TrkB signalling pathway mediates the protective effects of exercise in the diabetic rat retina.

Diabetic retinopathy is a leading cause of vision loss. Treatment options for early retinopathy are sparse. Exercise protects dying photoreceptors in models of retinal degeneration, thereby preserving vision. We tested the protective effects of exercise on retinal and cognitive deficits in a type 1 diabetes model and determined whether the TrkB pathway mediates this effect. Hyperglycaemia was induced in Long Evans rats via streptozotocin injection (STZ; 100 mg/kg). Following confirmed hyperglycaemia, both control and diabetic rats underwent treadmill exercise for 30 min, 5 days/week at 0 m/min (inactive groups) or 15 m/min (active groups) for 8 weeks. A TrkB receptor antagonist (ANA-12), or vehicle, was injected 2.5 h before exercise training. We measured spatial frequency and contrast sensitivity using optokinetic tracking biweekly post-STZ; retinal function using electroretinography at 4 and 8 weeks; and cognitive function and exploratory behaviour using Y-maze at 8 weeks. Retinal neurotrophin-4 was measured using ELISA. Compared with non-diabetic controls, diabetic rats showed significantly reduced spatial frequency and contrast sensitivity, delayed electroretinogram oscillatory potential and flicker implicit times and reduced cognitive function and exploratory behaviour. Exercise interventions significantly delayed the appearance of all deficits, except for exploratory behaviour. Treatment with ANA-12 significantly reduced this protection, suggesting a TrkB-mediated mechanism. Despite this, no changes in retinal neurotrohin-4 were observed with diabetes or exercise. Exercise protected against early visual and cognitive dysfunction in diabetic rats, suggesting that exercise interventions started after hyperglycaemia diagnosis may be a beneficial treatment. The translational potential is high, given that exercise treatment is non-invasive, patient controlled and inexpensive.

Daily visual stimulation in the critical period enhances multiple aspects of vision through BDNF-mediated pathways in the mouse retina.

Visual experience during the critical period modulates visual development such that deprivation causes visual impairments while stimulation induces enhancements. This study aimed to determine whether visual stimulation in the form of daily optomotor response (OMR) testing during the mouse critical period (1) improves aspects of visual function, (2) involves retinal mechanisms and (3) is mediated by brain derived neurotrophic factor (BDNF) and dopamine (DA) signaling pathways. We tested spatial frequency thresholds in C57BL/6J mice daily from postnatal days 16 to 23 (P16 to P23) using OMR testing. Daily OMR-treated mice were compared to littermate controls that were placed in the OMR chamber without moving gratings. Contrast sensitivity thresholds, electroretinograms (ERGs), visual evoked potentials, and pattern ERGs were acquired at P21. To determine the role of BDNF signaling, a TrkB receptor antagonist (ANA-12) was systemically injected 2 hours prior to OMR testing in another cohort of mice. BDNF immunohistochemistry was performed on retina and brain sections. Retinal DA levels were measured using high-performance liquid chromatography. Daily OMR testing enhanced spatial frequency thresholds and contrast sensitivity compared to controls. OMR-treated mice also had improved rod-driven ERG oscillatory potential response times, greater BDNF immunoreactivity in the retinal ganglion cell layer, and increased retinal DA content compared to controls. VEPs and pattern ERGs were unchanged. Systemic delivery of ANA-12 attenuated OMR-induced visual enhancements. Daily OMR testing during the critical period leads to general visual function improvements accompanied by increased DA and BDNF in the retina, with this process being requisitely mediated by TrkB activation. These results suggest that novel combination therapies involving visual stimulation and using both behavioral and molecular approaches may benefit degenerative retinal diseases or amblyopia.

The challenges of incorporation of omega-3 fatty acids into ration components and their prevalence in garrison feeding.

Increasingly, private and military consumers are becoming aware of the positive benefits of a diet rich in omega-3 fatty acids (FAs) as health claims range from reducing inflammation to improving mood. The number of positive scientific articles supporting these claims is rapidly increasing, leading the military to examine the possibility of omega-3 supplementation for personnel. A variety of menus used either in shipboard or garrison feeding include fatty fishes that are rich in omega-3 FAs. However, omega-3 FAs have shelf-stability issues because of their susceptibility to oxidize; therefore, they create a challenge in terms of incorporation into ration components in nutritionally significant amounts. As a result, the Department of Defense Combat Feeding Directorate is investigating methods, technologies, and emerging products for incorporation of omega-3s into ration components. Based on existing research, fortification of foods with omega-3 FAs would improve nutritional quality as well as provide added benefit to the Warfighters.

The threshold of insulin-induced hypophagia is lower in chicks selected for low rather than high juvenile body weight.

Chicks genetically selected for low juvenile body weight had a lower threshold of central insulin-induced decreased food and water intake and whole blood glucose concentration than those selected for juvenile high body weight. Plasma corticosterone concentration was increased but not differently between lines. Therefore, selection may have affected insulin sensitivity which may have then contributed to their hypo- and hyperphagia and differential body weights.

Satiety induced by central stresscopin is mediated by corticotrophin-releasing factor receptors and hypothalamic changes in chicks.

The central mechanism that mediates stresscopin (SCP)-induced satiety is poorly understood, and its effect on avian appetite is not documented. Thus, this study was conducted to elucidate some of the central and behavioral mechanisms that are associated with SCP-induced satiety using broiler- and layer-type chicks (Gallus gallus) as model organisms. In Experiment 1, broiler-type chicks responded with decreased food and water intake but had increased plasma corticosterone concentration after intracerebroventricular (ICV) SCP injection. However, the effect on water intake was secondary to food intake, since food-restricted SCP-treated broiler-type chicks did not reduce water intake in Experiment 2. In Experiment 3, layer-type chicks responded with decreased food intake at much lower doses than broiler-type chicks. In Experiment 4, astressin (a non-selective corticotrophin-releasing factor [CRF] receptor antagonist) prevented SCP-induced anorexia in broiler-type chicks. In Experiment 5, SCP-treated broiler-type chicks had an increased number of c-Fos immunoreactive cells in the ventromedial hypothalamus, parvicelluar and magnocellular divisions of the paraventricular nucleus and the periventricular nucleus. In Experiment 6, SCP-treated broiler-type chicks had decreased feeding pecks and increased jumping, distance moved and more escape attempts. Thus, we conclude that central SCP causes anorexigenic and other behavioral effects in chicks, and the hypothalamus and CRF receptors are involved.

Differential feed intake responses to central corticotrophin releasing factor in lines of chickens divergently selected for low or high body weight.

Effects of intracerebroventricular (ICV) injection of corticotrophin releasing factor (CRF) on feed intake were evaluated in two lines of White Plymouth Rock chickens that have been selected from a common base population for high (HWS) or low (LWS) juvenile body weight. Both lines responded with reduced feed intake after ICV CRF; however, the threshold of response was lower in line LWS than HWS. Additionally, the effects of two receptor antagonists, astressin and alpha-helical CRF (9-41; alpha-CRF), and the effect of CRF fragment 6-33, (which displaces CRF from its binding protein), were evaluated in these lines. Although all three antagonists increased feed intake in line LWS but not line HWS, they attenuated the appetite-reducing effects of CRF only in line HWS. Peripheral plasma corticosterone concentrations after an acute stressor were higher in line LWS than in line HWS. These data support the thesis of correlated responses in the CRF system to selection for high or low juvenile body weight. These differences may contribute to differential feed intake, and hence altered body weights.

Anorexigenic effects of central neuropeptide K are associated with hypothalamic changes in juvenile Gallus gallus.

The central mechanisms that mediate neuropeptide K (NPK) associated anorexia are poorly understood in any species, and information in this area of avian biology is totally lacking. Thus, the effects of intracerebroventricular NPK treatment were studied in Cobb-500 chicks (Gallus gallus). In Experiment 1, NPK caused decreased feed intake, but did not affect water intake or whole blood glucose concentration. In Experiment 2, NPK-treated chicks had increased c-Fos immunoreactivity in the parvicellular division of the paraventricular nucleus and arcuate nucleus. The lateral hypothalamus, ventromedial hypothalamus, dorsomedial hypothalamus, periventricular nucleus, magnocellular division of the paraventricular nucleus, and the superchiasmatic nucleus were not affected by NPK treatment. In Experiment 3, the number of feed pecks, exploratory pecks, jumps, escape attempts, and distance moved were decreased, while time spent standing was increased. None of the NPK-treated chicks sat or entered deep rest. In Experiment 4, blockage of corticotrophin releasing factor receptors did not affect NPK-induced anorexia. Thus, we conclude that NPK is a regulator of chick appetite and the effects may be mediated directly in the arcuate nucleus and parvicellular division of the paraventricular nucleus.

Central and peripheral alytesin cause short-term anorexigenic effects in neonatal chicks.

We studied the effects of alytesin, a natural analogue of bombesin, on appetite-related responses and behaviors in neonatal chicks. Chicks responded to both intracerebroventricular (ICV) and peripheral injections of alytesin with short-term reduced feed intake. ICV alytesin caused reduced short-term water intake when feed was present, but we determined this effect was secondary to feed intake since an effect on water intake was not detected in feed-restricted alytesin-treated chicks. The anorexigenic effect of both ICV and peripheral alytesin may be mediated at the hypothalamus, since all hypothalamic nuclei studied; regio lateralis hypothalami, nucleus dorsomedialis hypothalami, nucleus paraventricularis magnocellularis, nucleus perventricularis hypothalami, nucleus infundibuli hypothalami and the nucleus ventromedialis hypothalami, were activated as evident by increased c-Fos immunoreactivity. Central alytesin did not cause increased behaviors that were unrelated to ingestion and did not cause anxiety-related behavior patterns. Additionally, central alytesin did not affect pecking efficacy. We conclude that both ICV and peripheral alytesin injections induce anorexigenic effects in chicks, and the hypothalamus is involved. While the anorexigenic effects of alytesin and bombesin appear to be conserved across species, the two peptides may differ in other behavioral responses and central mechanisms of action.

Central visfatin causes orexigenic effects in chicks.

Intracerebroventricular injection of visfatin caused increased feed intake and pecking efficiency, but did not affect water intake in chicks. Visfatin-treated chicks had increased c-Fos immunoreactivity in the lateral hypothalamus, decreased reactivity in the ventromedial hypothalamus and the dorsomedial hypothalamus, infundibular nucleus, periventricular nucleus, paraventricular nucleus were not affected. A low dose of visfatin increased locomotion. We conclude that intracerebroventricular injection of visfatin causes orexigenic effects in chicks.

Anorexigenic effects of central neuropeptide S involve the hypothalamus in chicks (Gallus gallus).

Neuropeptide S (NPS) affects appetite-related processes in mammals. However, its role in avian biology is unreported. We hypothesized that intracerebroventricular (ICV) NPS would cause anorexigenic effects in chicks (Gallus gallus). To evaluate this, Cobb-500 chicks were centrally injected with multiple doses (0, 0.313, 0.625 and 1.250 mug) of NPS. NPS-treated chicks responded with decreased feed and water intake. The effect on water intake was secondary to feed intake, because fasted NPS-treated chicks did not reduce water intake. ICV NPS injection also reduced plasma corticosterone concentration. We monitored behavior and found decreased ingestive and exploratory pecking, jumping, locomotion, and increased time spent in deep rest. We hypothesized that the anorexigenic effects were hypothalamic in origin and quantified c-Fos reactivity in the lateral hypothalamus (LH), paraventricular nucleus (PVN) and ventromedial hypothalamus (VMH) after NPS treatment. NPS was associated with decreased c-Fos reactivity in the LH, increased reactivity in the PVN and had no effect in the VMH. When NPS was injected directly into the LH and PVN, chicks responded with decreased feed and water intake, suggesting that effects were directly mediated by these nuclei. We conclude that ICV NPS causes anorexigenic effects in chicks, without directly affecting water intake, and the hypothalamus is involved.