Marcello Canonaco

Amygdalar orexinergic-GABAergic interactions regulate anxiety behaviors of the Syrian golden hamster.

At present neurobiological interests are directing more attention towards the major role of the amygdalar GABA(A) receptor on orexin-dependent behaviors. This telencephalic region has been widely studied especially in view of its control on various psychiatric disorders such as anxiety and depression. Recently, cross-talking relationships between these two specific neuroreceptor systems of the central-cortical amygdalar complex has been considered an important element for anxiety type of behaviors. In the present study, we investigated the effects of central amygdalar infusions with orexin-A, orexin-B±GABA(A) receptor α₂ subunit agonist (flunitrazepam) on elevated plus-maze and light-dark explorative behaviors of the facultative hibernating Syrian hamster. In a first case, it seemed that doses of orexin administered directly into the central nucleus were responsible for greater anxiogenic type of effects as shown by more time being spent both in the dark compartment and the closed arm of the elevated plus-maze, whereas, these effects were suppressed in the presence of flunitrazepam. At the cellular level, the effects of orexin accounted for evident argyrophilic reactions (neurodegeneration phenomena) including altered cell membrane and loss of cytoplasmic architecture in most amygdalar and hippocampal neuronal fields, while in the presence of flunitrazepam these reactions resulted to either be unappreciable or absent. Overall the actions of α₂-dependent inhibitory signals tend to corroborate, for the first time, a neuroprotective role against the over-excitatory orexinergic neurodegeneration reactions and thus its abnormal anxiety-like indications may prove to be therapeutically useful for orexin-dependent sleeping disorders.

Influence of micro-patterned PLLA membranes on outgrowth and orientation of hippocampal neurites

In neuronal tissue engineering many efforts are focused on creating biomaterials with physical and chemical pathways for controlling cellular proliferation and orientation. Neurons have the ability to respond to topographical features in their microenvironment causing among others, axons to proliferate along surface features such as substrate grooves in micro-and nanoscales. As a consequence these neuronal elements are able to correctly adhere, migrate and orient within their new environment during growth. Here we explored the polarization and orientation of hippocampal neuronal cells on nonpatterned and micro-patterned biodegradable poly(l-lactic acid) (PLLA) membranes with highly selective permeable properties. Dense and porous nonpatterned and micro-patterned membranes were prepared from PLLA by Phase Separation Micromolding. The micro-patterned membranes have a three-dimensional structure consisting of channels and ridges and of bricks of different widths. Nonpatterned and patterned membranes were used for hippocampal neuronal cultures isolated from postnatal days 1-3 hamsters and the neurite length, orientation and specific functions of cells were investigated up to 12 days of culture. Neurite outgrowth, length plus orientation tightly overlapped the pattern of the membrane surface. Cell distribution occurred only in correspondence to membrane grooves characterized by continuous channels whereas on membranes with interconnected channels, cells not only adhered to and elongated their cellular processes in the grooves but also in the breaking points. High orientation degrees of cells were determined particularly on the patterned porous membranes with channel width of 20 mum and ridges of 17 mum whereas on dense nonpatterned membranes as well as on polystyrene culture dish (PSCD) controls, a larger number of primary developed neurites were distributed. Based on these results, PLLA patterned membranes may directly improve the guidance of neurite extension and thereby enhancing their orientation with a consequently highly ordered neuronal cell matrix, which may have strong bearings on the elucidation of regeneration mechanisms.

Some environmental contaminants influence motor and feeding behaviors in the ornate wrasse (Thalassoma pavo) via distinct cerebral histamine receptor subtypes.

Common environmental contaminants such as heavy metals and pesticides pose serious risks to behavioral and neuroendocrine functions of many aquatic organisms. In the present study, we show that the heavy metal cadmium and the pesticide endosulfan produce such effects through an interaction of specific cerebral histamine receptor subtypes in the teleost ornate wrasse (Thalassoma pavo). Treatment of this teleost with toxic cadmium levels for 1 week was sufficient to induce abnormal swimming movements, whereas reduced feeding behaviors were provoked predominantly by elevated endosulfan concentrations. In the brain, these environmental contaminants caused neuronal degeneration in cerebral targets such as the mesencephalon and hypothalamus, damage that appeared to correlate with altered binding levels of the three major histamine receptors (subtypes 1, 2, and 3). Although cadmium accounted for reduced binding activity of all three subtypes in most brain regions, it was subtype 2 that seemed to be its main target, as shown by a very great (p < 0.001) down-regulation in mesencephalic areas such as the stratum griseum central layer. Conversely, endosulfan provided very great and great (p < 0.01) up-regulating effects of subtype 3 and 1 levels, respectively, in preoptic-hypothalamic areas such as the medial part of the lateral tuberal nucleus, and in the suprachiasmatic nucleus. These results suggest that the neurotoxicant-dependent abnormal motor and feeding behaviors may well be tightly linked to binding activities of distinct histamine subtypes in localized brain regions of the Thalassoma pavo.

Steroid hormones and receptors of the GABAA supramolecular complex. I: Benzodiazepine receptor level changes in some extrahypothalamic brain areas of the female rat following sex steroid treatment

The effects of sex steroid hormones on the different receptor binding sites of the GABAA molecule remain unclear. In this report we have demonstrated, using autoradiography techniques, that the distribution pattern of the benzodiazepine receptors (a component of the GABAA molecule) in some extrahypothalamic brain regions is altered by both in vivo and in vitro sex steroid hormone treatment. In vivo administration of the sex steroids estradiol and progesterone induced a significant change in [3H]flunitrazepam (benzodiazepine agonist) binding levels in the amygdala, and cortico and posterior brain nuclei of the female rat. In fact, elevated and diminished receptor-binding levels were obtained in the corticomedial amygdala nucleus and in the pontine central gray matter respectively, following the administration of estradiol. Significant hormonal effects were also shown for animals that received only a progesterone dose, as demonstrated by the increased and decreased receptor levels in the basolateral amygdala nucleus and cortex lamina VI and in the substantia nigra pars reticulata, respectively. It was interesting, at this point, to investigate whether the hormone effects on [3H]flunitrazepam binding changes might be mediated through a GABA-dependent activity, because the benzodiazepine and GABAA receptors are coupled to a chloride ion channel in an allosteric manner. When 50 microM GABA was added to the incubation medium, substantially altered binding levels were recorded in animals that received progesterone replacement therapy only. The GABA-induced progesterone effects both increased substantially the binding levels in the oriens-pyramidalis CA1 layer of the hippocampus and in the intermediate gray layer of the superior colliculus as well as reducing receptor levels in the substantia nigra pars reticulata.(ABSTRACT TRUNCATED AT 250 WORDS)

A sexually dimorphic distribution pattern of the novel estrogen receptor G-protein-coupled receptor 30 in some brain areas of the hamster

The isolation of the G-protein-coupled receptor 30 (GPR30), an orphan membrane receptor unrelated to nuclear estrogen receptors (ERs), has become a key factor towards the unraveling of rapid estrogen action. This membrane receptor together with cellular signaling intermediaries, i.e., extracellular signal-dependent kinases 1 and 2, may promote neuronal proliferation and differentiation activities. In the present study, an evident gene expression pattern of GPR30 characterized postnatal 7 (young) and 60 (adult) days of age hamsters as shown by its heterogeneous mRNA distribution in hypothalamic, amygdalar and cerebellar areas of both sexes. In particular, most of the brain areas considered in the adult hamster plus only the amygdala and cerebellum of young animals behaved in a sexually dimorphic fashion. This similar pattern was also detected for the ERalpha and beta, as shown by the latter receptor prevailing in young and adult females, while the former predominated in young females. Even for the two kinases, a sexually dimorphic distribution was featured above all for young hamsters. Overall, the findings of the present study established a distinct expression pattern of the novel ER (GPR30) that may operate differently in some brain areas of the hamster and this may provide interesting insights regarding its probable neuroprotective role during the execution of some hibernating states, which are typical of our rodent model.

Feeding behaviors and ORXR–β-GABAAR subunit interactions in Carassius auratus

Orexins are one of the most potent orexigenic factors in fish that through their interaction with the GABA(A) receptor system assures the successful execution of feeding, motor and sleep-wake activities. In the present study, the effects of ORX-A (10ng/g BW) very greatly enhanced (p<0.001) the time spent in feeding behaviors while at the same time moderately increased (p<0.05) food intake of the goldfish. It is worthy to note that the great variations of time spent in feeding behaviors induced by β GABA(A)R agonist (muscimol, MUS) and antagonist (bicuculline, BIC) did not result to be correlated to any significant variations of food intake. It was, however, a T-maze study allowing us to establish that learning and mnemonic events very likely also operated in an ORX-A+GABA(A)R-dependent fashion in our fish model. Indeed, animals conditioned by red/blue lights greatly reduced latency time in the presence of ORX-A while neither MUS nor BIC alone modified such a parameter, with the exception of ORX-A+MUS being responsible for a moderate decrease of latency time with respect to conditioned fish treated with a saline solution. Conversely, ORX-A+MUS/BIC seemed to interfere with ORX-A actions as shown by their very great increase in latency time. Moreover, T-maze results appeared to be strengthened by evident ORXR transcriptional variations especially by the very great mRNA densities detected in some telencephalic regions of animals treated with ORX-A. Of all telencephalic regions Dl, considered homologous to the mammalian hippocampus, proved to be a major target for ORX-A effects. Overall, these data suggest that it is mainly the ORXergic system that promotes feeding behaviors via reward pathways in teleost fish as in mammals. Surprisingly, β GABA(A)R drugs did not modify such behaviors when given alone while the inhibitory effect on cognitive/reward processes was evoked when given together with ORX-A, suggesting that more than β subunits other GABA(A)R subunits could be promoting mnemonically guided motor behaviors.

Different binding activities of A- and B-type natriuretic hormones in the heart of two Antarctic teleosts, the red-blooded Trematomus bernacchii and the hemoglobinless Chionodraco hamatus☆

Different binding activities of 125I-rat atrial natriuretic peptide were evaluated using in vitro quantitative autoradiography in the heart of two antarctic notothenioid teleosts, the red-blooded Trematomus bernacchii and hemoglobinless Chionodraco hamatus. Saturable and specific binding sites for rat atrial natriuretic peptide were found in the atrium, ventricular myocardium, ventricular endocardium and inner and outer layers of the bulbus arteriosus of both fishes. Scatchard analysis of the saturation data showed that the atrium, ventricular endocardium and outer bulbar layer of T. bernacchii were characterized by a single class of high affinity natriuretic peptide binding sites (Kd = 14 ± 3.2, 9.7 ± 2.3 and 6.2 ± 1.3 pM, respectively), whereas the ventricular myocardium and the inner bulbar layer contained elevated numbers of two classes of high and low affinity natriuretic peptide binding sites (1.8 ± 0.6 < Kd < 209 ± 66 pM). In contrast, in C. hamatus, both high and low affinity binding sites were detected in all cardiac regions (2.1 ± 0.7 < Kd < 262 ± 90 pM). In both fishes, competition experiments in the presence of either unlabeled rat atrial natriuretic peptide or porcine brain natriuretic peptide indicated different displacement capacities. Porcine brain natriuretic peptide, able to bind to natriuretic peptides sites in all the heart regions of both notothenioids, provided a higher displacement capacity with respect to that of rat atrial natriuretic peptide in the atrium of T. bernacchii.

Distinct alpha subunits of the GABAA receptor are responsible for early hippocampal silent neuron-related activities.

The modulatory actions of GABAA receptor subunits are crucial for morphological and transcriptional neuronal activities. In this study, growth of hamster hippocampal neurons on biohybrid membrane substrates allowed us to show for the first time that the two major GABAA α receptor subunits (α2,5) are capable of early neuronal shaping plus expression differences of some of the main neuronal cytoskeletal factors (GAP‐43, the neurotrophin––BDNF) and of Gluergic subtypes. In a first case the inverse α5 agonist (RY‐080) seemed to account for the reduction of dendritic length at DIV7, very likely via lower BDNF levels. Conversely, the effects of the preferentially specific agonist for hippocampal α2 subunit (flunitrazepam) were, instead, directed at the formation of growth cones at DIV3 in the presence of greatly (P < 0.01) diminished GAP‐43 levels as displayed by strongly reduced axonal sprouting. It is interesting to note that concomitantly to these morphological variations, the transcription of some Gluergic receptor subtypes resulted to be altered. In particular, flunitrazepam was responsible for a distinctly rising expression of axonal NR1 mRNA levels from DIV3 (P < 0.01) until DIV7 (P < 0.001), whereas RY‐080 evoked a very great (P < 0.001) downregulation of dendritic GluR2 at only DIV7. Together, our results demonstrate that GABAA α2,5 receptor‐containing subunits by regulating the precise synchronization of cytoskeletal factors are considered key modulating neuronal elements of hippocampal morphological growth features. Moreover, the notable NR1 and GluR2 transcription differences promoted by these GABAA α subunits tend to favorably corroborate the early role of α2 + α5 on hippocampal neuronal networks in hibernating rodents through the recruitment and activation of silent neurons, and this may provide useful insights regarding molecular neurodegenerative events.

α GABAA subunit-orexin receptor interactions activate learning/motivational pathways in the goldfish

Orexins (ORXs) cross-talking with γ-aminobutyric acid(A) receptor (GABA(A)R) is beginning to constitute a key neuronal signaling feature responsible for the successful promotion of sleep-wake cycle, feeding and motor behaviors plus reward/motivational activities. In this work, ORX-A and the two α GABA(A)R agonists (zolpidem, ZOL; diazepam, DZP) accounted for very great (p<0.001) increases of feeding while only DZP elicited great (p<0.01) levels of food intake in the goldfish (Carassius auratus). It was, however, T-maze and conditioned place preference (CPP) methods that allowed us to specifically establish learning/reward-related events operating in an ORX-A+GABA(A)R-dependent fashion in our experimental model. T-maze data showed that conditioned ORX-A treated-fish were capable of reaching the red/blue chamber and ingesting their food reward in a very greatly reduced latency time with respect to untreated conditioned fish while DZP and ZOL greatly and moderately (p<0.05) reduced their latency time, respectively. Regarding CPP study, conditioned ORX-A- and DZP-treated animals showed comparably greater preferences for the conditioned compartment that became even greater in ORX-A+DZP-treated fish. Surprisingly, ORX receptor expression of the telencephalon was preferentially activated by ORX-A treatments while diencephalic/mesencephalic structures and namely the tuberculum posterioris (TPp) were more sensitive to DZP especially following treatment with ORX-A+DZP. Overall, behavioral performances along with ORX receptor transcriptional properties tend to point to α GABA(A)R agonists as enhancers of palatability while the ORXergic system constitutes a crucial link between satiety-related and cognitive centers through the activation of TPp thus proposing this ascending dopaminergic system as a key target of learning/reward processes in fish.

GABAergic influences on ORX receptor-dependent abnormal motor behaviors and neurodegenerative events in fish.

At date the major neuroreceptors i.e. gamma-aminobutyric acid(A) (GABA(A)R) and orexin (ORXR) systems are beginning to be linked to homeostasis, neuroendocrine and emotional states. In this study, intraperitoneal treatment of the marine teleost Thalassoma pavo with the highly selective GABA(A)R agonist (muscimol, MUS; 0.1 microg/g body weight) and/or its antagonist bicuculline (BIC; 1 microg/g body weight) have corroborated a GABA(A)ergic role on motor behaviors. In particular, MUS induced moderate (p<0.05) and great (p<0.01) increases of swimming towards food sources and resting states after 24 (1 dose) and 96 (4 doses) h treatment sessions, respectively, when compared to controls. Conversely, BIC caused a very strong (p<0.001) reduction of the former behavior and in some cases convulsive swimming. From the correlation of BIC-dependent behavioral changes to neuronal morphological and ORXR transcriptional variations, it appeared that the disinhibitory action of GABA(A)R was very likely responsible for very strong and strong ORXR mRNA reductions in cerebellum valvula and torus longitudinalis, respectively. Moreover these effects were linked to evident ultra-structural changes such as shrunken cell membranes and loss of cytoplasmic architecture. In contrast, MUS supplied a very low, if any, argyrophilic reaction in hypothalamic and mesencephalic regions plus a scarce level of ultra-structural damages. Interestingly, combined administrations of MUS+BIC were not related to consistent damages, aside mild neuronal alterations in motor-related areas such as optic tectum. Overall it is tempting to suggest, for the first time, a neuroprotective role of GABA(A)R inhibitory actions against the overexcitatory ORXR-dependent neurodegeneration and consequently abnormal swimming events in fish.