Background Shift work was recently described as a factor that increases the risk of Type 2 diabetes mellitus. In addition, rats born to mothers subjected to a phase shift throughout pregnancy are glucose intolerant. However, the mechanism by which a phase shift transmits metabolic information to the offspring has not been determined. Among several endocrine secretions, phase shifts in the light/dark cycle were described as altering the circadian profile of melatonin production by the pineal gland. The present study addresses the importance of maternal melatonin for the metabolic programming of the offspring. Methodology/Principal Findings Female Wistar rats were submitted to SHAM surgery or pinealectomy (PINX). The PINX rats were divided into two groups and received either melatonin (PM) or vehicle. The SHAM, the PINX vehicle and the PM females were housed with male Wistar rats. Rats were allowed to mate and after weaning, the male and female offspring were subjected to a glucose tolerance test (GTT), a pyruvate tolerance test (PTT) and an insulin tolerance test (ITT). Pancreatic islets were isolated for insulin secretion, and insulin signaling was assessed in the liver and in the skeletal muscle by western blots. We found that male and female rats born to PINX mothers display glucose intolerance at the end of the light phase of the light/dark cycle, but not at the beginning. We further demonstrate that impaired glucose-stimulated insulin secretion and hepatic insulin resistance are mechanisms that may contribute to glucose intolerance in the offspring of PINX mothers. The metabolic programming described here occurs due to an absence of maternal melatonin because the offspring born to PINX mothers treated with melatonin were not glucose intolerant. Conclusions/Significance The present results support the novel concept that maternal melatonin is responsible for the programming of the daily pattern of energy metabolism in their offspring.
References
[1]
PLoS Medicine Editors (2011) Poor diet in shift workers: a new occupational health hazard? PLoS Med 8: e1001152.
Manenschijn L, van Kruysbergen RG, de Jong FH, Koper JW, van Rossum EF (2011) Shift work at young age is associated with elevated long-term cortisol levels and body mass index. J Clin Endocrinol Metab 96: E1862–E1865.
[4]
Kivim?ki M, Batty GD, Hublin C (2011) Shift work as a risk factor for future type 2 diabetes: evidence, mechanisms, implications, and future research directions. PLoS Med 8: e1001138.
[5]
Pan A, Schernhammer ES, Sun Q, Hu FB (2011) Rotating night shift work and risk of type 2 diabetes: two prospective cohort studies in women. PLoS Med 8: e1001141.
[6]
Varcoe TJ, Wight N, Voultsios A, Salkeld MD, Kennaway DJ (2011) Chronic phase shifts of the photoperiod throughout pregnancy programs glucose intolerance and insulin resistance in the rat. PLoS One 6: e18504.
[7]
Dijk D-J, Duffy JF, Silva EJ, Shanahan TL, Boivin DB, et al. (2012) Amplitude Reduction and Phase Shifts of Melatonin, Cortisol and Other Circadian Rhythms after a Gradual Advance of Sleep and Light Exposure in Humans. PLoS ONE 7(2): e30037. doi 10.1371/journal.pone.0030037.
[8]
Drijfhout WJ, Brons HF, Oakley N, Hagan RM, Grol CJ, et al. (1997) A microdialysis study on pineal melatonin rhythms in rats after an 8-h phase advance: new characteristics of the underlying pacemaker. Neuroscience 80: 233–239.
[9]
Kennaway DJ, Voultsios A, Varcoe TJ, Moyer RW (2003) Melatonin and activity rhythm responses to light pulses in mice with the Clock mutation. Am J Physiol Regul Integr Comp Physiol 284: R1231–1240.
[10]
Armstrong SM (1989) Melatonin and circadian control in mammals. Experientia 45: 932–938.
[11]
Erlich SS, Apuzzo ML (1985) The pineal gland: anatomy, physiology, and clinical significance. J Neurosurg 63: 321–341.
[12]
Lima FB, Matsushita DH, Hell NS, Dolnikoff MS, Okamoto MM, et al. (1994) The regulation of insulin action in isolated adipocytes. Role of the periodicity of food intake, time of day and melatonin. Braz J Med Biol Res 27: 995–1000.
[13]
Ha E, Yim SV, Chung JH, Yoon KS, Kang I, et al. (2006) Melatonin stimulates glucose transport via insulin receptor substrate-1/phosphatidylinositol 3-kinase pathway in C2C12 murine skeletal muscle cells. J Pineal Res 41: 67–72.
[14]
Alonso-Vale MI, Andreotti S, Peres SB, Anhê GF, das Neves Borges-Silva C, et al. (2005) Melatonin enhances leptin expression by rat adipocytes in the presence of insulin. Am J Physiol Endocrinol Metab 288: E805–E812.
[15]
Lima FB, Machado UF, Bartol I, Seraphim PM, Sumida DH, et al. (1998) Pinealectomy causes glucose intolerance and decreases adipose cell responsiveness to insulin in rats. Am J Physiol 275: E934–E941.
[16]
Nogueira TC, Lellis-Santos C, Jesus DS, Taneda M, Rodrigues SC, et al. (2011) Absence of melatonin induces night-time hepatic insulin resistance and increased gluconeogenesis due to stimulation of nocturnal unfolded protein response. Endocrinology 152: 1253–1263.
[17]
Martins E Jr, Ligeiro de Oliveira AP, Fialho de Araujo AM, Tavares de Lima W, Cipolla-Neto J, et al. (2001) Melatonin modulates allergic lung inflammation. J Pineal Res 31: 363–369.
[18]
Mauriz JL, Molpeceres V, García-Mediavilla MV, González P, Barrio JP, et al. (2007) Melatonin prevents oxidative stress and changes in antioxidant enzyme expression and activity in the liver of aging rats. J Pineal Res 42: 222–230.
[19]
Bonora E, Manicardi V, Zavaroni I, Coscelli C, Butturini U (1987) Relationships between insulin secretion, insulin metabolism and insulin resistance in mild glucose intolerance. Diabete Metab 13: 116–121.
[20]
Caperuto LC, Anhê GF, Cambiaghi TD, Akamine EH, do Carmo Buonfiglio D, et al. (2008) Modulation of bone morphogenetic protein-9 expression and processing by insulin, glucose, and glucocorticoids: possible candidate for hepatic insulin-sensitizing substance. Endocrinology 149: 6326–6335.
[21]
Bordin S, Boschero AC, Carneiro EM, Atwater I (1995) Ionic mechanisms involved in the regulation of insulin secretion by muscarinic agonists. J Membr Biol 148: 177–184.
[22]
DeFronzo RA, Bonadonna RC, Ferrannini E (1992) Pathogenesis of NIDDM. A balanced overview. Diabetes Care 15: 318–368.
[23]
Rothenberg PL, Lane WS, Karasik A, Backer J, White M, et al. (1991) Purification and partial sequence analysis of pp185, the major cellular substrate of the insulin receptor tyrosine kinase. J Biol Chem 266: 8302–8311.
[24]
Li PM, Goldstein BJ (1996) Cell density-dependent changes in the insulin action pathway: evidence for involvement of protein-tyrosine phosphatases. J Cell Biochem 61: 31–38.
[25]
Taniguchi CM, Emanuelli B, Kahn CR (2006) Critical nodes in signalling pathways: insights into insulin action. Nat Rev Mol Cell Biol 7: 85–96.
[26]
Tamura H, Takayama H, Nakamura Y, Reiter RJ, Sugino N (2008) Fetal/placental regulation of maternal melatonin in rats. J Pineal Res 44: 335–340.
[27]
Richter HG, Hansell JA, Raut S, Giussani DA (2009) Melatonin improves placental efficiency and birth weight and increases the placental expression of antioxidant enzymes in undernourished pregnancy. J Pineal Res 46: 357–364.
[28]
Nagai R, Watanabe K, Wakatsuki A, Hamada F, Shinohara K, et al. (2008) Melatonin preserves fetal growth in rats by protecting against ischemia/reperfusion-induced oxidative/nitrosative mitochondrial damage in the placenta. J Pineal Res 45: 271–276.
[29]
McPherson M, Janssen I, Grundy A, Tranmer J, Richardson H, et al. (2011) Physical activity, sedentary behavior, and melatonin among rotating shift nurses. J Occup Environ Med 53: 716–721.
[30]
Borugian MJ, Gallagher RP, Friesen MC, Switzer TF, Aronson KJ (2005) Twenty-four-hour light exposure and melatonin levels among shift workers. J Occup Environ Med 47: 1268–1275.
[31]
Dumont M, Lanct?t V, Cadieux-Viau R, Paquet J (2012) Melatonin production and light exposure of rotating night workers. Chronobiol Int 29: 203–210.
[32]
Zanquetta MM, Seraphim PM, Sumida DH, Cipolla-Neto J, Machado UF (2003) Calorie restriction reduces pinealectomy-induced insulin resistance by improving GLUT4 gene expression and its translocation to the plasma membrane. J Pineal Res 35: 141–148.
[33]
Bonadonna RC, Del Prato S, Saccomani MP, Bonora E, Gulli G, et al. (1993) Transmembrane glucose transport in skeletal muscle of patients with non-insulin-dependent diabetes. J Clin Invest 92: 486–494.
[34]
Huang C, Thirone AC, Huang X, Klip A (2005) Differential contribution of insulin receptor substrates 1 versus 2 to insulin signaling and glucose uptake in l6 myotubes. J Biol Chem 280: 19426–19435.
[35]
Bae SS, Cho H, Mu J, Birnbaum MJ (2003) Isoform-specific regulation of insulin-dependent glucose uptake by Akt/protein kinase B. J Biol Chem 278: 49530–49536.
[36]
Picinato MC, Haber EP, Carpinelli AR, Cipolla-Neto J (2002) Daily rhythm of glucose-induced insulin secretion by isolated islets from intact and pinealectomized rat. J Pineal Res 33: 172–177.
[37]
Picinato MC, Haber EP, Cipolla-Neto J, Curi R, de Oliveira Carvalho CR, et al. (2002) Melatonin inhibits insulin secretion and decreases PKA levels without interfering with glucose metabolism in rat pancreatic islets. J Pineal Res 33: 156–160.
[38]
Mühlbauer E, Albrecht E, Hofmann K, Bazwinsky-Wutschke I, Peschke E (2011) Melatonin inhibits insulin secretion in rat insulinoma β-cells (INS-1) heterologously expressing the human melatonin receptor isoform MT2. J Pineal Res 51: 361–372.
[39]
Picinato MC, Hirata AE, Cipolla-Neto J, Curi R, Carvalho CR, et al. (2008) Activation of insulin and IGF-1 signaling pathways by melatonin through MT1 receptor in isolated rat pancreatic islets. J Pineal Res 44: 88–94.
[40]
Torres-Farfan C, Richter HG, Germain AM, Valenzuela GJ, Campino C, et al. (2004) Maternal melatonin selectively inhibits cortisol production in the primate fetal adrenal gland. J Physiol 554: 841–856.
[41]
Torres-Farfan C, Richter HG, Rojas-García P, Vergara M, Forcelledo ML, et al. (2003) mt1 Melatonin receptor in the primate adrenal gland: inhibition of adrenocorticotropin-stimulated cortisol production by melatonin. J Clin Endocrinol Metab 88: 450–458.
[42]
Torres-Farfan C, Mendez N, Abarzua-Catalan L, Vilches N, Valenzuela GJ, et al. (2011) A circadian clock entrained by melatonin is ticking in the rat fetal adrenal. Endocrinology 152: 1891–1900.
[43]
Nyirenda MJ, Lindsay RS, Kenyon CJ, Burchell A, Seckl JR (1998) Glucocorticoid exposure in late gestation permanently programs rat hepatic phosphoenolpyruvate carboxykinase and glucocorticoid receptor expression and causes glucose intolerance in adult offspring. J Clin Invest 101: 2174–2181.
