Effects of fasting and refeeding on serum leptin, adiponectin and free fatty acid concentrations in young and old male rats.

BACKGROUND: Regulatory mechanisms of metabolic homeostasis undergo important alterations during ageing. The age-related changes become often evident only during stimulation of basic functions that occurs, e.g. during fasting and refeeding which represent natural challenge to energy metabolism. OBJECTIVE: To determine the effect of short-term fasting and subsequent refeeding on serum levels of key hormones and metabolites in young adult 5- and 24-month-old male Wistar rats. METHODS: Control rats were fed ad libitum. Animals were fasted for 48 h or fasted and refed for 24 h. Metabolite serum concentrations were measured by standard methods. Leptin and insulin were determined by rat-specific RIA, and adiponectin serum levels by mouse/rat-specific ELISA. RESULTS: (1) Control serum levels of key metabolites and hormones were similar in both age groups except for increased triglycerides (TG) in old fed rats. (2) Fasting caused a significant decrease of leptin, insulin, glucose, and TG serum levels in both age groups, and an increase of free fatty acids (FFA) concentration, however, only in young animals. (3) Upon refeeding serum glucose, TG and insulin reversed to control levels in both age groups, however, FFA concentration decreased to control values only in young rats. (4) In contrast to young animals, refeeding of old rats did not increase serum leptin concentration to control level. (5) Neither fasting nor refeeding changed adiponectin serum levels in both age groups. CONCLUSION: Aging suppresses leptin secretion and metabolism of FFA during refeeding that follows short-term starvation. In old rats serum levels of FFA are refractive to the alterations induced by fasting/refeeding in young ones.

The effect of fasting and refeeding on the ultrastructure of the hypothalamic paraventricular nucleus in young and old rats.

In order to explore the morphological basis of the altered feeding behaviour of old rats, an ultrastructural investigation of the magnocellular neurons of the hypothalamic paraventricular nucleus (PVN) was performed. Young and old male Wistar rats, 5 and 24 months old, respectively, and with each age group comprising 12 animals, were divided into 3 groups. The rats in Group I were used as controls (normally fed), the rats of Group II were fasted for 48 hours and in Group III the rats were fasted for 48 hours and then refed for 24 hours. The brains were fixed by perfusion and histological and ultrathin sections were obtained by routine methods. Common features of the magnocellular PVN neurons of young and old rats were abundant Golgi complexes and short fragments of RER localised at the cell periphery. In contrast to young rats, the PVN neurons of old animals showed deep indentations of the nuclear envelope and age-related residual bodies. In both age groups fasting for 48 hours led to the expansion of the Golgi complexes and dilatation of RER cisternae. In contrast to those in fed rats, RER cisternae in the neurons of old fasted animals were situated between the nuclear envelope and the Golgi zone. Prolonged RER cisternae were distributed in the peripheral cytoplasm of refed old rats. Our observations suggest that at the ultrastructural level the process of ageing does not change the responsiveness of magnocellular PVN neurons to fasting-refeeding.

Ultrastructure of the ventromedial hypothalamic nucleus in fasted and refed young and old rats.

Many hypothalamic nuclei are involved in the regulation of food intake and energy homeostasis. An ultrastructural investigation of the hypothalamic ventromedial nucleus (VMN), a hypothetical "satiety centre" was performed to explore the morphological basis of altered feeding behaviour of old rats in an experimental model of fasting/refeeding. Young (5 months old, n=12) and old (24 months old, n=12) male Wistar rats were fasted for 48 hours, then refed for 24 hours and sampled thereafter. Brain tissue was fixed by perfusion, histological and ultrathin sections were obtained by routine methods. Although food intake was similar in control young and old rats, during refeeding old animals consumed less chow than young ones. The EM analysis of VMN neurones of old control rats revealed, besides typical age-related residual bodies, deep indentations of the nuclear envelope and the presence of long, undulating rough endoplasmic reticulum cisternae in the cell periphery. In both young and old rats fasting for 48 hours led to the expansion of Golgi complexes and increased folds of the nuclear envelope, which is suggestive of enhanced cellular activity of the VMN neurones. These fasting-induced alterations were sustained in the VMN neurones of refed rats in both age groups. The results showed that the VMN neurones of old control rats differ at the ultrastructural level from young ones. However, starvation and subsequent refeeding cause similar alterations in the hypothalamic neurones of "satiety centre" of both young and old rats.

Enhanced expression of plasminogen activator inhibitor-1 by dedifferentiated thyrocytes.

Porcine thyrocytes in vitro in the presence of TSH adopt follicular-like morphology. Epidermal growth factor, phorbol esters or transforming growth factor beta-1 (TGFbeta-1) induce a rapid spreading of the cells and dedifferentiation. In addition to thyroglobulin, dedifferentiated thyrocytes secreted into the culture medium three proteins in abundant quantities. Two of them have been previously identified as thrombospondin-1 and clusterin, respectively. Using the microsequencing method we identified the third one, a M(r) 45,000 glycosylated protein, as plasminogen activator inhibitor-1 (PAI-1). EGF, phorbol esters or TGF-beta1 predominantly increased PAI-1 protein expression in TSH-treated cells. The maximal increase of PAI-1 mRNA steady-state level was observed 6 h after EGF treatment and sustained up to 48 h. Recombinant PAI-1 inhibited cell-associated plasmin activity and delayed cell spreading. Enhanced synthesis and secretion of PAI-1 upon treatment with different growth factors during dedifferentiation process and spreading may be considered a feed-back defence mechanism of the cells to harmful extracellular stimuli.