Mary Jane Cullen

Characteristics of BDNF-induced weight loss

There is evidence that central infusion of brain-derived neurotrophic factor (BDNF) induces weight loss in rats. We have begun to investigate the physiological basis for BDNF-induced weight loss by assessing its relationship to (a) appetite, (b) serum indices of metabolic and renal toxicity, and (c) brain monoamine activity in areas associated with feeding or motor function. BDNF (0-6 microgram/day) was infused into the lateral ventricle (LV) of male Long-Evans rats for 14 days. Body weight and food intake were monitored throughout infusion and recovery periods. BDNF induced severe, dose-dependent appetite suppression and weight loss. Although appetite began to recover after the 10th infusion day, body weight had not returned to control values at the end of the recovery period. The weight loss observed in BDNF-infused rats was related to appetite suppression, since uninfused rats that were pair-fed to high dose BDNF-treated rats showed comparable weight loss. Despite severe weight loss, serum BUN, creatinine, thyroxine, glucose, and total protein were not affected by BDNF infusion. Striatal DO-PAC/DA was similarly unaffected by BDNF. In contrast, BDNF-infused rats showed a dose-dependent increase in hypothalamic 5-HIAA/5-HT that was not observed in pair-fed rats, suggesting that the observed increase in hypothalamic 5-HIAA/5-HT was a direct effect of BDNF infusion rather than a secondary effect of food restriction. These data suggest that BDNF may induce appetite suppression and weight loss through a central mechanism.

The effects of intrahippocampal BDNF and NGF on spatial learning in aged long evans rats

Spatial learning rate was compared in cognitively impaired aged rats infused with either brain-derived neurotrophic factor (BDNF) or nerve growth factor (NGF). BDNF or NGF was infused into the dorsal hippocampus/third ventricle while animals were being trained on the Morris water maze. Training continued until all rats met a spatial learning criterion. Seven weeks later, they were tested for retention of the task, and sacrificed for assessment of hippocampal high-affinity choline uptake (HACU) or hypothalamic biogenic amine levels. NGF, but not BDNF, improved spatial learning rate in aged rats and increased hippocampal choline uptake weeks after withdrawal of NGF. Although BDNF did not improve spatial learning, it did induce a partial, long-term normalization of the elevated hypothalamic 5-HT levels observed in our aged rats. These data suggest that (1) intrahippocampal/intraventricular infusion of NGF can improve the learning rate of aged, spatial learning-impaired rats, and that this improvement in acquisition could be associated with increased hippocampal cholinergic activity, and (2) that the BDNF-induced normalization of hypothalamic 5-HT levels in aged rats was not sufficient to improve learning rate in aged, spatial learning-impaired rats.

Efficacy of exogenous recombinant murine leptin in lean and obese 10- to 12-mo-old female CD-1 mice

Leptin efficacy was compared in obese and lean female CD-1 mice. Body weights in these 10- to 12-mo-old mice ranged from 29.7 to 62.0 g, and leptin levels correlated with body weight. Mice from the lean and obese ends of the weight distribution were treated with daily peripheral leptin injections (1-100 mg/kg) for a 33-day period. The half-maximal effective doses for weight loss and fat reduction were shifted 0.5-0.7 log to the right for obese mice. Leptin was less efficacious at low doses (1-3 mg/kg) in obese mice but equal to or more efficacious in obese than lean mice at high doses (30-100 mg/kg). Leptins initial effects on weight loss could be explained by appetite suppression in both groups, but its effects on fat reduction were greater in leptin-treated than pair-fed mice, particularly in the lean group. Leptin also prevented the elevations in serum corticosterone and ketones found in pair-fed lean mice. These data allow a quantitative comparison of leptin sensitivity in obese vs. lean CD-1 mice and suggest that in mice where obesity is a function of outbreeding and age, leptin sensitivity is moderately reduced. Furthermore, although appetite suppression has a clear role in leptins effects on body weight, leptin may also have specific effects on lipid metabolism and mobilization that are different from the metabolic compensations that normally occur with food deprivation.Leptin efficacy was compared in obese and lean female CD-1 mice. Body weights in these 10- to 12-mo-old mice ranged from 29.7 to 62.0 g, and leptin levels correlated with body weight. Mice from the lean and obese ends of the weight distribution were treated with daily peripheral leptin injections (1-100 mg/kg) for a 33-day period. The half-maximal effective doses for weight loss and fat reduction were shifted 0.5-0.7 log to the right for obese mice. Leptin was less efficacious at low doses (1-3 mg/kg) in obese mice but equal to or more efficacious in obese than lean mice at high doses (30-100 mg/kg). Leptins initial effects on weight loss could be explained by appetite suppression in both groups, but its effects on fat reduction were greater in leptin-treated than pair-fed mice, particularly in the lean group. Leptin also prevented the elevations in serum corticosterone and ketones found in pair-fed lean mice. These data allow a quantitative comparison of leptin sensitivity in obese vs. lean CD-1 mice and suggest that in mice where obesity is a function of outbreeding and age, leptin sensitivity is moderately reduced. Furthermore, although appetite suppression has a clear role in leptins effects on body weight, leptin may also have specific effects on lipid metabolism and mobilization that are different from the metabolic compensations that normally occur with food deprivation.

An age-related decline in striatal taurine is correlated with a loss of dopaminergic markers

Taurine is present in high concentration in the mammalian brain and is known to decline with aging. The present studies examined the relationship between the loss of striatal neurotransmitters and spatial learning ability in aged male Long-Evans rats. The effects of intrahippocampal infusions of neurotrophic factors-nerve growth factor (NGF) and brain-derived neurotrophic factor-were also examined for their ability to ameliorate the age-related decline in brain amino acid content. Taurine content was found to be significantly reduced in the striatum of aged rats (26 months old) that were impaired in spatial learning performance when compared to young unimpaired rats (5 months old). Aged rats that were behaviorally unimpaired had more modest reductions in taurine. Striatal dopamine content was also significantly reduced in aged learning-impaired rats. There was a significant (p < 0.001) correlation (r=0.61) between the striatal content of taurine and dopamine, but no such correlation was found for other striatal transmitters (glutamate, serotonin, norepinephrine). Treatment with neurotrophins had little effect on the age-related decline in striatal amino acids, although NGF treatment did improve spatial learning. These studies suggest (1) a link between age-related declines in striatal dopamine and taurine and (2) that NGF-induced improvement in spatial learning is not related to mechanisms involving changes in taurine or glutamate content.

Identification of a nonbasic melanin hormone receptor 1 antagonist as an antiobesity clinical candidate.

Identification of MCHR1 antagonists with a preclinical safety profile to support clinical evaluation as antiobesity agents has been a challenge. Our finding that a basic moiety is not required for MCHR1 antagonists to achieve high affinity allowed us to explore structures less prone to off-target activities such as hERG inhibition. We report the SAR evolution of hydroxylated thienopyrimidinone ethers culminating in the identification of 27 (BMS-819881), which entered obesity clinical trials as the phosphate ester prodrug 35 (BMS-830216).

Effects of controllability of stress on hippocampal pharmacology

To examine the effect of the controllability of stress on aspects of hippocampal noradrenergic, opiate, and cholinergic pharmacology, we trained rats in a controllability paradigm and assessed [3H]desmethylimipramine, [3H]quinuclidinyl benzilate, or [3H]naloxone binding in hippocampal areas CA1, CA3, and the dentate gyrus with quantitative autoradiography. Rats that could control shock termination were yoked to rats that could not control termination of equivalent shock; a third group of rats received no shock. When the rats that could terminate shock responded at an 85% rate, their brains were removed and sectioned, incubated with tritiated ligands, and exposed to film for an appropriate period. Quantitative densitometry revealed a 10%–22% decrease in naloxone binding in CA3 in rats receiving uncontrollable shock; no significant changes were observed in rats that could control shock. Thus, the ability to control shock prevented stress-induced changes in µ opiate receptor binding in area CA3 of the hippocampus.

Glial cell line-derived neurotrophic factor (GDNF) improves spatial learning in aged Fischer 344 rats

Glial cell line-derived neurotrophic factor (GDNF) increases choline acetyltransferase (ChAT) activity in the septohippocampal system of aged rats. Since the septohippocampal system has been implicated as a neurobiological substrate for spatial learning, the effects of GDNF were tested in aged, spatial learning-impaired Fisher 344 rats. Aged rats were characterized as spatial learning “impaired” or “unimpaired” using several indices of performance in the Morris water maze, and they were then given GDNF (100-µg bolus; icv) or phosphate-buffered saline (PBS). Six days after the GDNF or PBS injection, rats returned to water maze training, which continued until a spatial bias criterion was met. Immediately after meeting the criterion, rats were tested in a cue learning version of the task. GDNF significantly improved spatial learning in aged impaired rats, but not aged unimpaired or young rats. It did not alter cue learning rate for any group, nor did it alter swim speed. These data suggest that GDNF may support the integrity of neurons in the septum and hippocampus of aged rats.