According to the WHO(1), ‘exclusive breast-feeding is defined as no other food or drink, not even water for 6 months of life’. Exclusive and prolonged breast-feeding has also been associated with protection against long-term chronic diseases such as obesity and diabetes(Reference Harder, Bergmann and Kallischnigg2). However, no more than 35 % of infants worldwide are exclusively breastfed during the first 4 months of life(3).
Directly or indirectly, malnutrition has been responsible for 60 % of the 10·9 million deaths among children annually(3). Barker et al. (Reference Barker, Martyn and Osmond4) has associated low birth weight with diseases related to the metabolic syndrome (obesity, diabetes and hypertension) in adulthood. Additionally, our group has showed that adverse situations during lactation, such as malnutrition and hormonal changes, could permanently affect the nutritional and hormonal status of the progeny(Reference de Oliveira Cravo, Teixeira and Passos5–Reference Fagundes, Moura and Passos12). This association has been denominated metabolic programming, which is defined as a biological phenomenon that determines the relationship between physical and chemical stimuli in critical periods of early life, such as gestation and lactation, with future functional status(Reference Rodrigues, de Moura and Passos13–Reference de Moura, Lisboa and Passos16).
During lactation, maternal energy restriction programmes for overweight without altering food intake(Reference Passos, Ramos and Moura17), and leptin resistance to its anorexigenic effect in adult offspring(Reference Passos, Vicente and Lisboa18). In lactating rats, undernutrition is associated with a failure in milk production(Reference Passos, Ramos and Moura17) caused by hypoprolactinaemia(Reference Lisboa, Passos and Dutra19). Also, the inhibition of the last 3 d of lactation through maternal treatment with bromocriptine (a prolactin (PRL) inhibitor) caused milk production inhibition, neonatal malnutrition evidenced by lower body weight of weaned pups(Reference Bonomo, Lisboa and Passos20) as well as programmed for obesity, hyperleptinaemia, central leptin resistance(Reference Bonomo, Lisboa and Pereira21), higher TAG and cholesterol in adulthood(Reference Moura, Bonomo and Nogueira-Neto22), and secondary hypothyroidism(Reference Bonomo, Lisboa and Passos23). However, in this model, it is difficult to separate the effects of maternal hypoprolactinaemia from those of decrease in milk ingestion. On the other hand, recently, it has been observed that maternal moderate energy restriction during lactation was associated with beneficial effects in their offspring, such as lower body-weight gain and fat accumulation under a high-fat diet(Reference Palou, Priego and Sanchez24).
Leptin, a hormone mainly produced by adipocytes, acts through leptin receptors (OB-R) to inhibit food intake and stimulate energy expenditure by specific hypothalamic signals, and only its long form OB-Rb is capable of active intracellular signalling(Reference Lee, Proenca and Montez25). Leptin binding to OB-Rb initiates tyrosine phosphorylation by janus tyrosine kinase 2 (JAK2). Phosphorylated JAK2 recruits signal transducer and activator of transcription 3 (STAT3) proteins, which are activated through phosphorylation. Activated STAT3 dimerises and translocates to the nucleus, where it stimulates gene transcription. The JAK2/STAT3 pathway stimulates the transcription of suppressor of cytokine signalling 3 (SOCS3), a leptin-inducible inhibitor of the leptin signalling pathway(Reference Vaisse, Halaas and Horvath26, Reference Velloso, Araujo and de Souza27). In obese individuals, hyperleptinaemia does not cause satiety and increases energy expenditure, as expected. This is explained by leptin resistance, caused by the down-regulation of OB-R(Reference Considine, Considine and Williams28, Reference Martin, Perez and He29), by an impairment of the intracellular signalling pathway(Reference Ahima and Flier30, Reference Jéquier31) or by a reduced blood–brain barrier transport(Reference Burguera, Couce and Curran32, Reference Banks33).
Then, in order to know whether precocious weaning can programme for endocrine and metabolic dysfunctions, the present study was designed to evaluate the immediate and late repercussion of lactation interruption without the use of pharmacological substances or maternal separation upon food intake, body length and composition, lipid profile, leptin, insulin and adiponectin levels, expression of proteins of the leptin signalling pathway in the hypothalamus and glucose homeostasis in rat offspring.
Experimental methods
The use of the animals according to our experimental design was approved by the Animal Care and Use Committee of the Biology Institute of the State University of Rio de Janeiro (CEA/017/2009), which based its analysis on the principles adopted and promulgated by Brazilian Law (no. 11.794/2008). Experiments were conducted to minimise the number of animals and the suffering caused by the procedures following the ethical doctrine of the three ‘R's’ – reduction, refinement and replacement(Reference Drummond34, Reference Marques, Morales and Petroianu35).
Wistar rats were kept in a temperature-controlled room (23/24°C) with artificial dark–light cycles (lights on 07.00 hours and lights off 19.00 hours), Virgin female rats, 3 months old, were caged with male rats at a proportion of 3:1. After mating, each female was placed in an individual cage with free access to water and food until delivery. We used only the dams whose litter size was ten pups in order to avoid the influence of litter size in the programming effect. At birth, to maximise lactation performance(Reference Passos, Ramos and Moura17), litters were adjusted to six male pups/dam.
Experimental model of early weaning
After birth, twelve lactating rats were randomly separated into two groups: early weaning (EW, n 6) – dams were lightly anaesthetised with thiopental (0·06 mg/ml per 100 g) and wrapped with a bandage to interrupt the lactation in the last 3 d of lactation; control (n 6) – dams whose pups had standard lactation period, i.e. weaning occurred at 21 d of lactation. Both groups received food directly into the cage, and the pups had easy access to a drinking-water bottle.
During lactation, body weight and the naso-anal length of pups were daily monitored. After weaning, EW and control offspring had free access to water and a standard diet, and their body weight, food intake and body length were recorded. Relative food intake was measured by dividing food intake by body weight. We used two offspring from each dam, which were killed at 21 or 180 d after 12 h of fasting. The killing occurred by quick decapitation, with no prior anaesthesia (because anaesthesia affects hormone and lipid metabolism), to collect blood, carcass, visceral fat mass (VFM) and hypothalamus.
Body composition evaluation
On the day of killing, VFM was excised (mesenteric, epididymal and retroperitoneal white adipose tissue) and immediately weighed for evaluation of central adiposity. Total body fat and protein contents were determined by carcass analysis(Reference Fagundes, Moura and Passos36, Reference Troina, Figueiredo and Moura37). Pups were eviscerated; the carcass was weighed, autoclaved for 1 h and homogenised on distilled water (1:1). The homogenates were stored at 4°C for analysis.
The homogenate (3 g) was used to determine fat content gravimetrically. Samples were hydrolysed on a shaking water-bath at 70°C for 2 h with 30 % KOH and ethanol. Total fatty acids and non-esterified cholesterol were removed with three successive washing with petroleum ether. After drying, overnight in vacuum, tubes were weighed, and data are expressed as g of fat/100 g of carcass.
Protein content was determined in 1 g of the homogenate. Tubes were centrifuged at 2000 g for 10 min. Total protein concentrations were determined by the Lowry method(Reference Lowry, Rosebrough and Farr38). Data are expressed as g of protein/100 g of carcass.
Western blot analysis
To obtain cell extracts, the hypothalamus was homogenised in ice-cold lysis buffer (50 mm-HEPES, 1 mm-MgCl2, 10 mm-EDTA and 1 % Triton X-100, pH 6·4) containing the following protease inhibitors: aprotinin (10 μg/μl), leupeptin (10 μg/μl), pepstatin (2 μg/μl) and 1 mm-phenylmethylsulphonyl fluoride (Sigma-Aldrich, St Louis, MO, USA). After centrifugation (7500 g for 5 min), the homogenates were stored at − 20°C. OB-R (a leptin receptor), JAK2, STAT3, phosphorylated STAT3 and SOCS3 contents were analysed by Western blot as described previously(Reference Fagundes, Moura and Passos12), using actin as the internal control.
Briefly, protein concentrations were determined by the bicinchoninic acid Protein Assay Kit (Thermo Scientific, Rockford, IL, USA). Samples (30 μg of total protein) were separated by 10 % SDS-PAGE according to the molecular weight of each protein, and transferred to nitrocellulose membranes (Hybond ECL; Amersham Pharmacia Biotech, Amersham, London, UK). Rainbow standard markers (Amersham Biosciences, Uppsala, Sweden) were run in parallel to estimate molecular weights. The membranes were blocked with 5 % non-fat milk in Tween-Tris-buffered saline (20 mm-Tris–HCl, pH 7·5, 500 mm-NaCl and 0·1 % Tween-20) for 1 h. Specific primary antibodies (Santa Cruz Biotechnology, Inc., Santa Cruz, CA, USA) used were anti-OB-R, anti-JAK2, anti-STAT3, anti-phosphorylated STAT3, anti-SOCS3 and anti-actin. The membranes were incubated with primary antibodies at 1:500 dilution in Tween-Tris-buffered saline buffer for 1 h, with an appropriate secondary antibody (1:10 000, peroxidase-conjugated IgG; Santa Cruz Biotechnology) for 1 h and then with streptavidin (1:10 000; Zymed, San Francisco, CA, USA) for 1 h. The targeted proteins were detected by enhanced chemiluminescence (Amersham Pharmacia Biotech, Piscataway, NJ, USA) and then exposed to X-ray film for 10 s to 30 min. The images were scanned, and the bands were quantified by densitometry using Image J 1.34 s software (Wayne Rasband National Institute of Health, MA, USA).
Hormonal determination by RIA
Blood samples were centrifuged (1500 g for 20 min at 4°C) to obtain serum, which was frozen ( − 20°C) until analysis. All measurements were performed in one assay. Leptin was measured with a specific RIA kit (Linco Research, Inc., St Charles, MO, USA), which measures both rat and mouse leptin with a range of detection from 0·5 to 50 ng/ml; intra-assay variation was 2·9 %. Insulin concentration was determined using an RIA kit (ICN Pharmaceuticals, Inc., Orangeburg, NY, USA), with an assay sensitivity of 0·1 ng/ml and an intra-assay variation of 4·1 %. Adiponectin was measured with a specific RIA kit (Linco Research), with an assay sensitivity of 0·5 ng/ml and an intra-assay variation of 7·1 %. PRL was determined by a specific RIA using reagents supplied by the National Institute of Health (MD, USA). Data are reported in ng from the reference preparation RP-3 with an assay sensitivity of 0·3 ng/ml and an intra-assay coefficient of 8 %.
Insulin sensitivity
Fasting blood glucose was determined from the tail vein of fasting rats using a glucosimeter (ACCU-CHEK® Advantage; Roche Diagnostics, Mannheim, Germany). To determine the insulin sensitivity of adult animals, we used the insulin resistance index (IRI): fasting glycaemia (mg/l) × fasting insulinaemia (μIU/ml).
Lipid profile analysis
Serum levels of total cholesterol, TAG and HDL-cholesterol were analysed using Biosystem commercial test kits with an automated A15 spectrophotometer (Biosystems S.A., Barcelona, Spain). LDL-cholesterol and VLDL-cholesterol were calculated according to the equation of Friedwald:
Statistical analysis
Results are reported as means with their standard errors. Statistical analyses and graphics were performed using the GraphPad Prism 4 (GraphPad Software, Inc., La Jolla, CA, USA) program. Leptin signalling was analysed by the non-parametric Mann–Whitney U test. Other experimental data were analysed by Student's unpaired t test, with the level of significance set at P < 0·05.
Results
At 21 d, EW pups presented lower body weight ( − 10 %, P < 0·05) and naso-anal length ( − 4 %, P < 0·05) compared with the group normally weaned, as shown in Fig. 1. At 180 d, EW offspring showed higher body weight (+8 %, P < 0·05), higher body length (+3 %, P < 0·05) as well as persistent hyperphagia, as shown in Fig. 2.
Fig. 1 (a) Body weight and (b) length during lactation of pups that were normally breast-fed for 21 d (control, □) and early weaned (▲). Values are means with of twelve rats/group, with standard errors represented by vertical bars. * Mean values were significantly different compared with those of the control group (P < 0·05).
Fig. 2 (a) Body weight, (b) length, (c) food intake and (d) food intake/weight after weaning until pups of 180 d old were normally breast-fed for 21 d (control, □) and early weaned (▲). Values are means of twelve rats/group with standard errors represented by vertical bars. * Mean values were significantly different compared with those of the control group (P < 0·05).
As depicted in Table 1, the 21-d-old EW pups had lower total body fat ( − 29·7 %, P < 0·05), lower VFM ( − 40 %, P < 0·05), but higher total protein content (+40 %, P < 0·05). In adulthood, these animals showed higher total fat mass (+36 %, P < 0·05), higher VFM (+84 %, P < 0·05) and lower body protein mass ( − 22·5 %, P < 0·05). Juvenile EW offspring presented hypoleptinaemia ( − 73 %, P < 0·05), but adult EW offspring showed hyperleptinaemia (+185 %, P < 0·05). At 180 d, the leptin:body fat ratio was lower in the EW group ( − 41 %, control: 0·123 (sem 0·016), EW: 0·072 (sem 0·011), P < 0·05).
Table 1 Body composition and leptinaemia of control (C) and early-weaned (EW) offspring at 21 and 180 d
(Mean values with their standard errors, n 12)
* Mean values were significantly different from those of the control group (P < 0·05).
Table 2 shows the lipid profile of EW offspring in adult life. Serum TAG were higher in the EW group (+96 %, P < 0·05) compared with the control group. However, total cholesterol, HDL-cholesterol, LDL-cholesterol or VLDL-cholesterol did not change significantly between the groups.
Table 2 Lipid profile of adult control (C) and early-weaned (EW) offspring
(Mean values with their standard errors, n 12)
* Mean value was significantly different from those of the control group (P < 0·05)
Protein levels of leptin signalling pathway components in the hypothalamus of adult EW rats are shown in Fig. 3. At 180 d, EW offspring presented lower JAK2 ( − 43 %; Fig. 3(b)), lower phosphorylated STAT3 ( − 32 % P < 0·05; Fig. 3(d)), lower phosphorylated STAT3:STAT3 ratio ( − 24 %, P < 0·05, data not shown) and higher SOCS3 (+97 %, P < 0·05; Fig. 3(e)) expressions compared to the controls, but no change in OB-R (Fig. 3(a)) and STAT3 (Fig. 3(c)) levels.
Fig. 3 Homogenates of the hypothalamus from the control (C) and early-weaned (EW) groups at 180 d were obtained, and (a) OB-R (n 6), (b) janus tyrosine kinase 2 (JAK2) (n 6), (c) signal transducer and activator of transcription 3 (STAT3) (n 6), (d) phosphorylated STAT (pSTAT) (n 6) and (e) suppressor of cytokine signalling 3 (SOCS3) (n 6) detections were performed by Western blotting. OB-R, JAK2, STAT3, pSTAT and SOCS3 contents were quantified by scanning densitometry of bands and are expressed as relative (%) to the control group. Actin content was used as the control loading. A representative experiment is shown from two independent experiments. Values are means with standard errors, represented by vertical bars. * Mean values were significantly different from those of the control group (P < 0·05).
Concerning the glucose homeostasis of 21-d-old EW pups (Fig. 4), we observed lower glycaemia and insulinaemia ( − 10 and − 20 %, P < 0·05; Fig. 4(a) and (b), respectively) with unchanged adiponectin levels. In addition, IRI was lower ( − 30 %, P < 0·05; Fig. 4(d)), suggesting that these animals were more sensitive to insulin. In adulthood, despite the normal serum insulin levels, EW rats displayed higher serum glucose (+15 %, P < 0·05; Fig. 5(a)), higher IRI (+29 %, P < 0·05; Fig. 5(d)) with lower serum adiponectin and PRL levels ( − 59 , and − 38 %, P < 0·05; Fig. 5(c); Fig. 5(e), respectively), which suggest an insulin resistance.
Fig. 4 (a) Serum glucose, (b) insulin, (c) adiponectin levels and (d) insulin resistance index (IRI) of 21-d-old offspring that were normally breast-fed for 21 d (control; C) and early weaned (EW). Values are means of twelve rats/group with standard errors represented by vertical bars. * Mean values were significantly different compared with those of the control group (P < 0·05).
Fig. 5 (a) Glycaemia, (b) insulinaemia, (c) adiponectinaemia, (d) insulin resistance index (IRI) and (e) prolactinaemia of 180-d-old offspring that were normally breast-fed for 21 d (control; C) and early weaned (EW). Values are means of twelve rats/group with standard errors represented by vertical bars. * Mean values were significantly different compared with those of the control group (P < 0·05).
Discussion
The importance of mother–infant relationships in development, including the role of nutrition and physical contact, has been characterised from endocrine and neurochemical perspectives(Reference Liu, Caldji and Sharma39, Reference Uriarte, Breigeiron and Benetti40). Milk is an important source of leptin that has been proposed to be required during a neonatal critical period for a normal postnatal development of hypothalamic pathways in the arcuate nucleus, which are involved in leptin signalling(Reference Bouret, Draper and Simerly41). In mice, EW has been shown to affect the neuroendocrine response to stress(Reference Kikusui, Nakamura and Kakuma42). As during lactation important cognitive and neurological development occurs, adverse environmental changes in this critical period of life can predispose the development of some diseases in adulthood(Reference Barker14, Reference Huang43). Nowadays, the time period dedicated to breast-feeding has decreased gradually, mainly because women are increasingly participating in the labour market.
The metabolic syndrome is defined as a set of at least three risk factors to CVD, such as central obesity, higher blood pressure, hypertriacylglycerolaemia, HDL-cholesterol reduction and insulin resistance(Reference Teixeira, Passos and Ramos44). The present study analysed the consequences of precocious weaning with no maternal separation or using pharmacological substances upon the programming of the body adiposity, glucose homeostasis, and hormone and lipid profiles in juvenile and adult rats, in order to investigate the possible changes in some parameters directly associated with the metabolic syndrome.
At 21 d, we showed that EW caused lower body weight, length, VFM, total body fat, hypoglycaemia and hypoinsulinaemia, all changes linked to malnutrition status. When the bandage was introduced to interrupt lactation, solid food was provided inside the cage, and the animals were already able to drink water in the bottle. This reinforces the importance of milk ingestion even at the last 3 d of lactation. In this moment, EW offspring seems to have normal insulin sensitivity since the IRI was lower. However, at 180 d, those animals displayed overweight, higher total and visceral adiposity, higher serum levels of TAG and glucose as well as a higher IRI, which are components of the metabolic syndrome. Serum insulin levels were inappropriately unchanged, also suggesting a pancreatic β-cell failure. Some studies show that malnutrition caused by a large litter (eighteen pups) during all the suckling period reduces body-weight gain and adiposity(Reference Velkoska, Cole and Dean45), and increases circulating adiponectin in adulthood(Reference Prior, Velkoska and Watts46). However, in the present study, EW programmed for overweight and insulin resistance; it is possible that these contradictory findings were due to the intensity of undernutrition. In those studies, authors used an experimental model of moderate undernutrition, because despite increasing the competition among the pups, they still drank maternal milk, the opposite of our experimental model that is characterised by a severe malnutrition, because the pups did not drink maternal milk in the last 3 d of lactation.
At 21 d, EW offspring showed lower serum leptin concentration, and this could imprint those animals for central leptin resistance and obesity. Previously, we showed that both maternal energy malnutrition during lactation and maternal hypoprolactinaemia caused by bromocriptine administration at the end of lactation (an EW experimental model) cause malnutrition of the pups at weaning(Reference de Moura, Lisboa and Passos16, Reference Lisboa, Passos and Dutra19), and programme for higher body-weight gain and central leptin resistance(Reference Passos, Ramos and Moura17, Reference Bonomo, Lisboa and Passos20). In both models, there seems to be a higher transfer of leptin from the mothers to the pups through the milk(Reference Lisboa, Passos and Dutra19, Reference Dorner and Plagemann47). On the other hand, oral leptin treatment of suckling pups, equivalent to five times the amount of leptin normally ingested from maternal milk, was related to the prevention of later overweight/obesity(Reference Picó, Oliver and Sanchez48). In addition, Attig et al. (Reference Attig, Solomon and Ferezou49), using an antagonist to a leptin receptor during lactation, showed that the offspring is also programmed for obesity and leptin resistance. Thus, it seems that the correct leptin serum concentration and also the nutritional status during lactation are necessary for a normal leptin action and adipogenesis.
As early-weaned rats presented hyperphagia, higher adiposity and serum leptin levels in adult life, we decided to analyse the leptin signalling pathway in the hypothalamus. In fact, despite normal OB-R and STAT3 contents being detected, those animals exhibited lower JAK2, lower pSTAT and higher SOCS3 levels, which indicate a development of hypothalamic leptin resistance. Additionally, postnatal overfeeding caused by litter size reduction leads to the same mechanism in adult animals (lower JAK2 and pSTAT and higher SOCS3 expression), also suggesting central leptin resistance(Reference Rodrigues, de Moura and Passos50). Thus, an adequate milk supply is an important factor responsible for a normal leptin action at the hypothalamic level.
Recently, it has been demonstrated that serum leptin adjusted for body fat in humans can be another criterion to evaluate the metabolic syndrome(Reference Paz-Filho, Volaco and Suplicy51). It seems that leptin production by adipose tissue is decreased in obese subjects, suggesting a relative leptin deficiency associated with advanced stages of the metabolic syndrome. In the present study, this relative deficiency was observed in adult EW rats since they showed a lower leptin:body fat ratio, corroborating the hypothesis that adipose tissue in obesity is dysfunctional.
Some studies have shown that higher body visceral fat is a risk factor to insulin resistance and other metabolic disorders in humans(Reference Abate, Garg and Peshock52, Reference Seidell and Bouchard53) and rodents(Reference Barzilai, She and Liu54, Reference Gabriely, Ma and Yang55). On the other hand, adiponectin levels have been associated with higher insulin sensitivity(Reference Berg, Combs and Du56, Reference Yamauchi, Kamon and Waki57), and its level is inverse to total body adiposity(Reference Arita, Kihara and Ouchi58). So, it is possible that hyperglycaemia and hypoadiponectinaemia found in 180-d-old EW offspring, even with a normal serum insulin, may be due to its higher body fat and could be the beginning of insulin resistance. Changes in glucose homeostasis in adult life, such as lower insulin secretion(Reference Desai, Byrne and Meeran59, Reference Moura, Caldeira Filho and de Freitas Mathias60), changes in insulin sensitivity(Reference Fagundes, Moura and Passos12, Reference Benyshek, Johnston and Martin61), higher glucogenolysis(Reference Burns, Desai and Cohen62), lower β-cell quantity and pancreatic content of insulin(Reference Bertin, Gangnerau and Bailbe63) are associated with protein malnutrition in critical periods of life. Moreover, PRL modulates the proliferation of pancreatic β-cells and the consequent lowering of glycaemia(Reference Ose, Miyata and Yoshioka64). The fact that programmed EW rats had lower serum PRL could explain why they have an inappropriate response of insulin to hyperglycaemia have shown were adults, perhaps because they have an impairment on the development of pancreatic β-cells, Recently, we have shown that maternal hypoprolactinaemia for the last 3 d of lactation programmes for insulin resistance and lower serum PRL in their adult offspring(Reference Moura, Bonomo and Nogueira-Neto22).
Concerning the lipid profile, besides no important change in total cholesterol, HDL-cholesterol, LDL-cholesterol or VLDL cholesterol, the hypertriacylglycerolaemia of adult EW offspring may indicate higher atherogenesis risk(Reference Després65), which suggests a higher risk of developing CVD. In fact, there is an association of low birth weight with dyslipidaemia and hypertension in adulthood(Reference Fall, Osmond and Barker66). In the present model, persistent hyperphagia could contribute to the high TAG levels. Previously, we showed that neonatal hyperleptinaemia programmed for higher food intake and hypertriacylglycerols(Reference Toste, de Moura and Lisboa67). Despite some similarities (higher total and visceral fat, hypertriacylglycerolaemia), EW differs from the PRL inhibition model in relation to cholesterol and HDL-cholesterol levels. It seems that PRL suppression is more deleterious for the lipid profile than the EW.
In summary, the amount of our data provides evidence that EW leads to the late development of the metabolic syndrome as well as central leptin resistance. Our experimental model reinforces the idea that postnatal malnutrition caused by shortening lactation is important for the metabolic programming of future diseases, even when no pharmacological treatment is used.
Acknowledgements
The present study was supported by the National Council for Scientific and Technological Development (Conselho Nacional de Desenvolvimento Científico e Tecnológico – CNPq), the Carlos Chagas Filho Research Foundation of the State of Rio de Janeiro (Fundação Carlos Chagas Filho de Amparo à Pesquisa do Estado do Rio de Janeiro – FAPERJ) and Coordination for the Enhancement of Higher Education Personnel (Coordenação de Aperfeiçoamento de Pessoal de Nível Superior – CAPES). N. d. S. L. was recipient of a FAPERJ fellowship, and E. d. O. was recipient of a CAPES fellowship. The authors are grateful to Antonio CM de Sá, Vania Pinto and Ana Maria B Coutinho from Laboratory of Lipids (LabLip, UERJ) for lipid profile determination. We also thank Mr Carlos Roberto, Miss Monica Moura and Mr Luciano Santos for their technical assistance. The authors declare no conflict of interest. P. C. L., E. G. d. M. and M. C. F. P. designed the study and wrote the protocol and manuscript. N. d. S. L., J. F. N. N. and E. d. O. were responsible for animal programming, biochemical and molecular procedures. All authors contributed to and approved the final manuscript.
