Effect of inhibin, follistatin, or activin infusion into the lateral hypothalamus on operant behavior of rats fed lysine deficient diet

Brain amino acid sensing

The 20 different amino acids, in blood as well as in the brain, are strictly maintained at the same levels throughout the day, regardless of food intake. Gastric vagal afferents only respond to free glutamate and sugars, providing recognition of food intake and initiating digestion. Metabolic control of amino acid homeostasis and diet-induced thermogenesis is triggered by this glutamate signalling in the stomach through the gut-brain axis. Rats chronically fed high-sugar and high-fat diets do not develop obesity when a 1% (w/v) monosodium glutamate (MSG) solution is available in a choice paradigm. Deficiency of the essential amino acid lysine (Lys) induced a plasticity in rats in response to Lys. This result shows how the body is able to identify deficient nutrients to maintain homeostasis. This plastic effect is induced by activin A activity in the brain, particularly in certain neurons in the lateral hypothalamic area (LHA) which is the centre for amino acid homeostasis and appetite. These neurons respond to glutamate signalling in the oral cavity by which umami taste is perceived. They play a quantitative role in regulating ingestion of deficient nutrients, thereby leading to a healthier life. After recovery from malnutrition, rats prefer MSG solutions, which serve as biomarkers for protein nutrition.

Involvement of activin and inhibin in the regulation of food and water intake in the rat

The expression of activin and inhibin has been demonstrated in the hypothalamus, but their physiological roles in the brain remain to be elucidated. In the present study, involvement of activin and inhibin in the regulation of food and water intake was examined. Male rats were deprived of food or water for 12 and 60 hr, and mRNA levels of activin/inhibin alpha, betaA and betaB subunits in the hypothalamus were estimated by RT-PCR. Gene expression of alpha subunit transiently decreased at 12 hr of food deprivation, while it did not change during water deprivation. Food and water deprivation for 60 hr increased mRNA levels of betaA and betaB subunits, respectively. These results indicated that gene expression of each subunit was independently regulated. Injection of activin A (0.5 and 4.0 microg) into the third ventricle decreased food intake. Water intake was suppressed by 4.0 microg, but not 0.5 microg, of activin A. Intracerebroventricular injection of inhibin A (0.5 and 4.0 microg) decreased water intake in a dose dependent manner without affecting food intake, suggesting that inhibin could act independently of activin. Taken together, it is suggested that activin and inhibin take part in the central regulation of nutrient and fluid balance, though further study is needed to determine precise molecular species involved.

Circadian release of hypothalamic norepinephrine in rats in vivo is depressed during early L-lysine deficiency

Rats rapidly recognize an amino acid-deficient diet, presumably via central mechanisms that involve hypothalamic circuits. We evaluated the effects of a deficiency of the essential amino acid, L-lysine, on the ventromedial hypothalamus (VMH) norepinephrine (NE) circadian release in free-moving, nonstressed rats. A dialysis probe was implanted into the VMH of male Wistar rats. Continuous microdialysis measurement was done during the first 26 h of L-lysine (Lys) deficiency in rats that had free access to food and fluid. The dark phase was from 1900 to 0700 h. Rats were divided into six groups according to their food and fluid intakes. They were fed either normal (Lys sufficient) or Lys deficient powdered food and provided with distilled water, glycine (Gly, 400 mmol/L) or Lys solution (400 mmol/L). In control rats, VMH NE release showed a diurnal pattern, with the lowest levels measured at the onset of the dark phase. In Lys-deficient rats, the release was significantly depressed from the early morning (0500 h) compared with Lys-sufficient rats, without any differences in food and fluid intakes. A normal pattern of VMH NE was restored by the provision of 400 mmol/L Lys solution to deficient rats. The results suggest that the VMH NE release is involved in the early integration of signals about amino acid deficiency.

Effects of L-lysine deficient diet on the hypothalamic interstitial norepinephrine and diet-induced thermogenesis in rats in vivo

Rats readily recognize an amino acid deficient diet, presumably via central mechanisms that involve hypothalamic circuits. Presently, effects of the essential amino acid L-lysine deficiency on the ventromedial (VMH) and lateral (LH) hypothalamus norepinephrine (NE) release were evaluated in free moving rats. Microdialysis measurement was undertaken once in 48 h (12:00 noon-14:00) in rats that had free access to food and drink. Significant decline in the food intake and VMH NE release were found in rats fed L-lysine diet. No changes were identified in LH NE release. Additionally, no significant differences in diet-induced spatial thermogenesis between normal and L-lysine deficient non-stressed rats were found in vivo. The results suggested that the VMH NE release was specifically involved in the integration of signals about amino acid deficiency. However, the decrease in VMH NE was not translated into changes of thermogenic responses to diet.

Activin exerts a neurotrophic effect on cultured hippocampal neurons

Activin is a member of the transforming growth factor (TGF)-beta superfamily, which comprises a growing list of multifunctional proteins that serve as regulators of cell proliferation and differentiation. Recently, activin was shown to regulate the neurotransmitter phenotype in peripheral neurons. It is also a potent survival factor for neurogenic clonal cell lines, retinal neurons and midbrain dopaminergic neurons. We have studied the effect of activin on hippocampal cells which show abundant expression of activin receptors or binding sites. Exposure of primary cultures of rat hippocampal neurons to activin supported neuronal survival. This neurotrophic action of activin was blocked by treatment with the tyrosine kinase inhibitor genistein or the protein kinase C inhibitor calphostin C. However, the Ca2+/calmodulin kinase inhibitor KN-62 had no effect. Nicardipine, a blocker of the L-type Ca2+ channel, also inhibited the neurotrophic effect of activin. Furthermore, activin potentiated the depolarization-induced elevation in intracellular Ca2+ concentration ([Ca2+]i). The neurotrophic effect and the potentiation of depolarization-induced increase of [Ca2+]i caused by activin were completely abolished by the protein synthesis inhibitor cycloheximide. These results suggest that activin supports neuronal survival by increasing the expression of voltage-dependent Ca2+ channel through the action of a tyrosine kinase and of protein kinase C, but not of Ca2+/calmodulin kinase.