Early life diet containing prebiotics and bioactive whey protein fractions increased dendritic spine density of rat hippocampal neurons.

Early life nutrition plays an important role in brain development. Emerging research in rodents, piglets and humans suggest that prebiotics, milk fat globule membrane and lactoferrin may each play unique roles in brain development and cognitive functions. However, knowledge of their combined impact is lacking. We show here that providing weanling rats with a diet containing milk fat globule membrane, lactoferrin and a polydextrose/galactooligosaccharide prebiotic blend led to a significant increase in total dendritic spine density in hippocampal dentate gyrus neurons. Region-specific alterations in dendritic spine density and morphology could provide a mechanistic basis underlying broader cognitive benefits, but further research is required to demonstrate functional consequences of these observations.

Neurotoxic methamphetamine regimens produce long-lasting changes in striatal G-proteins.

Animals repeatedly dosed with methamphetamine during a single day suffer damage to brain dopamine and serotonin terminals and show behavioral deficits. These methamphetamine regimens also produce long-term reductions in dopamine agonist-stimulated immediate-early gene responses both in striatum and several cortical areas, but the mechanism(s) underlying these long-lasting effects of methamphetamine remain uncertain. Six weeks after a neurotoxic regimen of methamphetamine (4 × 4 mg/kg) or saline, α subunit levels of striatal G-proteins that couple dopamine receptors to second messenger systems were measured. Because the damage to striatal monoamine terminals produced by methamphetamine is regionally heterogeneous, we used radioimmunocytochemistry, which combines quantification with regional resolution. We found significant increases in G(iα) and G(olfα) expression in the ventral striatum (but not in the dorsolateral striatum or nucleus accumbens) of methamphetamine-pretreated rats, a regional pattern similar to that reported for methamphetamine effects on dopamine terminal markers. By contrast, G(qα) expression was unaffected in all striatal subregions. The central roles of G(i) and G(olf) in modulating the activity of a series of interlinked intracellular signaling pathways suggest that methamphetamine-induced changes in G(i) and G(olf) can have lasting effects on striatal neuronal function.

A sensitizing D-amphetamine dose regimen induces long-lasting spinophilin and VGLUT1 protein upregulation in the rat diencephalon.

Numerous studies in this lab and others have reported psychostimulant-induced alterations in both synaptic protein expression and synaptic density in striatum and prefrontal cortex. Recently we have shown that chronic D-amphetamine (D-AMPH) administration in rats increased synaptic protein expression in striatum and limbic brain regions including hippocampus, amygdala, septum, and paraventricular nucleus of the thalamus (PVT). Potential synaptic changes in thalamic nuclei are interesting since the thalamus serves as a gateway to cerebral cortex and a nodal point for basal ganglia influences. Therefore we sought to examine drug-induced differences in synaptic protein expression throughout the diencephalon. Rats received an escalating (1-8 mg/kg) dosing regimen of D-AMPH for five weeks and were euthanized 28 days later. Radioimmunocytochemistry (RICC) revealed significant upregulation of both spinophilin and the vesicular glutamate transporter, VGLUT1, in PVT, mediodorsal (MD), and ventromedial (VM) thalamic nuclei as well as in lateral hypothalamus (LH) and habenula. Strong positive correlations were observed between VGLUT1 and spinophilin expression in PVT, medial habenula, MD, VM and LH of D-AMPH-treated rats. No significant D-AMPH effect was seen in sensorimotor cortices for either protein. Additionally, no significant differences in the general vesicular protein synaptophysin were observed for any brain region. These findings add to evidence suggesting that long-lasting stimulant-induced synaptic alterations are widespread but not ubiquitous. Moreover, they suggest that D-AMPH-induced synaptic changes may occur preferentially in excitatory synapses.

A sensitizing d-amphetamine regimen induces long-lasting spinophilin protein upregulation in the rat striatum and limbic forebrain.

Structural studies have shown that chronic regimens of psychostimulants increase dendritic spine number in the rat striatum. The present study used Western blotting and radioimmunocytochemistry to examine psychostimulant-induced changes in the levels of spinophilin, a protein found abundantly in dendritic spines. Spinophilin determinations were conducted in striatum as well as several other subcortical regions implicated in psychostimulant-induced neuroplasticity. Rats received an escalating (1-8 mg/kg) dosing regimen of d-amphetamine (twice daily, i.p.) for 5 weeks, were tested for locomotor sensitization, and were killed 28 days later. This amphetamine dosing regimen was found to induce a significant sensitization of locomotor activity in these animals. Using both Western blotting and radioimmunocytochemistry, spinophilin protein was found to be upregulated in the striatum of amphetamine-treated rats. In addition, radioimmunocytochemistry revealed that spinophilin was increased in the septum, hippocampus, amygdala and the cingulate cortex, and was unchanged in sensorimotor cortices. Because it binds to F-actin and protein phosphatase-1, spinophilin has been proposed as a protein linking synaptic transmission to changes in spine morphology. Radioimmunocytochemistry for spinophilin provides a novel approach to identification of brain regions whose neurons undergo dendritic change after chronic exposure to drugs of abuse.