Merylin Zizza

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.

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.

Aestivation and hypoxia-related events share common silent neuron trafficking processes

BackgroundThe availability of oxygen is a limiting factor for neuronal survival since low levels account not only for the impairment of physiological activities such as sleep-wake cycle, but above all for ischemic-like neurodegenerative disorders. In an attempt to improve our knowledge concerning the type of molecular mechanisms operating during stressful states like those of hypoxic conditions, attention was focused on eventual transcriptional alterations of some key AMPAergic silent neuronal receptor subtypes (GluR1 and GluR2) along with HSPs and HIF-1α during either a normoxic or a hypoxic aestivation of a typical aquatic aestivator, i.e. the lungfish (Protopterus annectens).ResultsThe identification of partial nucleotide fragments codifying for both AMPA receptor subtypes in Protopterus annectens displayed a putative high degree of similarity to that of not only fish but also to those of amphibians, birds and mammals. qPCR and in situ hybridization supplied a very high (p < 0.001) reduction of GluR1 mRNA expression in diencephalic areas after 6 months of aerial normoxic aestivation (6mAE). Concomitantly, high (p < 0.01) levels of HSP70 mRNAs in hypothalamic, mesencephalic and cerebellar areas of both 6mAE and after 6 months of mud hypoxic aestivation (6mMUD) were detected together with evident apoptotic signals. Surprisingly, very high levels of GluR2 mRNAs were instead detected in thalamic along with mesencephalic areas after 6 days of normoxic (6dAE) and hypoxic (6dMUD) aestivation. Moreover, even short- and long-term hypoxic states featured high levels of HIF-1α and HSP27 transcripts in the different brain regions of the lungfish.ConclusionsThe distinct transcriptional variations of silent neurons expressing GluR1/2 and HSPs tend to corroborate these factors as determining elements for the physiological success of normoxic and hypoxic aestivation. A distinct switching among these AMPA receptor subtypes during aestivation highlights new potential adaptive strategies operating in key brain regions of the lungfish in relation to oxygen availability. This functional relationship might have therapeutic bearings for hypoxia-related dysfunctions, above all in view of recently identified silent neuron-dependent motor activity ameliorations in mammals.

Lead-induced neurodegenerative events and abnormal behaviors occur via ORXRergic/GABAARergic mechanisms in a marine teleost

The hindering effects of metals and in particular lead (Pb) are representing a growing threat to aquatic organisms such as fish. This observation derives from toxic concentrations of Pb accounting for altered neurophysiological activities of some interesting teleost models like Thalassoma pavo, a fish species highly known for its host-cleaning symbiosis. In this study, the nominal PbNO(3) concentration of 1.6 mg/L was capable of reducing feeding and resting bouts as early as 24 h of exposure while hyperactive swimming episodes were also detected. Such abnormal behaviors were tightly correlated to up-regulated orexin receptor (ORXR) mRNA expression levels in some brain areas such as the lateral thalamic nucleus (+213%) and the optic tectum (+90%) with respect to controls. Interestingly, these transcriptional effects seemed to be attenuated when Pb-exposed fish received either 100 ng/g of ORX-A (-70%) or 0.1 μg/g of γ-aminobutyric acid(A) receptor (GABA(A)R) agonist muscimol (MUS; -97%) compared to fish exposed to Pb alone. Moreover, a net neurodegenerative process of the different brain areas was reported after Pb exposure as displayed by their marked amino cupric silver stained cells while these cells were devoid of any staining reaction after treatment with MUS only. Conversely, addition of the GABA(A)R antagonist bicuculline (BIC; 1 μg/g) moderately (p<0.05) enhanced Pb-dependent behavioral and neurodegenerative actions. Overall, these first indications strongly point to altered ORXR/GABA(A)R interactions during neurotoxic events of a metal that by evoking harmful neurobiological dysfunctions may endanger the survival of commercially valuable fish with eventual repercussions on human health.

HSP90 and pCREB alterations are linked to mancozeb-dependent behavioral and neurodegenerative effects in a marine teleost

ABSTRACT The pesticide mancozeb (mz) is recognized as a potent inducer of oxidative stress due to its ability to catalyze the production of reactive oxygen species plus inhibiting mitochondrial respiration thus becoming an environmental risk for neurodegenerative diseases. Despite numerous toxicological studies on mz have been directed to mammals, attention on marine fish is still lacking. Thus, it was our intention to evaluate neurobehavioral activities of ornate wrasses (Thalassoma pavo) exposed to 0.2 mg/l of mz after a preliminary screening test (0.07–0.3 mg/l). Treated fish exhibited an evident (p < 0.001) latency to reach T‐maze arms (> 1000%) while exploratory attitudes (total arm entries) diminished (− 50%; p < 0.05) versus controls during spontaneous exploration tests. Moreover, they showed evident enhancements (+ 111%) of immobility in the cylinder test. Contextually, strong (− 88%; p < 0.01) reductions of permanence in light zone of the Light/Dark apparatus along with diminished crossings (− 65%) were also detected. Conversely, wrasses displayed evident enhancements (160%) of risk assessment consisting of fast entries in the dark side of this apparatus. From a molecular point of view, a notable activation (p < 0.005) of the brain transcription factor pCREB occurred during mz‐exposure. Similarly, in situ hybridization supplied increased HSP90 mRNAs in most brain areas such as the lateral part of the dorsal telencephalon (Dl; + 68%) and valvula of the cerebellum (VCe; + 35%) that also revealed evident argyrophilic signals. Overall, these first indications suggest a possible protective role of the early biomarkers pCREB and HSP90 against fish toxicity. HIGHLIGHTSFish exposed to mancozeb exhibited an evident latency to reach T‐maze arms.Mancozeb caused immobility and reduction of explorative attitudes.Fish exposed to mancozeb showed anxiogenic performances in the Light/Dark apparatus.The brain of fish exposed to mancozeb supplied pCREB plus HSP90 mRNA up‐regulations.Some brain areas of fish exposed to mancozeb revealed an evident neurodegeneration.

Neurobehavioral alterations plus transcriptional changes of the heat shock protein 90 and hypoxia inducible factor-1α in the crucian carp exposed to copper

The various physiological alterations caused by copper (Cu) exposure in fish have attracted great interests toward neuronal strategies against Cu toxicity. Here, neurobehavioral activities (including anxiety-like behaviors) and transcriptional levels of heat shock protein (Hsp)90 and hypoxia inducible factor-1alpha (HIF-1α) were evaluated in the crucian carp (Carassius carassius) treated with nominal sub-lethal higher (1.45mg/L) and lower (0.30mg/L) concentrations of CuCl2. Both concentrations accounted for diminished swimming speed and food intake plus a strong preference for the dark side of the light/dark apparatus together with a reduction of crossings between the two compartments with respect to controls. Contextually, Hsp90 and HIF-1α transcripts were largely down- and up-regulated, respectively, in some brain areas such as in the medial part of the dorsal telencephalon (Dm, -52%) and in the ventral part of the ventral telencephalon (Vv, +68%). When carps were transferred to CuCl2-free water, some behaviors were rescued especially for fish previously exposed to 0.30mg/L concentration. In this same condition, Hsp90 mRNA levels were recuperated (-94%) in the medial preglomerular nucleus (NPGm) with respect to exposed fish while HIF-1α mRNA was mostly down-regulated in telencephalic stations. Moreover, recovery capacities of this extraordinary resistant fish was exhibited by evident reductions (-80%) of the dark argyrophilic granules such as in the ventral telencephalon (VTel). Overall, our results point to interesting responses against Cu toxicity involving Hsp90 and HIF-1α transcripts that may constitute early indicators of environmental stressors leading to the repair of metal-induced damages in fish with notable brain plasticity properties.

ORX Neuroreceptor System and HSP90 Are Linked to Recovery Strategies Against Copper Toxicity in Thalassoma pavo

Fish are particularly sensitive to copper (Cu) because although it is an essential metal, it becomes dangerous for aquatic ecosystems, thus accounting for physiological alterations. In this study, we investigated Cu effects on neurobehavioral activities of Thalassoma pavo and, above all, its recovery strategies by evaluating behavioral disturbances, neurodegeneration, and expression of heat shock protein (HSP)90 and orexin receptor (ORXR). Ornate wrasses exposed to nominal sublethal higher (1.07 mg/l) and lower (0.25 mg/l) concentrations of CuCl₂·H₂O mostly reduced swimming and feeding activities along with inducing abnormal behaviors in a dose-dependent manner. Concomitantly, ORXR transcripts were mostly upregulated in the diffuse nucleus of the inferior lobe (NDLI, + 142%) and the corpus of the cerebellum (CCe, + 243%), whereas HSP90 was downregulated only in lateral part of the dorsal telencephalon (Dl, -35%), the nucleus glomerulosus (NG; -40%), and the optic tectum (OT; -33%). Interestingly, when fish were transferred to Cu-free water, some behaviors were promptly rescued, especially in fish previously exposed to the lower Cu concentration. This rescuing tendency was confirmed by evident reductions of argyrophilic signals in Dl (-67%), NG (-31%), and OT (-42%) of fish exposed to 0.25 mg/l Cu. Moreover, transcriptional events of both ORXR and HSP90 were further upregulated in order to orchestrate a reactivation of behavioral and neuronal functions. Overall, this study highlights, for the first time, new neuronal strategies against environmental adverse conditions involving both ORXergic system and HSP90 as key elements that may assure, at least in part, protection and recovery processes against toxic agents.

Orexin-A influences mRNA expression of some glutamatergic receptor subtypes in Carassius auratus (Actinopterygii: Cyprinidae)

Abstract At date, studies are beginning to show that ionotropic glutamate receptors (iGluRs) are influenced by the orexin/hypocretin (ORX) system during the regulation of several physiological functions in mammals. In this study, we showed that the effects of ORX-A and specific glutamatergic antagonists (3-(+)-2-carboxypiperazin-4-yl-propyl-1-phosphonate, CPP/cyano-7-nitro-quinoxaline-2,3-dione, CNQX) on the expression of NMDAR (NR1) and AMPAR (GluR2) subtype genes underlie a tight relationship of the ORXergic system with iGluRs in the teleost Carassius auratus (goldfish; Linnaeus, 1758). The application of specific primers for NR1 and GluR2 permitted us to identify two partial coding sequences (cds) of 115 bp and 90 bp that were highly similar (97% and 81%, respectively) to the related sequences of the rat (Rattus norvegicus). These cds were used to carry out a semi-quantitative RT-PCR (reverse transcription-polymerase chain reaction) in which a differentiated expression pattern of NR1 and GluR2 was obtained following drug treatments. Interestingly, goldfish treated with ORX-A showed a significant (p < 0.001) up-regulation of NR1 expression (∼120%) while GluR2 was only moderately up-regulated (+45%; p < 0.05) with respect to controls. As far as CPP effects were concerned, this NMDAR antagonist strongly blocked (–72%; p < 0.01) NR1 expression while CNQX did not account for any significant variation with respect to controls. Moreover, the contextual administration of ORX-A+CPP continued to provide a blocking effect on NR1 expression, especially when compared to ORX-A-treated fish (–98%). On the other hand, ORX-A+CNQX caused an up-regulated trend even though of a lesser extent with respect to ORX-A-treated fish (–44%). Regarding GluR2, only the AMPAR antagonist moderately blocked (–38%) its expression, an effect that was completely abolished in the presence of ORX-A. Overall, results of the present study highlight, for the first time, a prevalent up-regulatory role of ORX-A on NMDAR subtype mRNA expression in fish.

Reduced learning and memory performances in high-fat treated hamsters related to brain neurotensin receptor1 expression variations

HighlightsHigh fat diet modifies NOR (recognition) and CPP (reward) performances.Feeding behaviors and body weight alterations in hyperlipidemic hamsters.Elevated lipid and glucose blood levels were caused by high fat diet.Neurotensin receptor expression variations in limbic areas due to high fat diet. ABSTRACT Recent indications are suggesting that high fat and sugar‐enriched foods do not only evoke harmful physiological conditions, but they also endure evident structural alterations in cerebral regions controlling cognitive and feeding behaviors. Food consumption plus neuronal energy regulatory mechanisms seem to constitute a complex system assuring that food calories do not exceed body requirements. At the same time obesogenic‐related properties of limbic feeding stations like the hypothalamus (HTH), hippocampus (HIP) and amygdala (AMY) tend to control eating habits through the interaction of distinct neuropeptides. For this purpose, it was our intention to correlate expression differences of a key anti‐obesogenic neuropeptide receptor i.e. neurotensin1 (NTR1) on mnemonic performances in the hibernating hamster (Mesocricetus auratus) exposed to a high fat diet (HFD). Interestingly, these hamsters exhibited a notable enhanced (p < 0.01) body weight from the fifth on to the twelfth week of treatment, which was accompanied by elevated blood lipid cholesterolo and triglycerides and glucose levels. At the same time these hamsters provided diminished locomotor activities such as exploratory bouts, rearing and grooming behaviors. Of greater relevance was their very extreme (p < 0.001) inability of identifying new objects during novel object recognition (NOR) tests along with not having correctly chosen the chamber of the conditioned place preference (CPP) apparatus, which contained the gratifying reward. Surprisingly the altered behavioral plus mnemonic tasks of HFD hamsters were tightly related to elevated NTR1 expression changes in the above limbic sites thus proposing this neuronal system as a highly probable alternative for treating obesity‐dependent mnemonic dysfunctions.

Probiotics modify body weight together with anxiety states via pro-inflammatory factors in HFD-treated Syrian golden hamster

&NA; Emerging studies are beginning to suggest that emotional states together with healthful measures constitute pertinent features of our lifestyle in which bad eating habits but more importantly what our gut has to host are causing great concern. It is well known that humans have established mutual relationships with a wide array of colonized microbes (collectively called gut microbiota) consisting of bacteria, fungi, eukaryotic parasites and viruses. The gut microbiota has exhibited a notable ability of communicating with the brain via a two‐way system that includes the vagus nerve, immune sites, and a number of neurotransmitters. Interestingly, stressful along with obesity, cognitive, and brain developmental states are strongly influenced by microbiota homeostatic conditions. It was our aim to investigate behavioral and obesity effects evoked by treatment with probiotics via neuroinflammatory factors and namely IL‐1&bgr;, NLRP3, Caspase‐1 and NF‐kB levels in the Syrian golden hamster. Following treatment with a high‐fat diet (HFD), in the presence or absence of a multi‐species probiotic formulation, hamsters were exposed to an unpredictable chronic mild stress (UCMS) test for 4 weeks. Independently of the diet, probiotics treatment markedly reduced stress‐like behaviors in the different mazes. Moreover, probiotics decreased hypothalamic expression levels of the pro‐neuroinflammatory factors like IL‐1&bgr;, NLRP3, Caspase‐1 and NF‐kB, whereas HFD increased them. Contextually, they decreased plasmatic levels of IL‐1&bgr;, NLRP3 and caspase‐1 but not NF‐kB. Our findings clearly support probiotics as a potentially valuable treatment strategy in obesity and anxiety, thereby proposing them for clinical treatments in patients with metabolic and mood disorders.