European Journal of Experimental Biology Open Access

Keywords

high fat diet, pregnancy, offspring, unsaturated fat diet, leptin sensitivity

Introduction

The maternal obesity have a greater influence to increased the risk of disease in their offspring childhood [1-4] in addition to their pregnancy complication [5] and higher leptin level [6] it documented a problem in human population with transgeneration effect [7]. The nutritional condition during pregnancy influence in utero and fetal growth and disease in adulthood [8] few studies are conducted on the long term effect of excess nutrition during pregnancy or lactation on obesity development in offspring [9]. The epidemic of obesity and childhood disease in development countries related partly to the association between prenatal nutrition and postnatal food consumption [10] some studies investigate the role of maternal rich diet on fetal development [11]. Obesity during pregnancy playing a pathogenetic role in the development of obese phenotype in offspring [12] the children who are born from obese mothers are likely to be obese more than the children from lean mothers [13] . The gestinational diabetes effected on fetal development and increased the rate of birth weight and enhanced diabetogenic tendency in offspring [14]. Several studies reported the maternal over nutrition lead to cause cardiovascular dysfunction in offspring by increased the tendency of obesity and impaired insulin tolerance [15-17]. The aim of the study is determined the effect of maternal diet enriched with saturated fat on development obesity , metabolic syndrome and puberty in offspring and the role of unsaturated fat to modulate these effects .

Materials and Methods

Animals: Female Wister albino rats (6 weeks aged and 97± 10 g weight) were acclimatizing on low fat diet for one week before introducing to the experimental diets, the animals either feeding on low fat diet (control diet LF: 10% energy from tallow ) n=12 or on a high fat diet (HF 45% energy from tallow) n=36 for 12 weeks ( table 1) and assigned as experiment one of the study. All animals were kept in constant room temperature (25-30 c) and 12:12 h light: dark cycle with free access to food and water. in the experiment 2 of the study a group of rats n=6 from the control were continued on low fat diet for additional 8 weeks , while the rats from high fat diet group were divided into the following subgroups ( n= 6). The first subgroup was continued to feed on HF diet (45%) for additional 8 weeks (HF-HF). The second subgroup was received moderate fat diet (22.5 % fat) in which tallow was replaced by olive oil (HF-O.d) or peanut (HF-P.d) for additional 8 weeks.. The third subgroup was received a low fat diet (10 % tallow) for additional 8 weeks (HF-LF). The forth subgroup was received a moderate fat diet (M.d: 22.5 % tallow) for additional 8 weeks (HF-M.d).

Diet: Diet induced obesity in rodents (HFd 45 % fat ) and it΄s control ( LFd 10 % fat ) was formulated according to the research diet [18]. Moderate fat diet M.d (HF-M.d , HF-O.d , HF-P.d) was modifying according to the high fat diet of this study.The composition of the experimental diet shows in table 1.

Study the reproductive performance: To study the reproductive function, virgin female rats from each dietary groups from the experiment 1 and 2 of the study were used : LFd , Hfd , LF-LF , HF-HF , HF-P.d, HF-O.d, HF-LF and HF-M.d ( n=6 ) .The virgin female rats were time mated by monitored ousters cycle in virginal smear before introducing to the male (one male for each female , aged 17 -18 week ) .Day one of pregnancy was determined by the present of sperms after vaginal lavage . Pregnant rats were housed in group (n=3 each cage) in standard cage, containing sawdust and maintained on their assigned diet with free access to water. All animals were kept in constant room temperature (25-30 c) and 12:12 h light: dark cycle with free access to food and water. During the gestation period, daily food intake and body weight were recorded for each groups. On the day 21, 22 of pregnancy, dams were monitored and observed during delivery. After delivery, the pup’s weight was recorded. For the next three days, pups mortality was recorded .Dams were continued on their assigned diet in each dietary group during the lactation period until weaning. After weaning, the female and male offspring of each dietary experiment were weighed and then fed on control diet (10 % from fat). The vaginal opining was examined daily, and the vaginal smears were collected and observed for the presence of cornified epithelial cells (estrus). Body weight recorded and the female offspring were anesthetized and sacrificed. Blood samples were collected, Plasma stored at -78 c.

Hormonal measurements: Plasma rat leptin and insulin was measured using rat Elisa kit from CRYSTAL CHEM INC (for leptin cat no. 90040 USA, for insulin cat no. 90010 USA).

Biochemical parameters: Plasma glucose , total cholesterol (T-ch), triglycerides (TG) , high density lipoprotein (HDL), total protein , albumin concentrations were measured by enzymatic method using diagnostic Kit from Randox (UK) and Biolabo companies (France) .

Low density lipoprotein (LDL) was calculated according to the formula Friedewal [19]: LDL cholesterol = T.ch - HDL - (TG/5) , very low density lipoprotein (VLDL) was measured according to the formula Tietz [20]: VLDL = TG/5 . Phospholipids were measured according to the formula Tietz [20]: Phospholipids = 68 + (T-ch × 0.89).

Statistical analysis: Data were analyzed by one- way and two- way ANOVA using a general liner models procedure using SPSS version 15.0 statistic program. Comparisons between the data were made using least significant differences (LSD). Differences were considered to be significant at p<0.05.

Results

Pups birth and weaning weight: pups of high fat dams give higher birth weight with significantly (p<0.05) (6.600 gm) than obtained in control group, (table 2). No mortality was observed in pups after 3 days of lactation in both groups. High birth weight were recorded in the HF-P.d and HF-M.d followed by HF-O.d and HF-Lf groups. The continuous feeding on high fat diet reduced pups birth weight (5.10 gm). During lactation period the pups of HF-HF and HF-M.d groups had mortality rate 1.6 and 1.3 while the groups HF-O.d and HF-LF had rate 0.33. After weaning the female and male offspring showed higher weaning weight in HF group with higher puberty weight in females that reflected the short time for puppetry compared to control group (figures 1,2), Followed by higher weight in HFP. d group (42.33gm ±1.37 for female and 43.67 gm±3.721 for male) . Normal weaning weight in HF-O.d , HF-Ld and HF-M.d groups . The female offspring of HF-HF group had the less weaning weight (29.67gm ±1.012 )with early puberty time whereas the male recorded weight 30.33 gm ± 1.10 as the control with no significant as shown in figure 3 . The results show delayed age of puberty in HF-O.d group (47.67 ±4.4 days). Puberty females’ weight were normal in all dietary groups except in HF-HF group which showed the lower puberty weight (118 gm ± 2.64) followed by HF-LF group with 122.67 gm ± 2.51.

Offspring plasma leptin and insulin: Female offspring of high fat diet group (HF,HF-HF) in the onset of puberty , had significantly (p<0.05) higher fasting plasma leptin levels (2.31 ng/ml , 2.415 ng/mL) and insulin levels (0.540 ng/ml , 0.87 ng/ mL, respectively) compared to the control group( table 3) . Consequent by higher insulin concentration in female offspring of HF-M.d group (0.98 ng/mL) and plasma leptin was higher (2.155 ng/ml ). In HF-P.d group, the concentration of plasma leptin was 1.621 ng/ml and insulin 0.59 ng/ml with no significant from the control groups . In HF-O.d and HF-LF groups, plasma leptin levels in females decreased slightly (1.261 ng/ml ,1.520 ng/ml) than the control group (LF-LF) (1.600 ng/ml) , whereas their plasma insulin did not differ from the control group .

Female Offspring biochemical parameters: Fasting plasma glucose ,total cholesterol (TG) and triglycerides (TG) were significantly (p<0.05) increased in females offspring of HF diet groups (HF, HF-HF) (18.30 , 1.667 , 5.320 mmol/L ,and 21.40 , 5.933 , 1.774 mmol/L respectively) compared to control group (LF-LF) (12.5, 2.80,0.661 mmol/L respectively) (table 4) .In HF- P.d group, female plasma glucose was 12.50 mmol/L with no significant difference from the control group, consequent by HFO. d group with significantly(p<0.05) (11.63 mmol/L) . In HF-LF and HF-M.d group, high levels of plasma glucose were recorded in females (14.23, 14.83 mmol /L respectively). However, the plasma T-ch and TG were high in all groups with significant differences (p<0.05) from the control.

Discussion

Our results demonstrate that the higher fetal weight of high fat fed dams (fed for 15 weeks) may be caused by changes in nutritional transport though placenta ,either up –regulation of specific nutrition’s like glucose and amino acids indicating from higher protein gene expression of glucose trans port Glut 4 and sodium coupled neutral amino acid transport SANAT 2 [21] or either to the ability of placenta to take up chylomicron remnants core lipids by increasing mRNA expression of fatty acid oxidation protein PPAR rather than fatty acid transport [22] . The reduction in fetal growth in dams fed high fat diet for 23 weeks (HF-HF group) may explained by decreased sensitivity of body tissue to insulin action as a resulted from highest insulin and glucose concentration that may have an effect on placental nutrition transport, that could have an influence on the numerous events in fetus growing process or on reproductive hormones including prostaglandin synthesis [23]. Diets supplemented with USFA (MUFA or PUFA) prior and though pregnancy resulted in normal fetus weight, especially with peanut supplementation. The possible explanation either to the changes in maternal nutritional status during ovum maturation and in early embryonic development which had greater effect than the last trimesters of pregnancy due to placental barrier development [24] or the fatty acid composition of the diet may influencing on the umbilical plasma phospholipids composition that may cause a competition between fatty acid types which became more effective in altering the neonatal essential fatty acids status [25] in addition to the beneficial role of oil/fat antioxidants to increase fertility and reproductive performance [26 ,27]. Another factor may be attributed to the activation role of USFA diet on reproductive process, via providing a precursor for prostaglandin synthesis and can modulate the expression pattern of many enzymes involved in both prostaglandin and steroid metabolism, also the proportion of different PUFA in tissue of the reproductive tract reflects dietary consumption [28]. Our finding on peanut effect was similar to the findings of Tchokonte & Longo [29], they found that intraperitoneal injection of peanut oil in female rats increased endometrial receptivity; pregnancy rate and fertility by triggering decidulisation and deliveries than progesterone stimulate rats.

As shown in HF-HF and HF-M.d groups At birth, Pups of high fat fed dams had higher body weight than their low fat counterparts, the possible explanation that increase in milk preference from HFd dams, Therefore, the increased food intake was due to increased milk production in high fat fed dams [30], or due to permanent increase in galanin expression that induced a preference for fat ingestion in neonatal overfed dams [31]. The increased body weight in HF-HF and HF-M.d groups caused higher levels of plasma cholesterol as the fat deposition that have positive association with blood lipid [32] and higher plasma glucose may be related to impair insulin sensitivity, also diabetes association obesity increased glycosylated haemoglobin HbA1C [33]. Some of the following studies conducted on the effect of extreme obesity to reduce offspring birth weight and body size [7] or to increase pups mortality [34] in dams fed a high fat diet, and other researchers reported that obesity during pregnancy have long term effect on offspring development [17] , and the metabolism of offspring was effected and altered by overweight and gestational diabetes which have greater propensity to develop diabetes and / or obesity [35]. The peanut group (HF-P.d ), olive oil (HF-O.d) low and moderate saturated diet groups ,their offspring weight as the control , this data demonstrate that different fatly acids had different effect on body weight , composition and metabolism [36]. The alteration in activity of hypothalamus gonadotropin releasing hormone (HGRH) neurons and consequent increase in the release of gonadotropin from pituitary gland cause the release of gonadal hormones from gonads and initiate puberty [37]. Our results indicate that fetal exposure to HFd and HF-M.d diet influence the timing of puberty in rat offspring. Body fat mass may contribute ( HF group ) [38], and the fat rich diet also effect [39] , or it occur independent on change in total body weight as shown in HF-O.d group and HF-HF group [40] .

High fat diet groups (HF, HF-HF) and HF-M.d female offspring had higher leptin concentration ,this may related to the quality of dietary fat during the suckling period influence the leptin levels and the responsiveness of the hypothalami-pituitary –adrenal axis in rat pups [41] or may the high fat diet through gestation cause hypothalamic leptin resistance in offspring ,increase leptin levels and developing obesity [42]. Offspring normal plasma leptin in HF-P.d and HF-O.d may caused by the effect of maternal fatty acid composition on leptin level in dams and in their pups [43] or because sucking pups on unsaturated fatty acids may lower leptin as their mothers. The hyperleptinemia and hyperinsulinemia in offspring may cause by reduced sensitivity to circulating leptin and / or insulin in critical receptor region in hypothalamus [44] by increasing mRNA and protein levels of leptin receptor and insulin in HF fetus hypothalami and increased mRNA levels of neuropeptide y and agouitrelated polypeptide indicating orexigenic in offspring [12] these effects may be modulated by activity of unsaturated fatty acid on leptin and insulin receptors and increased their sensitivity and caused their action by decreasing insulin concentrations to normal levels .

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