Hepatic vagotomy alters limbic and hypothalamic neuropeptide responses to insulin-dependent diabetes and voluntary lard ingestion.

Hypothalamic anorexigenic [corticotropin-releasing factor (CRF) and proopiomelanocortin] peptides decrease and the orexigen, neuropeptide Y, increases with diabetic hyperphagia. However, when diabetic rats are allowed to eat lard (saturated fat) as well as chow, both caloric intake and hypothalamic peptides normalize. These neuropeptide responses to lard require an intact hepatic vagus [la Fleur et al. (2003) Diabetes, 52, 2321-2330]. Here, we delineate temporal interactions after lard consumption +/- hepatic vagotomy (HV) between feeding and brain neuropeptide expression in insulin-dependent diabetic rats. CRF-mRNA was reduced in the paraventricular nuclei (PVN) by 6 h after presentation of lard, before caloric intake increased in HV-diabetic rats, and did not increase at 30 or 36 h, as it did in shamHV-diabetic rats eating lard. CRF-mRNA was increased in the bed nuclei of the stria terminalis of HV-diabetic rats compared with shamHV-diabetic rats only when caloric intake was high at 30 or 36 h. At 36 h, shamHV-diabetic rats eating chow had increased CRF-mRNA in the central amygdala but diabetic rats eating lard had decreased CRF-mRNA, whereas HV-diabetic rats eating chow or lard had normal CRF-mRNA in the central amygdala. We conclude that eating lard restores peptide expression to normal in the hypothalamus of diabetic rats, and because decreased CRF-mRNA in the PVN precedes the increase in caloric intake in HV-diabetic rats eating lard, that the loss of a hepatic vagal signal to PVN may be responsible for increased intake; moreover, CRF-mRNA in limbic structures is also sensitive to both HV and lard ingestion in diabetic rats.

Interaction between corticosterone and insulin in obesity: regulation of lard intake and fat stores.

Passive elevations in glucocorticoids result in increased insulin and abdominal obesity with peripheral wasting, as observed in Cushing's syndrome, with little effect on chow intake. In the absence of insulin (streptozotocin-induced diabetes) diabetic rats markedly increase their chow intake in proportion to glucocorticoids. Given a choice of lard or chow, diabetic rats first eat lard, then reduce caloric intake to normal for 48 h before returning to hyperphagia on chow alone. We performed three experiments to determine the relationship of corticosterone and insulin to lard intake, chow intake, body weight, hormones, and fat depots. The results of these studies clarify the actions of both circulating glucocorticoids and insulin on caloric intake in adult male rats. Our experiments show that glucocorticoids provoke dose-related increases in total caloric intake that persist for days and weeks; the results also suggest that increasing insulin concentrations stimulated by glucocorticoids determine the amount of fat intake. Furthermore, we show that lard intake is associated with increasing insulin concentrations. Additionally, the results in adrenalectomized and adrenalectomized, streptozotocin-induced diabetic rats strongly suggest that it is a combination of corticosterone and insulin that increases abdominal fat depot weight. Independently of the hormonally manipulated rats, the results also show that intact rats voluntarily eat a considerable and stable proportion of their daily calories as lard when given a choice between lard and chow. These results suggest that some human obesities may result from elevated glucocorticoids and insulin increasing the proportional intake of high density calories.

The hepatic vagus mediates fat-induced inhibition of diabetic hyperphagia.

Diabetic rats both overeat high-carbohydrate diet and have altered hypothalamic neuropeptide Y (NPY) and corticotropin-releasing factor (CRF). In contrast, a high-fat diet reduces caloric intake of diabetics to normal, reflected by normal hypothalamic NPY and CRF content. How the brain senses these changes in diet is unknown. To date, no hormonal changes explain these diet-induced changes in caloric intake. We tested whether the common branch of the hepatic vagus mediates the fat signal. We presented fat in two ways. First, diabetic and vehicle-treated rats were offered a cup of lard in addition to their normal high-carbohydrate diet. Second, we switched diabetic rats from high-carbohydrate diet to high-fat diet, without choice. In streptozotocin-treated rats, both methods resulted in fat-induced inhibition of caloric intake and normalization of hypothalamic neuropeptides to nondiabetic levels. Strikingly, common branch hepatic vagotomy (unlike gastroduodenal vagotomy) entirely blocked these fat-induced changes. Although a shift in hepatic energy status did not explain the lard-induced changes in diabetic rats, the data suggested that common hepatic branch vagotomy does not interfere with hepatic energy status. Furthermore, common branch hepatic vagotomy without diabetes induced indexes of obesity. Abnormal function of the hepatic vagus, as occurs in diabetic neuropathy, may contribute to diabetic obesity.