La exposición prenatal a andrógenos como factor de reprogramación fetal / Prenatal exposure to androgens as a factor of fetal programming

Both epidemiological and clinical evidence suggest a relationship between the prenatal environment and the risk of developing diseases during adulthood. The first observations about this relationship showed that prenatal growth retardation or stress conditions during fetal life were associated to cardiovascular, metabolic and other diseases in later life. However, not only those conditions may have lasting effects after birth. Growing evidence suggests that prenatal exposure to steroids (either of fetal or maternal origin) could be another source of prenatal programming with detrimental consequences during adulthood. We have recently demonstrated that pregnant women with polycystic ovary syndrome exhibit elevated androgen levels compared to normal pregnant women, which could provide an androgen excess for both female or male fetuses. We have further tested this hypothesis in an animal model of prenatal androgenization, finding that females born from androgenized mothers have a low birth weight and high insulin resistance, that starts at an early age. On the other hand, males have low testosterone and LH secretion in response to a GnRH analogue test compared to control males and alterations in seminal parameters. We therefore propose that our efforts should be directed to modify the hyperandrogenic intrauterine environment to reduce the potential development of reproductive and metabolic diseases during adulthood.

The Circadian Timing system: Making Sense of day/night gene expression

The circadian time-keeping system ensures predictive adaptation of individuals to the reproducible 24-h day/night alternations of our planet by generating the 24-h (circadian) rhythms found in hormone release and cardiovascular, biophysical and behavioral functions, and others. In mammals, the master clock resides in the suprachiasmatic nucleus (SCN) of the hypothalamus. The molecular events determining the functional oscillation of the SCN neurons with a period of 24-h involve recurrent expression of several clock proteins that interact in complex transcription/translation feedback loops. In mammals, a glutamatergic monosynaptic pathway originating from the retina regulaltes the clock gene expression pattern in the SCN neurons, synchronizing them to the light:dark cycle. The emerging concept is that neural/humoral output signals from the SCN impinge upon peripheral clocks located in other areas of the brain, heart, lung, gastrointestinal tract, liver, kidney, fibroblasts, and most of the cell phenotypes, resulting in overt circadian rhythms in integrated physiological functions. Here we review the impact of day/night alternation on integrated physiology; the molecular mechanisms and input/output signaling pathways involved in SCN circadian function; the current concept of peripheral clocks; and the potential role of melatonin as a circadian neuroendocrine transducer.