Neonatal fibroblast growth factor treatment enhances cocaine sensitization.

Growth factors are critical in neurodevelopment and neuroplasticity, and recent studies point to their involvement in addiction. We previously reported increased levels of basic fibroblast growth factor (FGF2) in high novelty/drug-seeking rats (bred high responders, bHR) compared to low novelty/drug-seeking rats(bred low responders, bLRs). The present study asked whether an early life manipulation of the FGF system(a single FGF2 injection on postnatal day 2) can impact cocaine sensitization and associated neurobiological markers in adult bHR/bLR animals. Neonatal FGF2- and vehicle-treated bHR/bLR rats were sensitized to cocaine(7 daily injections, 15 mg/kg/day, i.p.) in adulthood. Neonatal FGF2 markedly increased bLRs' typically low psychomotor sensitization to cocaine (day 7 locomotor response to cocaine), but had little effect on bHRs' cocaine sensitization. Gene expression studies examined dopaminergic molecules as well as FGF2 and the FGFR1 receptor in cocaine naïve animals, to investigate possible neurobiological alterations induced by neonatal FGF2 exposure that may influence behavioral response to cocaine. bLRs showed decreased tyrosine hydroxylase in the ventral tegmental area (VTA), decreased D1 and increased D2 receptor expression in the nucleus accumbens core, as well as decreased FGF2 in the VTA, substantia nigra, accumbens core, and caudate putamen compared to bHRs. Neonatal FGF2 selectively increased D1 receptor and FGF2 mRNA in the accumbens core of bLRs, which may contribute to their heightened cocaine sensitization. Our results suggest increased FGF2 in the mesodopaminergic circuit (as in baseline bHRs and neonatal FGF2-exposed bLRs vs. baseline bLRs) enhances an individual's susceptibility to cocaine sensitization and may increase vulnerability to drug seeking and addiction.

DNA methylation in the developing hippocampus and amygdala of anxiety-prone versus risk-taking rats.

All organisms exhibit a wide range of emotional behaviors and interact with the environment in different ways. Some individuals may be more quiet and shy whereas others are more outgoing and adventurous. These temperamental and personality differences can predispose individuals to certain psychopathologies which may be influenced by genetic vulnerability and/or early life experiences. Rodent models can be used to recapitulate emotional reactivity differences, and these models can, in turn, be used to examine potential neurobiological underpinnings of these traits. The present study utilizes two strains of rats that were selectively bred for differences in novelty seeking. High Novelty-Responding (bHR) rats are very active in response to novelty, exhibit exaggerated risk-taking, aggression, impulsivity, and show increased behavioral response to cocaine. Low Novelty-Responding (bLR) rats show increased anxiety, depressive behavior and vulnerability to chronic stress. One way in which the bHR versus bLR behavioral phenotypes may differ is through epigenetic modification of DNA. DNA can be modified through processes such as acetylation or methylation to either enhance or subdue gene expression. This study examines putative differences in methylation levels in the hippocampus and amygdala of developing bHR-bLR rats. Previous research observed widespread gene expression differences in the bLR developing hippocampus, and the current study aims to begin to examine potential epigenetic factors that may contribute to those gene differences. The amygdala was chosen because it is involved in emotional processes, in part through its connections with the hippocampus. Therefore, the present study used in situ hybridization to assess the expression of DNA methyltransferase-1 (DNMT1) mRNA in the hippocampus, amygdala and several other brain areas of bHR and bLR pups at three developmental time points: postnatal days (P) 7, 14, and 21. We focused on the first 3 postnatal weeks, in part to parallel our early microarray gene expression work, and because this represents a critical period of brain development, which shapes individuals' lifelong emotional and stress reactivity. We found significant differences in dentate gyrus and CA3 regions of the hippocampus at P7 with no differences seen at P14 or P21. Interestingly, we also found significant bHR-bLR DNMT1 differences at P7 within the lateral, basolateral and medial nuclei of the amygdala, with no difference at P14 and P21, suggesting that the first postnatal week is a critical period for DNA methylation during brain development.

Inborn differences in environmental reactivity predict divergent diurnal behavioral, endocrine, and gene expression rhythms.

Circadian dysfunction has long been implicated in the etiology of mood disorders. The gene Clock and related molecules (e.g. Per1, Per2) represent key regulators of circadian rhythmicity, and their targeted disruption in mutant mice produces potentiated reward drive, novelty-seeking, impulsivity, disrupted sleep, reduced depression and anxiety - a behavioral profile highly reminiscent of our selectively bred high responder (bHR) rats compared to bred low responders (bLRs). The current study evaluated potential diurnal bHR-bLR differences in behavior, gene expression, and neuroendocrinology. Relative to bHRs, bLRs showed diminished homecage locomotion during the dark (but not light) phase and a delayed corticosterone peak. In situ hybridizations in hypothalamus, amygdala, and hippocampus at Zeitgeber Time (ZT)2 and ZT14 revealed distinct bHR-bLR day-night gene expression fluctuations. bHRs exhibited altered day-night patterns of corticotrophin releasing hormone (CRH) and arginine vasopression (AVP) mRNA in the hypothalamus, and perturbed hippocampal MR:GR ratios relative to bLR rats. bHR-bLR rats showed disparate day-night Clock expression in the suprachiasmatic nucleus, a master circadian oscillator, with bHRs showing higher levels at ZT14 versus ZT2 and bLRs showing the opposite pattern. Clock, Per1 and Per2 were assessed in the substantia nigra pars compacta (SNc) and ventral tegmental area (VTA) since disruption of these genes induces "bHR-like" behavior in mutant mice. Clock and Per1 did not differ between strains, but there were robust Per2 differences, with bHRs having reduced Per2 in VTA and SNc. These findings resonate with earlier work demonstrating that perturbation of Clock and related molecules contributes to disturbances of emotional and addictive behaviors.

Pattern of forebrain activation in high novelty-seeking rats following aggressive encounter.

We have previously demonstrated that selectively-bred High (bHR) and Low (bLR) novelty-seeking rats exhibit agonistic differences, with bHRs acting in a highly aggressive manner when facing homecage intrusion. In order to discover the specific neuronal pathways responsible for bHRs' high levels of aggression, the present study compared c-fos mRNA expression in several forebrain regions of bHR/bLR males following this experience. bHR/bLR males were housed with female rats for 2 weeks, and then the females were replaced with a male intruder for 10 min. bHR/bLR residents were subsequently sacrificed by rapid decapitation, and their brains were removed and processed for c-fos in situ hybridization. Intrusion elicited robust c-fos mRNA expression in both phenotypes throughout the forebrain, including the septum, amygdala, hippocampus, cingulate cortex, and the hypothalamus. However, bHRs and bLRs exhibited distinct activation patterns in select areas. Compared to bHR rats, bLRs expressed greater c-fos in the lateral septum and within multiple hypothalamic nuclei, while bHRs showed greater activation in the arcuate hypothalamic nucleus and in the hippocampus. No bHR/bLR differences in c-fos expression were detected in the amygdala, cortical regions, and striatum. We also found divergent 5-HT1A receptor mRNA expression within some of these same areas, with bLRs having greater 5-HT1A, but not 5-HT1B, receptor mRNA levels in the septum, hippocampus and cingulate cortex. These findings, together with our earlier work, suggest that bHRs exhibit altered serotonergic functioning within select circuits during an aggressive encounter.