A water-alcohol extract of Citrus grandis whole fruits has beneficial metabolic effects in the obese Zucker rats fed with high fat/high cholesterol diet.

Epidemiological studies suggest that citrus fruits and compounds such as flavonoids, limonoids and pectins have health promoting effects. Our aim was to study the effects of Citrus grandis (L.) Osbeck var. tomentosa hort. fruit extract on the energy metabolism. A whole fruit powder from dry water and alcohol extracts of C. grandis containing 19% naringin flavonoid was prepared. The effects of the citrus extract were followed in the obese Zucker rats fed with the HFD. The circulatory levels of GLP-1 decreased significantly by the extract in comparison to the HFD group, whereas the decreased ghrelin levels were reversed. The levels of PYY were decreased in all HFD groups. The leptin amounts decreased but not significantly whereas insulin and amylin were unchanged. The cholesterol and glucose levels were somewhat but not systematically improved in the HFD fed rats. Further studies are needed to identify the active compounds and their mechanisms.

Neuroanatomical mapping of juvenile rat brain regions with prominent basal signal in [(35)S]GTPgammaS autoradiography.

[(35)S]GTPgammaS autoradiography represents a powerful functional approach to detect receptor-dependent G(i/o) protein activity in anatomically defined brain structures. Inherent to this technique, however, is the notable basal signal evident in several brain regions in the absence of receptor stimulation by exogenously added agonist. In the rat brain, much of this basal labelling derives from tonic activation of adenosine A(1) and lysophosphatidic acid LPA(1) receptors in the gray and white matter regions, respectively. Despite the elimination of the two receptor activities, prominent basal [(35)S]GTPgammaS labelling is still evident in discrete brain structures, possibly reflecting regional enrichment of G(i/o) and/or constitutive receptor activity or the presence of still unknown endogenous ligands activating their orphan receptors. Here, the anatomical distribution of the enhanced basal signal was systematically mapped in brain sections of 4-week-old male Wistar rats. Regions with prominent basal [(35)S]GTPgammaS labelling represented neuroanatomically distinct structures, in particular various thalamic and hypothalamic nuclei. For instance, the paraventricular thalamic nucleus, the bed nucleus of the stria terminalis and the subfornical organ were highly labelled, as were the periaqueductal gray and the nucleus of the solitary tract. Pre-treatment with N-ethylmaleimide (NEM), an alkylating agent preventing all known receptor-driven G protein activity in cryostat sections markedly decreased the basal binding in all examined regions. In preliminary screening, selective antagonists for various brain-enriched G(i/o)-coupled receptors failed to suppress the basal signal in any of the studied regions.

Increased leptin expression in the dorsal vagal complex suppresses adiposity without affecting energy intake and metabolic hormones.

OBJECTIVE: Increased leptin transgene expression locally in hypothalamic sites suppresses weight and energy intake, enhances thermogenic energy expenditure, and differentially modulates metabolic hormones for an extended period. We evaluated whether a similar localized expression of leptin transgene in the dorsal vagal complex (DVC) in the caudal brain stem that also displays the biologically relevant leptin receptor would reproduce these varied responses and thus demonstrate functional connectivity between the hypothalamus and DVC. RESEARCH METHODS AND PROCEDURES: Adult female rats were microinjected with a recombinant adeno-associated virus encoding either rat leptin or green fluorescent protein gene (control) in the DVC. Food intake and body weight were monitored weekly, and metabolic variables were analyzed at the end of 10 weeks. RESULTS AND DISCUSSION: Increased leptin transgene expression in the DVC suppressed the time-related increase in body weight accompanied by a transient decrease in food intake at week 1 post-injection and little effect on thermogenic energy expenditure. That suppression of weight was due to decreased adiposity is shown by the markedly suppressed white adipose tissue-derived hormones, leptin and adiponectin. Circulating concentrations of pancreatic insulin, gastric ghrelin, and glucose levels were unchanged. This segregation of the varied effects of leptin expression in hypothalamic sites vs. DVC endorses the view that among the various endocrine organs under sympathetic nervous system control, only those leptin-activated neural circuits in the hypothalamus that suppress weight and adiposity on a long-term basis transverse through DVC en route to white adipose tissue.

Perigestational suppression of weight gain with central leptin gene therapy results in lower weight F1 generation.

The efficacy of central leptin therapy on weight homeostasis through various phases of reproduction, pregnancy outcome and postnatal, prepubertal and pubertal growth of offspring was assessed. Enhanced leptin transgene expression after a single intracerebroventricular injection of recombinant adeno-associated virus vector encoding the leptin gene (rAAV-lep) decreased calorie intake and weight in adult nulliparous female rats. rAAV-lep treated rats conceived normally, displayed unremarkable pregnancy rate, parturition and delivered normal sized litters. Significantly lower weight was maintained through gestation, lactation, and post-lactation periods. The maintenance of a modest weight reduction was accompanied by voluntarily reduced calorie intake, increased thermogenic energy expenditure, decreased adiposity as reflected by drastically reduced leptin levels, and suppressed insulin and insulin-like growth factor 1 levels through lactation and post-lactation in rAAV-lep treated dams. The offspring at birth weighed significantly less than those of controls and this lower weight range was sustained during postnatal, prepubertal, pubertal and adult (3 months old) periods, contemporaneous with metabolic circulating hormones in the normal range. For the first time we show the persistent efficacy of central leptin gene therapy to suppress weight gain through all phases of reproduction, lactation and post-lactation in dams and reveal the potential imprinting link to producing lower weight in the F1 generation.