Effect of chronic corticosterone application on depression-like behavior in C57BL/6N and C57BL/6J mice.

Many studies using genetic mouse models are performed with animals on either one of the two closely related genetic backgrounds, C57BL/6J or C57BL/6N. These strains differ only in a few genetic loci, but have some phenotypic differences that also affect behavior. In order to determine the effects of chronic stress hormone exposure, which is relevant for the pathogenesis of psychiatric disorders, we investigated here the behavioral manifestations of long-term increase in corticosterone levels. Thus, male mice from both sub-strains were subcutaneously implanted with corticosterone (20 mg) or placebo pellets that released the hormone for a period of 21 days and resulted in significantly elevated plasma corticosterone levels. Corticosterone significantly increased food intake in B6N, but not in B6J mice. At various time points after pellet implantation, we performed tests relevant to activity and emotional behaviors. B6J mice displayed a generally higher activity in the home cage and the open field. Corticosterone decreased the activity. In B6N mice, corticosterone also decreased sucrose preference, worsened the coat state and increased forced swim immobility, while it had no effect in the B6J strain. Altogether, these results indicate that B6N mice are more sensitive to some of the effects of chronic corticosterone treatment than B6J mice.

Enhanced microglial activity in FAAH(-/-) animals.

AIMS: Several lines of evidence suggest that the endocannabinoid system is involved in the regulation of glial activity. Enhanced levels of the endocannabinoid N-arachidonoyl ethanolamine (AEA, also referred to as anandamide) as well as non-cannabinoid lipids like palmitoylethanolamine (PEA) due to genetic deletion or pharmacologic blockade of its degrading enzyme fatty acid amide hydrolase (FAAH) reduced neuroinflammatory changes in models of neurodegeneration. Now we addressed the question if genetic deletion of FAAH also influences age-related neuroinflammation. MAIN METHODS: To answer this question we compared the number and size of microglia in young and old wild-type and FAAH(-/-) mice and analysed the distribution of microglia sizes in the four groups. Additionally, we analysed IL-6 and IL-1ß levels with ELISA and astrocyte activities as ratio of GFAP-positive areas in the hippocampus. KEY FINDINGS: Ageing was associated with an increased number and activity of microglia, elevated IL-6 and IL-1ß levels and enhanced area covered by astrocytes in wild-type animals. Unexpectedly, in FAAH(-/-) animals the number of microglia and the ratio of activated microglia and IL-1ß level were already higher in young animals than in age-matched wild-type controls. There was no further age-related increase in these inflammation markers in the knockout line. SIGNIFICANCE: Our results suggest that AEA is involved in the regulation of microglia activity. Life-long elevation of AEA levels disturbs microglial regulation and leads to pro-inflammatory changes.

Enkephalin knockout male mice are resistant to chronic mild stress.

Enhanced stress reactivity or sensitivity to chronic stress increases the susceptibility to mood pathologies such as major depression. The opioid peptide enkephalin is an important modulator of the stress response. Previous studies using preproenkephalin knockout (PENK KO) mice showed that these animals exhibit abnormal stress reactivity and show increased anxiety behavior in acute stress situations. However, the consequence of enkephalin deficiency in the reactivity to chronic stress conditions is not known. In this study, we therefore submitted wild-type (WT) and PENK KO male mice to chronic stress conditions, using the chronic mild stress (CMS) protocol. Subsequently, we studied the CMS effects on the behavioral and hormonal level and also performed gene expression analyses. In WT animals, CMS increased the expression of the enkephalin gene in the paraventricular nucleus (PVN) of the hypothalamus and elevated the corticosterone levels. In addition, WT mice exhibited enhanced anxiety in the zero-maze test and depression-related behaviors in the sucrose preference and forced swim tests. Surprisingly, in PENK KO mice, we did not detect anxiety and depression-related behavioral changes after the CMS procedure, and even measured a decreased hormonal stress response. These results indicate that PENK KO mice are resistant to the CMS effects, suggesting that enkephalin enhances the reactivity to chronic stress.

Dynorphins regulate the strength of social memory.

Emotionally arousing events like encounter with an unfamiliar con-species produce strong and vivid memories, whereby the hippocampus and amygdala play a crucial role. It is less understood, however, which neurotransmitter systems regulate the strength of social memories, which have a strong emotional component. It was shown previously that dynorphin signalling is involved in the formation and extinction of fear memories, therefore we asked if it influences social memories as well. Mice with a genetic deletion of the prodynorphin gene Pdyn (Pdyn(-/-)) showed a superior partner recognition ability, whereas their performance in the object recognition test was identical as in wild-type mice. Pharmacological blockade of kappa opioid receptors (KORs) led to an enhanced social memory in wild-type animals, whereas activation of KORs reduced the recognition ability of Pdyn(-/-) mice. Partner recognition test situation induced higher elevation in dynorphin A levels in the central and basolateral amygdala as well as in the hippocampus, and also higher dynorphin B levels in the hippocampus than the object recognition test situation. Our result suggests that dynorphin system activity is increased in emotionally arousing situation and it decreases the formation of social memories. Thus, dynorphin signalling is involved in the formation of social memories by diminishing the emotional component of the experience.

Increased morphine analgesia and reduced side effects in mice lacking the tac1 gene.

BACKGROUND AND PURPOSE: Although morphine is a very effective analgesic, its narrow therapeutic index and severe side effects limit its therapeutic use. Previous studies indicated that the pharmacological responses of opioids are modulated by genetic and pharmacological invalidation of tachykinin receptors. Here we address the role of substance P and neurokinin A, which are both encoded by the tachykinin 1 (tac1) gene, as modulators of opioid effects. EXPERIMENTAL APPROACH: The analgesic and side effect potential of morphine was compared between wild-type and tac1 null mutant mice. KEY RESULTS: Morphine was a more potent analgesic in tac1 null mutant mice, that is, in the absence of substance P/neurokinin A signalling. Interestingly, the most serious side effect of acute morphine, that is respiratory depression, was reduced in tac1(-/-) animals. Comparing the addictive potential of morphine in wild-type and knockout animals we found that morphine preference was similar between the genotypes. However, the aversive effect of withdrawal precipitated by naloxone in morphine-dependent animals was significantly reduced in tac1 knockout mice. Behavioural sensitization, the underlying mechanism of addiction, was also significantly lower in tac1(-/-) mice. CONCLUSION AND IMPLICATIONS: The analgesic potential of morphine was increased in tac1 knockout mice. In contrast, both the ventilatory suppressing effect and the addictive potential of morphine were reduced. These results suggest that reducing activity of the tachykinin system may be a possible strategy to improve the pharmacological potential of morphine.

Altered respiratory pattern and hypoxic response in transgenic newborn mice lacking the tachykinin-1 gene.

Substance P is known to be involved in respiratory rhythm and central pattern-generating mechanisms, especially during early development. We therefore studied respiratory responses in transgenic newborn mice (Tac1(-/-)) lacking substance P and neurokinin A (NKA). In vivo, the effects of intermittent isocapnic hypoxia (IH) and hypercapnia were studied using whole body flow plethysmography at P2-3 and P8-10. In vitro, anoxic responses and the effects of hypocapnic and hypercapnic conditions were studied in brain stem-spinal cord preparations (C4 activity) at P2. Hypoxic challenge considerably modified the respiratory activity in transgenic mice displayed in vivo as an attenuated increase in tidal volume during IH. Transgenic mice also showed a more prominent posthypoxic frequency decline in vivo, and posthypoxic neuronal arrests appeared more often in vitro. We recognized two types of sigh activity: with or without a following pause. During IH, the amount of sighs with a pause decreased and those without increased, a redistribution that became stronger with age only in controls. Intermittent anoxia induced long-term facilitation effects in controls, but not in Tac1(-/-) animals, manifested as an increase in burst frequency in vitro and by an augmentation of ventilation during posthypoxic periods in vivo. Thus our data demonstrate that a functional substance P/NKA system is of great importance for the generation of an adequate respiratory response to hypoxic provocation in newborn mice and during early maturation. It also indicates that substance P (and/or NKA) is involved in the development of the plasticity of the respiratory system.

Early age-related cognitive impairment in mice lacking cannabinoid CB1 receptors.

The molecular mechanisms contributing to the normal age-related decline of cognitive functions or to pathological learning and memory impairment are largely unknown. We demonstrate here that young mice (6-7 weeks) with a genetic deletion of the cannabinoid CB1 receptor performed as well as WT mice, or often better, in a number of learning and memory paradigms, including animal models of skill-learning, partner recognition, and operant conditioning. In contrast, the performance of mature mice (3-5 months) lacking CB1 receptors was much worse than that of age-matched WT animals. In most tests, these mice performed at the same level as old animals (14-17 months), suggesting that the decline in cognitive functions is accelerated in the absence of CB1 receptors. This rapid decline in CB1-deficient animals is accompanied by a loss of neurons in the CA1 and CA3 regions of the hippocampus.

Mutagenesis and knockout models: NK1 and substance P.

Tachykinins play an important role as peptide modulators in the CNS. Based on the concentration and distribution of the peptides and their receptors, substance P (SP) and its cognate receptor neurokinin 1 (NK1R) seem to play a particularly important role in higher brain functions. They are expressed at high levels in the limbic system, which is the neural basis of emotional responses. Three different lines of evidence from physiological studies support such a role of SP in the regulation of emotionality: (1) stress is often associated with elevated level of SP in animals and humans; (2) systematic and local injections of SP influence anxiety levels in a dose-dependent and site-specific manner; (3) NK1 receptor antagonists show anxiolytic effects in different animal models of anxiety. Although these studies point to the NK1 receptor as a promising target for the pharmacotherapy of anxiety disorders, high affinity antagonists for the human receptors could not be studied in rats or mice due to species differences in the antagonist binding sites. However, studies on anxiety and depression-related behaviors have now been performed in mouse mutants deficient in NK1 receptor or SP and NKA. These genetic studies have shown that anxiety and depression-related phenotypes are profoundly affected by the tachykinin system. For example, NK1R-deficient mice seem to be less prone depression-related behaviors in models of depression, and one study also provided evidence for reduced anxiety levels. Mice deficient in SP and NKA behaved similarly as the NK1R knockouts. In animal models of anxiety they performed like wildtype mice treated with anxiolytic drugs. In behavioral paradigms related to depression they behaved like wildtype animals treated with antidepressants. In summary, the genetic studies clearly show that the SP/NK1 system plays an important role in the modulation of emotional behaviors.

mCPP-induced anxiety in the light-dark box in rats--a new method for screening anxiolytic activity.

The activity of anxiolytic and other drugs in a light-dark test situation was studied in rats treated with the anxiogenic compound m-chlorophenyl-piperazine (mCPP). mCPP 0.5 mg/kg significantly diminished the exploratory activity of the animals in the light compartment of the apparatus. Drugs to be tested against mCPP-induced anxiety when studied alone (not in combination with mCPP) did not significantly alter the activity of rats in the light-dark apparatus, except yohimbine, which reduced the movement time values in the lit area. 1,4-Benzodiazepines [diazepam (0.1-4mg/kg) and chlordiazepoxide (2-8mg/kg)], 5-HT2A/2C antagonists [ritanserin (0.25-8 mg/kg) and deramciclane (0.5-8 g/kg)], the 5-HT3 antagonist MDL-72222 (3 mg/kg) and ethanol (2-4 mg/kg) significantly reduced the effect of mCPP. A dose-dependent increase in the exploratory activity of mCPP-treated animals was found in the 2,3-benzodiazepine girisopam (2.5-5 mg/kg)-treated groups. Tofisopam, another 2,3-benzodiazepine molecule, also showed activity against mCPP, although its effect was not statistically significant. The 5-HT1A partial agonist buspirone was also active in the dose range of 0.25-0.5 mg/kg, while the 5-HT1A full agonist 8-OH-DPAT was the only drug with presumed anxiolytic activity that clearly lacked any effect in this model. Imipramine, amitriptyline, morphine, naloxone, haloperidol, clozapine, amphetamine, yohimbine, carbamazepine and diphenylhydantoin were not effective. We conclude that mCPP-induced anxiety in the light-dark box is a potent and useful method for screening and detecting anxiolytic activity of a wide range of compounds with various modes of action.

Some doubts about the basic concept of hole-board test.

Hole board test is a generally used method for screening the potential anxiolytic character of drugs. The test is based on the assumption, that head-dipping activity of the animals is inversely proportional to their anxiety state. We tested this assumption by measuring the head-dipping activity of animals in environments with different levels of aversive character (illumination). The anxiolytic chlordiazepoxide significantly elevated head-dipping activity in moderately aversive environment, it was not active in non-aversive environment, and it exhibited inhibitory activity in highly aversive environment. When the latency of the first head-dip was measured, we found that the proportion of animals with short latency was significantly increased in moderately and highly aversive environments. It is concluded, that the inverse relation between anxiety state and head-dipping activity is true only in a certain range of anxiety level. In more aversive situations, when the anxiety level of the animals is high, the holes nay represent a possible way to escape from the aversive environment instead of an explorable object. In this case the relation between anxiety state and head-dipping activity is directly and not inversely proportional.

Neurotoxic effect of enteral aluminium.

Long Evans rats were treated for 90 days with water-soluble, insoluble or chelated aluminium compounds. The daily treatments given were as follows: controls, NaCl (100 mg/kg body weight) plus citric acid (30 mg/kg); AlCl3 (30 or 100 mg/kg); Al(OH)3 (100 mg/kg) plus citric acid (30 mg/kg); Al(OH)3 (300 mg/kg). Their learning ability was determined in the labyrinth test at day 90, and the choline-acetyltransferase, acetylcholinesterase activity and aluminium content of the brains were measured. Soluble and chelated aluminium compounds seriously worsened the learning ability, and the aluminium content of the brain was elevated. Acetylcholinesterase activity increased and choline-acetyltransferase activity decreased, resulting in a diminished cholinergic activity, which is a characteristic of Alzheimer's disease.