Estrogen and adiposity--utilizing models of aromatase deficiency to explore the relationship.

Estrogen has an important role to play in energy homeostasis in both men and mice. Lack of estrogen results in the development of a metabolic syndrome in humans and rodents, including excess adiposity, hepatic steatosis (in male but not female aromatase knockout (ArKO) mice) and insulin resistance. Estrogen replacement results in a prompt reversal of the energy imbalance symptoms associated with estrogen deficiency. A corollary to the perturbed energy balance observed in the ArKO mouse is the death by apoptosis of dopaminergic neurons in the hypothalamic arcuate nucleus of male ArKO mice, an area of the brain pivotal to the regulation of energy uptake, storage, and mobilisation. An extension of our work exploring the relationship between estrogen and adiposity has been to examine the role played by androgens in energy balance. We have demonstrated that an increased androgen to estrogen ratio can promote visceral fat accumulation in the rodent by inhibiting AMPK activation and stimulating lipogenesis. Therefore, understanding the regulation of energy homeostasis is becoming an increasingly fascinating challenge, as the number of contributors, their communications, and the complexity of their interactions, involved in the preservation of this equilibrium continues to increase. Models of aromatase deficiency, both naturally occurring and engineered, will continue to provide valuable insights into energy homeostasis.

Sleep and rest regulation in young and old oestrogen-deficient female mice.

The effect of circulating oestrogen deficiency on sleep regulation and locomotor activity was investigated in aromatase cytochrome P450 deficient mice (ArKO) and wild-type (WT) controls. Sleep was recorded in 3-month old mice during a 24-h baseline day, 6-h sleep deprivation (SD) and 18-h recovery, and activity was recorded at the age of 3, 9 and 12 months. In mice deficient of oestrogen, the total amount of sleep per 24 h was the same as in WT controls. However, in ArKO mice, sleep was enhanced in the dark period at the expense of sleep in the light phase, and was more fragmented than sleep in WT mice. This redistribution of sleep resulted in a damped amplitude of slow-wave activity (SWA; power between 0.75-4.0 Hz) in non-rapid eye movement sleep across 24 h. After SD, the rebound of sleep and SWA was similar between the genotypes, suggesting that oestrogen deficiency does not affect the mechanisms maintaining the homeostatic balance between the amount of sleep and its intensity. Motor activity decreased with age in both genotypes and was lower in ArKO mice compared to WT at all three ages. After SD, the amount of rest in 3-month old WT mice increased above baseline and was more consolidated. Both effects were less pronounced in ArKO mice, reflecting the baseline differences between the genotypes. The results indicate that despite the pronounced redistribution of sleep and motor activity in oestrogen deficient mice, the basic homeostatic mechanisms of sleep regulation in ArKO mice remain intact.

Cholesterol feeding prevents adiposity in the obese female aromatase knockout (ArKO) mouse.

The aromatase (ArKO) knockout mouse develops obesity marked by increased gonadal fat depots. This obesity is characterized by pronounced hypertrophy and hyperplasia in adipocytes with corresponding increases in transcripts involved in fat development. Aromatase deficiency in mice and humans with natural mutations of the aromatase gene also leads to metabolic syndrome, particularly hepatic steatosis. In ArKO mice, this hepatic steatosis, the increased body weight and serum triglycerides are surprisingly prevented by cholesterol feeding. We sought to investigate whether the reduction in body weight upon cholesterol feeding is reflected in gonadal fat depots, which account for a large percentage of body weight in the ArKO mouse. Indeed, gonadal fat depots in female ArKO mice were significantly reduced after cholesterol feeding. Concomitantly, adipocyte hyperplasia and hypertrophy were dramatically reduced upon cholesterol feeding in ArKO mice. Real-time PCR analysis revealed concurrent changes with adipocyte volume in the levels of lipoprotein lipase, caveolin-1 and CD59 transcripts. Little change was observed in levels of transcripts involved in de novo fatty acid synthesis, beta-oxidation, lipolysis, differentiation and cholesterol metabolism, suggesting that cholesterol feeding prevents hyperplasia and hypertrophy of ArKO adipocytes, possibly as a consequence of changes in transcript levels of lipoprotein lipase and therefore fatty acid uptake.

Prepulse inhibition of acoustic startle in aromatase knock-out mice: effects of age and gender.

Estrogen has been suggested to play a neuromodulatory and neuroprotective role on the brain dopamine system. We used aromatase knockout (ArKO) mice that lack a functional aromatase enzyme and are unable to convert testosterone into estrogen, and assessed prepulse inhibition of acoustic startle, locomotor hyperactivity to amphetamine treatment and rotarod performance. Mice were tested at either 1 month, 4-5 months or 12-18 months of age. In male, but not female ArKO mice, there was an age-related reduction of prepulse inhibition. The 12-18 months old male ArKO mice also showed significantly greater amphetamine-induced hyperactivity. Mice heterozygous for the mutation showed no deficits or were in-between wildtype mice and ArKO mice. We postulate that these data indicate a neuroprotective role of estrogen, particularly in male mice, on ageing of brain mechanisms involved in pre-pulse inhibition and locomotor activity regulation. It is likely that these brain mechanisms are or include dopaminergic activity.

Effect of estrogen deficiency in the male: the ArKO mouse model.

Aromatase, the enzyme responsible for the conversion of androgens to estrogens, is present in the mouse gonads, brain, adipose tissue and bone. Depletion of endogenous estrogens in the aromatase deficient mouse (ArKO) caused by the targeted disruption of the Cyp19 gene resulted in an impairment of sexual behaviour and an age-dependent disruption of spermatogenesis. This disruption occurred during early spermiogenesis, due possibly to increased number of apoptotic round spermatids. Development of obesity was associated with ageing, decrease in lean mass, hypercholesterolemia, hyperleptinemia, and insulin resistance and hepatic steatosis. However, it was not correlated with hyperphagia but to decreased physically-active behaviour. ArKO mice also developed osteoporosis. Thus, studies using the ArKO mice model has led to several insights into the multiple roles played by estrogens in the development and maintenance of fertility, sexual behaviour, lipid metabolism and bone remodelling.