Brain Metabolic DNA: A Long Story and Some Conclusions.

We have previously outlined the main properties of brain metabolic DNA (BMD) and its involvement in circadian oscillations, learning, and post-trial sleep. The presence of BMD in certain subcellular fractions and their behavior in cesium gradients have suggested that BMD originates from cytoplasmic reverse transcription and subsequently acquires a double-stranded configuration. More recently, it has been reported that some DNA sequences of cytoplasmic BMD in learning mice are different from that of the control animals. Furthermore, BMD is located in vicinity of the genes involved in different modifications of synaptic activity, suggesting that BMD may contribute to the brain's response to the changing environment. The present review outlines recent data with a special emphasis on reverse transcription of BMD that may recapitulate the molecular events at the time of the "RNA world" by activating mitochondrial telomerase and generating RNA templates from mitochondrial transcripts. The latter unexpected role of mitochondria is likely to promote a better understanding of mitochondrial contribution to cellular interactions and eukaryotic evolution. An initial step regards the role of human mitochondria in embryonic BMD synthesis, which is exclusively of maternal origin. In addition, mitochondrial transcripts involved in reverse transcription of BMD might possibly reveal unexpected features elucidating mitochondrial involvement in cancer events and neurodegenerative disorders.

Brain metabolic DNA: recent evidence for a mitochondrial connection.

This review highlights recent data concerning the synthesis of brain metabolic DNA (BMD) by cytoplasmic reverse transcription and the prompt acquisition of the double-stranded configuration that allows its partial transfer to nuclei. BMD prevails in the mitochondrial fraction and is present in presynaptic regions and astroglial processes where it undergoes a turnover lasting a few weeks. Additional data demonstrate that BMD sequences are modified by learning, thus indicating that the modified synaptic activity allowing proper brain responses is encoded in learning BMD. In addition, several converging observations regarding the origin of BMD strongly suggest that BMD is reverse transcribed by mitochondrial telomerase.

Genetic Up-Regulation or Pharmacological Activation of the Na+/Ca2+ Exchanger 1 (NCX1) Enhances Hippocampal-Dependent Contextual and Spatial Learning and Memory.

The Na+/Ca2+ exchanger 1 (NCX1) participates in the maintenance of neuronal Na+ and Ca2+ homeostasis, and it is highly expressed at synapse level of some brain areas involved in learning and memory processes, including the hippocampus, cortex, and amygdala. Furthermore, NCX1 increases Akt1 phosphorylation and enhances glutamate-mediated Ca2+ influx during depolarization in hippocampal and cortical neurons, two processes involved in learning and memory mechanisms. We investigated whether the modulation of NCX1 expression/activity might influence learning and memory processes. To this aim, we used a knock-in mouse overexpressing NCX1 in hippocampal, cortical, and amygdala neurons (ncx1.4over) and a newly synthesized selective NCX1 stimulating compound, named CN-PYB2. Both ncx1.4over and CN-PYB2-treated mice showed an amelioration in spatial learning performance in Barnes maze task, and in context-dependent memory consolidation after trace fear conditioning. On the other hand, these mice showed no improvement in novel object recognition task which is mainly dependent on non-spatial memory and displayed an increase in the active phosphorylated CaMKIIα levels in the hippocampus. Interestingly, both of these mice showed an increased level of context-dependent anxiety.Altogether, these results demonstrate that neuronal NCX1 participates in spatial-dependent hippocampal learning and memory processes.

Brain metabolic DNA in memory processing and genome turnover.

Sophisticated methods are currently used to investigate the properties of brain DNA and clarify its role under physiological conditions and in neurological and psychiatric disorders. Attention is now called on a DNA fraction present in the adult rat brain that is characterized by an elevated turnover and is not involved in cell division or DNA repair. The fraction, known as brain metabolic DNA (BMD), is modulated by strain, stress, circadian oscillations, exposure to enriched or impoverished environment, and notably by several training protocols and post-trial sleep. BMD is frequently localized in glial cells but is also present in neurons, often in the perinucleolar region. Its distribution in repetitive and non-repetitive DNA fractions shows that BMD differs from native DNA and that in learning rats its profile differs from that of control rats. More detailed knowledge of the molecular, cellular, and time-dependent BMD features will be necessary to define its role in memory acquisition and processing and in the pathogenesis of neurologic disorders.

Intranasal Dopamine Reduces In Vivo [(123)I]FP-CIT Binding to Striatal Dopamine Transporter: Correlation with Behavioral Changes and Evidence for Pavlovian Conditioned Dopamine Response.

PURPOSE: Dopamine (DA), which does not cross the blood-brain barrier, has central and behavioral effects when administered via the nasal route. Neither the mechanisms of central action of intranasal dopamine (IN-DA), nor its mechanisms of diffusion and transport into the brain are well understood. We here examined whether IN-DA application influences dopamine transporter (DAT) binding in the dorsal striatum and assessed the extent of binding in relation to motor and exploratory behaviors. We hypothesized that, based on the finding of increased extracellular DA in the striatum induced by application of IN-DA, binding of [(123)I]FP-CIT to the DAT should be decreased due to competition at the receptor. METHODS: Rats were administered 3 mg/kg IN-DA and vehicle (VEH), with IN-DA injection either preceding or following VEH. Then motor and exploratory behaviors (traveled distance, velocity, center time, sitting, rearing, head-shoulder motility, grooming) were assessed for 30 min in an open field prior to administration of [(123)I]FP-CIT. DAT binding after IN-DA and VEH was measured with small animal SPECT 2 h following administration of the radioligand. RESULTS: (1) After IN-DA application, striatal DAT binding was significantly lower as compared to VEH, indicating that the nasally delivered DA had central action and increased DA levels comparable to that found previously with L-DOPA administration; and (2) DAT binding in response to intranasal VEH was lower when IN-DA application preceded VEH treatment. This finding is suggestive of Pavlovian conditioning of DA at the level of the DAT, since the DA treatment modified (decreased) the binding in response to the subsequent VEH treatment. VEH treatment also reduced motor and exploratory behaviors more when applied before, as compared to when it followed IN-DA application, also indicative of behavioral Pavlovian conditioning akin to that found upon application of various psychostimulant drugs. THE RESULTS: (a) demonstrate a direct central action of intranasally applied DA on the DAT in the dorsal striatum, indicating enhanced DA availability; and (b) provide first evidence of a Pavlovian conditioned DA response at the DAT. The latter results have relevance to understanding neurochemical mechanisms that underlie placebo action in the treatment of Parkinsonian patients.

Prepuberal stimulation of 5-HT7-R by LP-211 in a rat model of hyper-activity and attention-deficit: permanent effects on attention, brain amino acids and synaptic markers in the fronto-striatal interface.

The cross-talk at the prefronto-striatal interface involves excitatory amino acids, different receptors, transducers and modulators. We investigated long-term effects of a prepuberal, subchronic 5-HT7-R agonist (LP-211) on adult behaviour, amino acids and synaptic markers in a model for Attention-Deficit/Hyperactivity Disorder (ADHD). Naples High Excitability rats (NHE) and their Random Bred controls (NRB) were daily treated with LP-211 in the 5th and 6th postnatal week. One month after treatment, these rats were tested for indices of activity, non selective (NSA), selective spatial attention (SSA) and emotionality. The quantity of L-Glutamate (L-Glu), L-Aspartate (L-Asp) and L-Leucine (L-Leu), dopamine transporter (DAT), NMDAR1 subunit and CAMKIIα, were assessed in prefrontal cortex (PFC), dorsal (DS) and ventral striatum (VS), for their role in synaptic transmission, neural plasticity and information processing. Prepuberal LP-211 (at lower dose) reduced horizontal activity and (at higher dose) increased SSA, only for NHE but not in NRB rats. Prepuberal LP-211 increased, in NHE rats, L-Glu in the PFC and L-Asp in the VS (at 0.250 mg/kg dose), whereas (at 0.125 mg/kg dose) it decreased L-Glu and L-Asp in the DS. The L-Glu was decreased, at 0.125 mg/kg, only in the VS of NRB rats. The DAT levels were decreased with the 0.125 mg/kg dose (in the PFC), and increased with the 0.250 mg/kg dose (in the VS), significantly for NHE rats. The basal NMDAR1 level was higher in the PFC of NHE than NRB rats; LP-211 treatment (at 0.125 mg/kg dose) decreased NMDAR1 in the VS of NRB rats. This study represents a starting point about the impact of developmental 5-HT7-R activation on neuro-physiology of attentive processes, executive functions and their neural substrates.

Modulatory effects following subchronic stimulation of brain 5-HT7-R system in mice and rats.

The serotonin receptor 7 (5-HT7-R) plays important functional roles in learning and memory, in regulation of mood and circadian rhythmicity. LP-211 is a new selective agonist, belonging to 1-arylpiperazine category. We report studies aimed to evaluate the modulatory effect of a subchronic regimen on behavioral/molecular parameters. At low dose [0.25 mg/kg intraperitoneally (i.p.)], LP-211 induced a 6-h anticipated wake up in adult mice (with no temporal landmark by constant light), acting as nonphotic stimulus for 'internal clock' resetting. In standard 12:12-h light/dark cycle, a subchronic effect (5-6 days at 0.25 mg/kg, once per day) was observed: delayed wake up, reduced peak of locomotor activity and no evidence for brain cellular proliferation after ex vivo analysis. Other studies in rats were aimed to investigate long-term effects of developmental LP-211 administration into adulthood. Subchronic LP-211 (0.125 mg/kg i.p. once per day during the prepuberal phase) reduced l-glutamate, N-methyl-d-aspartate receptor 1 and dopamine transporter within the ventral striatum. With LP-211 (0.25 mg/kg i.p. once per day during the postpuberal phase), clear reductions were observed in the immunoreactivity of serotonin transporter and dopaminergic D2 receptors in the ventral and dorsal striatum, respectively. Subchronic LP-211 in rats and mice appears to be a suitable tool for studying the role of 5-HT7-R in sleep disorders, emotional/motivational regulations, attentive processes and executive functions.

Emotional and risk seeking behavior after prepuberal subchronic or adult acute stimulation of 5-HT7-Rs in Naples High Excitability rats.

We report here the results of studies aimed to investigate the involvement of serotonin receptor 7 subtype (5-HT7-R) in the modulation of emotional response in Naples High-Excitability (NHE) rat, a validated model for hyperactivity and impaired attention. A range of dosages (0.0, 0.125, 0.250, or 0.500 mg/kg) of LP-211, a selective agonist of 5-HT7-Rs, has been evaluated in animals at different age (adolescence and adulthood). Male NHE and random bred (NRB) control rats were tested in an Elevated Zero-Maze (EZM) after LP-211 treatment in two different regimens: at the issue of adolescent, subchronic exposure (14 intraperitoneal [i.p.] injections, once/day, pnd 31-44, tested on pnd 45--Exp. 1) or as adult, acute effect (15 min after i.p. injection--Exp. 2). Adolescent, subchronic LP-211 at 0.500 mg/kg dosage increased the frequency of head-dips only in NHE rats. Drug effect on time spent and entries in open EZM quadrants were revealed with adult, acute administration of 0.125 mg/kg LP-211 (both strains), indicating a tendency toward anxiolytic effects. In conclusion, data demonstrate that subchronic stimulation of 5-HT7-Rs during prepuberal period increases novelty-seeking/risk-taking propensity in NHE adults. These sequels are revealing increased disinhibition and/or motivation to explore in the NHE rats, which are characterized by a hyperactive dopaminergic system. These data may open new perspectives in studying mechanism of risk-seeking behavior.

Antidepressants share the ability to increase catecholamine output in the bed nucleus of stria terminalis: a possible role in antidepressant therapy?

RATIONALE: Antidepressants include a relatively wide spectrum of drugs that increase the synaptic concentration of monoamines, mostly through neurotransmitter reuptake blockade. The bed nucleus of stria teminalis (BNST) is considered a relay station in mediating the activation of stress response but also in the acquisition and expression of emotions. BNST is richly innervated by monoamines and sends back projections to the nucleus of origin. We previously showed that the administration of selective blockers of norepinephrine transporter (NET) increases the extracellular concentration (output) of dopamine, suggesting that dopamine could be captured by NET in the BNST. OBJECTIVES: The aim of this study, carried out by means of in vivo microdialysis, was to ascertain the acute effects that antidepressants with varying mechanisms of action have on dopamine and norepinephrine output in the BNST. RESULTS: We observed that all the antidepressants tested (5-20 mg/kg i.p.) increased the output of catecholamines, dose dependently. In particular, the maximum increases (as a percent of basal) for norepinephrine and dopamine respectively, were as follows: desipramine, 239 and 137; reboxetine, 185 and 128; imipramine, 512 and 359; citalopram, 95 and 122; fluoxetine, 122 and 68; bupropion, 255 and 164. CONCLUSIONS: These results suggest that catecholamine transmission in the BNST may be part of a common downstream pathway that is involved in the action mechanism of antidepressants. Consequently, it is hypothesized that a dysfunction of neuronal transmission in this brain area may have a role in the etiology of affective disorders.

Neurobehavioral adaptations to methylphenidate: the issue of early adolescent exposure.

Exposure to psychostimulants, including both abused and therapeutic drugs, can occur first during human adolescence. Animal modeling is useful not only to reproduce adolescent peculiarities but also to study neurobehavioral adaptations to psychostimulant consumption. Human adolescence (generally considered as the period between 9/12 and 18 years old) has been compared with the age window between postnatal days (pnd) 28/35 and 50 in rats and mice. These adolescent rodents display basal hyperlocomotion and higher rates of exploration together with a marked propensity for sensation-seeking and risk-taking behaviors. Moreover, peculiar responses to psychostimulants, including enhanced locomotor sensitization, no drug-induced stereotypy and reduced place conditioning have been described in adolescent rodents. During this age window, forebrain dopamine systems undergo profuse remodeling, thus providing a neuro-biological substrate to explain behavioral peculiarities observed during adolescence, as well as the reported vulnerabilities to several drugs. Further, methylphenidate (MPH, better known as Ritalin®), a psychostimulant extensively prescribed to children and adolescents diagnosed with attention-deficit/hyperactivity disorder (ADHD), raises concerns for its long-term safety. Using magnetic resonance techniques, MPH-induced acute effects appear to be different in adolescent rats compared to adult animals. Moreover, adolescent exposure to MPH seems to provoke persistent neurobehavioral consequences: long-term modulation of self-control abilities, decreased sensitivity to natural and drug reward, enhanced stress-induced emotionality, together with an enhanced cortical control over sub-cortical dopamine systems and an enduring up-regulation of Htr7 gene expression within the nucleus accumbens (NAcc). In summary, additional studies in animal models are necessary to better understand the long-term consequences of adolescent MPH, and to further investigate the safety of the prescription and administration of such pharmacological treatment at early life stages.

Intranasal application of dopamine reduces activity and improves attention in Naples High Excitability rats that feature the mesocortical variant of ADHD.

Based on findings of a profound action of intranasally applied dopamine (DA) on dopamine release in the striatum, we examined the possibility that intranasal application of DA would influence indices of attention and activity in juvenile male rats of the Naples High Excitability line. This rat model features the main aspects of Attention Deficit/Hyperactivity Disorder (ADHD). Juvenile NHE rats received an intranasal application of either DA (0.075 mg/kg, 0.15 mg/kg and 0.3 mg/kg) or vehicle into both nostrils daily for 15 days. On day 14, 1 h after treatment, they were tested in the Làt maze, and one day later, in the eight arm radial maze. Activity in the Làt maze: The highest dose of DA (0.3 mg/kg) decreased horizontal (HA) and vertical (VA) activity during the first 10 min of the test. No effect was found for rearing duration (RD), which indexes non-selective attention (NSA). Activity in the radial maze: No treatment effects were found for HA and VA components, and for RD. Attention indices: The intermediate dose of DA (0.15 mg/kg) significantly improved the number of arms visited before the first repetitive arm entry in the radial maze, an index of selective spatial attention (SSA). In conclusion, intranasal application of DA reduced hyperactivity at the highest dose used, whereas the intermediate dose improved attention in an animal model of ADHD. These results suggest the potential of employing intranasal DA for therapeutic purposes.

A classical Mendelian cross-breeding study of the Naples high and low excitability rat lines.

The development of brain and behaviour is controlled by the interaction of genetic determinants and environmental factors. To study genetic determinants, model systems such as the Naples rat lines, i.e. Naples high (NHE) and low excitability (NLE), are useful. They have been selectively bred for divergent behaviour arousal to novelty. Aim of this study was to assess the extent of the genetic control of the selection trait. Thus adult albino rats of NHE and NLE lines have been used throughout. According to a classical Mendelian cross-breeding design, a first experiment was carried out with hybrids obtained from parental lines P1 (NHE) and P2 (NLE) as F1, F2 and related backcrosses B1 (F1xP1) and B2 (F1xP2). Young adults (60-80 days) offspring of both gender were exposed separately for two 10min tests to a spatial novelty (Lát-maze). To verify a possible sex link of the trait, a second experiment was carried out adding to the Mendelian cross design parental gender. Behavioural variables were horizontal (corner-crossings: HA), vertical (rearings on hindlimbs: VA) or total activity (HVA: HA+VA) scores. The heritability of HVA trait was estimated across the 20 generations of selection and Mendelian cross hybrids. Quantitative-genetic analysis on this trait and its HA and VA components, was applied by the Lynch and Walsh joint-scaling test procedure to evaluate underlying genetic mechanism. The correlation between experimental data of hybrids and estimated values from different heritability models were also computed. Results indicated that (i) the activity scores by Mendelian hybrids were intermediate between the two parental lines and were also graded; (ii) there was no sex effect on the heritability of trait but only a general tendency of females to higher activity levels; (iii) the heritability of HVA trait was very high (h2 index=0.824); (iv) heritability model of HVA and HA trait was polygenic with a marked epistatic control where as VA trait was fitted by simpler model with less genes and lower epistatic effect. In conclusion the Naples lines reveal strong genetic determinants for behavioural traits associated with polygenic pattern. Moreover, HA and VA activity components with prevailing cognitive and non-cognitive meaning, respectively, show differential genetic control.

Differential alcohol drinking behaviour and dependence in the Naples low- and high-excitability rat lines.

Alcoholism is composed of a series of phenomena, which can be approached in model systems. Our aim was to investigate psychogenetics of alcohol drinking behaviour and dependence in the Naples rat lines. Thus, adult male rats of the Naples low- (NLE), high-excitability (NHE) and random-bred control (NRB) lines had 24-h access to a four-bottle system with tap water and 5, 10 and 20% alcohol solutions. Total voluntary alcohol intake and preference were measured during a 6-week period. In order to analyze behavioural dependence, two abstinence periods were introduced, followed by re-exposure to the bottles. The first was a pure re-test and the second was a quinine test (adding 0.02% quinine alcohol solution). Finally, to verify the role of opioids on alcohol drinking behaviour, rats received naltrexone (5 mg/kg i.p.). Thirty minutes later, they had access for 2 h to a three-bottle system with water, 5 and 20% alcohol solution, respectively. Results indicate that (i) total alcohol intake on day 1 was higher in both NLE/NHE, becoming higher in NLE rats during the 6-week period, (ii) different alcohol preference patterns in the Naples lines were observed over time of testing, (iii) during re-test, NLE rats showed neither reversibility nor alcohol deprivation effect, (iv) during quinine test, only NLE rats reduced alcohol intake to a lower extent and (v) naltrexone reduced by 50% the intake of the preferred solution. Therefore, the NLE rats appear as a new model for studying the neural substrates of the dependence behaviour.

The control of responsiveness in ADHD by catecholamines: evidence for dopaminergic, noradrenergic and interactive roles.

We explore the neurobiological bases of attention deficit hyperactivity disorder (ADHD) from the viewpoint of the neurochemistry and psychopharmacology of the catecholamine-based behavioural systems. The contributions of dopamine (DA) and noradrenaline (NA) neurotransmission to the motor and cognitive symptoms of ADHD (e.g. hyperactivity, variable and impulsive responses) are studied in rodent and primate models. These models represent elements of the behavioural units observed in subjects with ADHD clinically, or in laboratory settings (e.g. locomotion, changed sensitivity/responsivity to novelty/reinforcement and measures of executive processing). In particular, the models selected emphasize traits that are strongly influenced by mesocorticolimbic DA in the spontaneously hypertensive (SHR) and the Naples high excitability (NHE) rat lines. In this context, the mode of action of methylphenidate treatment is discussed. We also describe current views on the altered control by mesolimbic catecholamines of appropriate and inappropriate goal-directed behaviour, and the tolerance or intolerance of delayed reinforcement in ADHD children and animal models. Recent insights into the previously underestimated role of the NA system in the control of mesocortical DA function, and the frontal role in processing information are elaborated.

Dysfunctions in dopamine systems and ADHD: evidence from animals and modeling.

Animal models are useful for characterizing neural substrates of neuropsychiatric disorders. Several models have been proposed for the study of Attention Deficit Hyperactivity Disorder (ADHD). The models can be divided into various groups: (i) genetically derived hyperactivity/ inattention, (ii) animal models showing symptoms after pharmacological intervention, and (iii) those based on spontaneous variations in a random population. Spontaneously hypertensive (SHR) and Naples High Excitability (NHE) rats show behavioral traits featuring the main aspects of ADHD in humans but show different changes in dopamine (DA) systems. In fact, the enzyme tyrosine hydroxylase is hyperexpressed in NHE rats and hypoexpressed in SHR. The DA transporter is hyperexpressed in both lines, although in the SHR, DAT activity is low (reduced DA uptake). The DA levels in the striatum and prefrontal cortex are increased in the juvenile SHR, but are decreased in handled young and non-handled older animals. The mRNA of the D1 DA receptor is upregulated in the prefrontal cortex of SHR and down-regulated in NHE. The D2 DA receptors are likely to be hypofunctioning in SHR, although the experimental evidence is not univocal, whereas their mRNA is hyperexpressed in NHE. Thus, in SHR both the mesocortical and mesolimbic DA pathways appear to be involved, whereas in NHE only the mesocortical system. To understand the effects of methylphenidate, the elective ADHD drug treatment in humans, in a dysfunctioning DA system, we realized a simple mathematical model of DA regulation based on experimental data from electrophysiological, cyclic voltammetry, and microdialysis studies. This model allows the estimation of a higher firing frequency of DA neurons in SHR rats and suggests that methylphenidate increases attentive processes by regulating the firing rate of DA neurons.

Dopamine phenotype and behaviour in animal models: in relation to attention deficit hyperactivity disorder.

The phenotypic expression of behaviour is the outcome of interacting neuronal networks and is modulated by different subcortical systems. In the present paper the role of a major subcortical neurochemical system, dopamine (DA), is reviewed. In particular, knockout (KO) technology has given an overwhelming insight into the effects of specific component of the dopaminergic system. Therefore, the behavioural profile of dopamine transporter (DAT), tyrosine hydroxylase (TH), DA and cAMP-regulated phosphoprotein (DARPP 32), and D1, D2, D3, D4 and D5 dopamine receptors knockouts (and their combination) is reviewed.TH, D1, D2, D4 KO mice exhibit decreased locomotor activity, perhaps due to decreased motivational level. D3 KO and DAT KO mice show an increase in basal and novelty-induced activity respectively. It is possible that the increased dopamine levels in DAT KO mice enhance motivation. These observations support the hyperDA hypothesis in hyperactive phenotypes. Moreover, they suggest that the inhibitory effect of psychostimulant drugs, such as methylphenidate and amphetamines, in Attention Deficit Hyperactivity Disorder may be the outcome of an altered balance between auto- and hetero-receptors. However, since KO technology is hampered by blockade of the target at early stages of development, some alternatives have been proposed, such as inducible mutagenesis and inhibitory small RNAs conveyed to target by viral vectors in adulthood.

Behavioural, pharmacological, morpho-functional molecular studies reveal a hyperfunctioning mesocortical dopamine system in an animal model of attention deficit and hyperactivity disorder.

Clinical and experimental evidence suggest an involvement of dopamine systems, mainly the mesocorticolimbic one (MCL), in Attention-Deficit Hyperactivity Disorder (ADHD). However, it remains to be ascertained whether the systems are hyper- or hypo-functioning, for the implications of the functional state. Indeed, differential functional states of the MCL branches are suggested to be the neural substrate of different ADHD variants. This review covers published and unpublished data from the Naples-High Excitability (NHE) rat, an animal model of ADHD, featuring its main aspects, with no hypertension. Therefore, a multiple approach based on morphological studies of dopamine, norepinephrine, glutamate, acetylcholine and GABA systems, synaptic (Calcium/Calmodulin kinase II) and extrasynaptic (chondroitin sulphates) environments, and molecular biology and pharmacological studies on the dopamine system has been carried out. Morphological findings suggest dopamine neurons in the Ventral Tegmental Area (VTA) to be hypertrophic in NHE rats. The mesostriatal and mesolimbic dopamine branches appear to be normal in basal conditions. However, the striatal interface is probably defective following activation. Conversely, the prefrontal cortex, which represents the second main target of VTA dopamine neurons, has many alterations at the basal level. Therefore, the emerging picture is the association of a hyperinnervating and hyperfunctioning mesocortical branch of the dopamine system. Thus, the evidence gathered so far might improve our understanding of the neural substrates of neuropsychiatric disorders such as ADHD, schizophrenia and drug addiction.

The Naples High- and Low-Excitability rats: selective breeding, behavioral profile, morphometry, and molecular biology of the mesocortical dopamine system.

The Naples High- (NHE) and Low-Excitability (NLE) rat lines have been selected since 1976 on the basis of behavioral arousal to novelty (Làt-maze). Selective breeding has been conducted under continuous genetic pressure, with no brother-sister mating. The behavioral analyses presented here deal with (1) activity in environments of different complexity, i.e., holeboard and Làt maze; (2) maze learning in hexagonal tunnel, Olton, and Morris water mazes and; (3) two-way active avoidance and conditioned taste aversion tests. Morphometric analyses deal with central dopaminergic systems at their origin and target sites, as well as the density of dopamine transporter immunoreactivity. Molecular biology analyses are also presented, dealing with recent experiments on the prefrontal cortex (PFc), cloning and identifying differentially expressed genes using subtractive libraries and RNAase protection. The divergence between NLE and NHE rats varies as a function of the complexity level of the environment, with an impaired working and reference memory in both lines compared to random bred (NRB) controls. Moreover, data from the PFc of NHE rats show a hyperdopaminergic innervation, with overexpression of mRNA species involved in basal metabolism, and down-regulation of dopamine D1 receptors. Altogether, the evidence gathered so far supports a hyperfunctioning mesocorticolimbic system that makes NHE rats a useful tool for the study of hyperactivity and attention deficit, learning and memory disabilities, and drug abuse.

A morphometric evidence for a hyperfunctioning mesolimbic system in an animal model of ADHD.

The hyperfunctioning dopamine hypothesis in the mesocorticolimbic (MCL) system has been addressed by a neurogenetic approach in model systems. Thus, a morphometric analysis was carried out on neurons of origin of Substantia Nigra (SN) and Ventral Tegmental Area (VTA) dopamine systems of the Naples High-Excitability (NHE), Low-Excitability (NLE) and control lines. Male adult rats were tested in a spatial novelty for indices of activity and non-selective attention. Mesencephalic coronal sections were processed for tyrosine hydroxylase (TH) immunohistochemistry and cytochromoxidase (C.O.) histochemistry. Image analysis in the rostro-caudal plane showed (i) a higher neuron size of TH+ elements in the VTA of NHE and NLE, across the entire structure in the NHE, and only in the middle portion in the NLE; (ii) a higher expression of TH in the neuropil of the VTA in NHE; (iii) a lower C.O. activity in both NLE and NHE; (iv) no differences in the SN. The larger neuron size in both NHE and NLE rats as compared with control rats, along with higher TH expression mainly in the NHE, in absence of any relevant alteration in the SN, reveals an unbalance between the two dopamine systems and a subsequent alteration in limbic (reward, motivation, sustained attention) functions. The decreased C.O. activity might be due to reduced feedback inhibition by striatal GABA neurons and interneurons leading to increased DA neuron firing. In conclusion, the increased behavioral activity and impaired attention observed in the NHE rats are associated to hyperfunctioning MCL system in this genetic model of Attention-Deficit Hyperactivity Disorder (ADHD).