important environmental factor that modulates the expression of genes involved in metabolic pathways and a variety of phenotypes associated with obesity and diabetes. During pregnancy, diet is a major factor that influences the organ developmental plasticity of the foetus. Experimental evidence shows that nutritional factors, including energy, fatty acids, protein, micronutrients, and folate, affect various aspects of metabolic programming. Different epigenetic mechanisms that are elicited by bioactive factors in early critical developmental ages affect the susceptibility to several diseases in adulthood. The beneficial effects promoted by exercise training are well recognised, and physical exercise may be considered one of the more prominent non-pharmacological tools that can be used to attenuate metabolic programming and to consequently ameliorate the illness provoked by metabolic diseases and reduce the prevalence of obesity, type 2 diabetes, and cardiovascular diseases. Literature on the different outcomes of unbalanced diets and the beneficial effects of some bioactive molecules during gestation and lactation on the metabolic health of offspring, as well as the potential mechanisms underlying these effects, was reviewed. The importance of the combined effects of functional nutrition and exercise as reprogramming tools of metabolic programming is discussed in depth. Finally, this review provides recommendations to healthcare providers that may aid in the control of early programming in an attempt to optimise the health of the mother and child.