Briony J. Catlow

Granulocyte colony stimulating factor decreases brain amyloid burden and reverses cognitive impairment in Alzheimer's mice.

Granulocyte colony stimulating factor (G-CSF) is a multi-modal hematopoietic growth factor, which also has profound effects on the diseased CNS. G-CSF has been shown to enhance recovery from neurologic deficits in rodent models of ischemia. G-CSF appears to facilitate neuroplastic changes by both mobilization of bone marrow-derived cells and by its direct actions on CNS cells. The overall objective of the study was to determine if G-CSF administration in a mouse model of Alzheimers disease (AD) (Tg APP/PS1) would impact hippocampal-dependent learning by modifying the underlying disease pathology. A course of s.c. administration of G-CSF for a period of less than three weeks significantly improved cognitive performance, decreased beta-amyloid deposition in hippocampus and entorhinal cortex and augmented total microglial activity. Additionally, G-CSF reduced systemic inflammation indicated by suppression of the production or activity of major pro-inflammatory cytokines in plasma. Improved cognition in AD mice was associated with increased synaptophysin immunostaining in hippocampal CA1 and CA3 regions and augmented neurogenesis, evidenced by increased numbers of calretinin-expressing cells in dentate gyrus. Given that G-CSF is already utilized clinically to safely stimulate hematopoietic stem cell production, these basic research findings will be readily translated into clinical trials to reverse or forestall the progression of dementia in AD. The primary objective of the present study was to determine whether a short course of G-CSF administration would have an impact on the pathological hallmark of AD, the age-dependent accumulation of A beta deposits, in a transgenic mouse model of AD (APP+ PS1; Tg). A second objective was to determine whether such treatment would impact cognitive performance in a hippocampal-dependent memory paradigm. To explain the G-CSF triggered amyloid reduction and associated reversal of cognitive impairment, several mechanisms of action were explored. (1) G-CSF was hypothesized to increase activation of resident microglia and to increase mobilization of marrow-derived microglia. The effect of G-CSF on microglial activation was examined by quantitative measurements of total microglial burden. To determine if G-CSF increased trafficking of marrow-derived microglia into brain, bone marrow-derived green fluorescent protein-expressing (GFP+) microglia were visualized in the brains of chimeric AD mice. (2) To assess the role of immune-modulation in mediating G-CSF effects, a panel of cytokines was measured in both plasma and brain. (3) To test the hypothesis that reduction of A beta deposits can affect synaptic area, quantitative measurement of synaptophysin immunoreactivity in hippocampal CA1 and CA3 sectors was undertaken. (4) To learn whether enhanced hippocampal neurogenesis was induced by G-CSF treatment, numbers of calretinin-expressing cells were determined in dentate gyrus.

Effects of psilocybin on hippocampal neurogenesis and extinction of trace fear conditioning.

Drugs that modulate serotonin (5-HT) synaptic concentrations impact neurogenesis and hippocampal (HPC)-dependent learning. The primary objective is to determine the extent to which psilocybin (PSOP) modulates neurogenesis and thereby affects acquisition and extinction of HPC-dependent trace fear conditioning. PSOP, the 5-HT2A agonist 25I-NBMeO and the 5-HT2A/C antagonist ketanserin were administered via an acute intraperitoneal injection to mice. Trace fear conditioning was measured as the amount of time spent immobile in the presence of the conditioned stimulus (CS, auditory tone), trace (silent interval) and post-trace interval over 10 trials. Extinction was determined by the number of trials required to resume mobility during CS, trace and post-trace when the shock was not delivered. Neurogenesis was determined by unbiased counts of cells in the dentate gyrus of the HPC birth-dated with BrdU co-expressing a neuronal marker. Mice treated with a range of doses of PSOP acquired a robust conditioned fear response. Mice injected with low doses of PSOP extinguished cued fear conditioning significantly more rapidly than high-dose PSOP or saline-treated mice. Injection of PSOP, 25I-NBMeO or ketanserin resulted in significant dose-dependent decreases in number of newborn neurons in hippocampus. At the low doses of PSOP that enhanced extinction, neurogenesis was not decreased, but rather tended toward an increase. Extinction of “fear conditioning” may be mediated by actions of the drugs at sites other than hippocampus such as the amygdala, which is known to mediate the perception of fear. Another caveat is that PSOP is not purely selective for 5-HT2A receptors. PSOP facilitates extinction of the classically conditioned fear response, and this, and similar agents, should be explored as potential treatments for post-traumatic stress disorder and related conditions.

Effects of environmental enrichment and physical activity on neurogenesis in transgenic PS1/APP mice

Rodents exposed to environmental enrichment show many differences, including improved cognitive performance, when compared to those living in standard (impoverished) housing. The purpose of the present study was to determine if a selective increase in neurogenesis occurred in cognitively-protected Tg mice raised in an enriched environment compared to those reared in physical activity housing. At weaning, double Tg APP+PS1 mice were placed into one of three environments: complete environmental enrichment (CE), enhanced physical activity (PA), or individual, impoverished housing (IMP). At 9-10 months of age, Tg mice were injected with BrdU (100 mg/kg BID) followed by euthanasia either 24 h or 2 weeks after the last injection. Unbiased estimates of BrdU positive cells in the hippocampal subgranular zone revealed a significant increase in cellular proliferation in Tg mice raised in CE or PA compared to Tg mice reared in IMP housing. However, counts of BrdU birth-dated cells 2 weeks after labeling showed no difference among the three groups, indicating decreased survival of cells in those groups (CE and PA) with higher cellular proliferation rates in the neurogenic niche. Counts of calretinin-expressing cells, a marker of immature neurons, also indicated no difference among the three groups of mice. In view of our prior study showing that enhanced cognitive activity (but not enhanced physical activity) protects Tg mice against cognitive impairment, the present results indicate that increased generation and survival of new neurons in the hippocampal dentate gyrus is not involved with the cognitively-protective effects of complete CE in Alzheimers transgenic mice.

Effects of MDMA (“ecstasy”) during adolescence on place conditioning and hippocampal neurogenesis

The use of 3,4,methylenedioxymethamphetamine (MDMA), the active agent in ecstasy, during adolescence is widespread yet the effects on adolescent behavior and brain development are unknown. The aim of the present study was 1) to evaluate effects of MDMA in adolescent rats using the conditioned place preference (CPP) paradigm to measure MDMA-induced reward and 2) assess effects of MDMA administration on cellular proliferation, survival and neurogenesis in the dentate gyrus of the hippocampus. During the adolescent period, MDMA CPP was measured in adolescents [postnatal day (PND) 28-39] by training rats to associate 1.25, 2.5, 5.0mg/kg MDMA or saline administration with environmental cues. After CPP ended, bromodeoxyuridine (BrdU) was injected and rats were euthanized either 24h (to evaluate cell proliferation) or 2 weeks (to assess neurogenesis) after the last MDMA injection. Adolescents expressed a CPP for 2.5mg/kg MDMA. Repeated exposure to 5.0mg/kg MDMA during adolescence increased cell proliferation, yet diminished neurogenesis, an effect that was replicated using flow cytometry. These findings suggest differential dose effects of adolescent MDMA exposure on reward related behaviors and hippocampal neurogenesis.

Heightened cocaine-induced locomotor activity in adolescent compared to adult female rats

Initiation and experimentation with illicit drugs often occurs in adolescence. Evidence suggests that adolescent rats are more sensitive to some of the effects of drugs of abuse than adult rats. The present study investigated whether adolescent and adult female Sprague Dawley rats differ in cocaine-induced locomotor activity. Animals were placed in the test environment for 30 minutes, and then administered an intraperitoneal (IP) injection of either cocaine (20mg/kg) or saline (0.9%). Both adult and adolescent animals showed significant increases in locomotor activity as a result of cocaine administration compared to saline controls. Interestingly, cocaine induced significantly more locomotor activity in the adolescent females compared to the adults, demonstrating that cocaine acts differently in developing animals.

Early inhibition of TNFα increases 6-hydroxydopamine-induced striatal degeneration

Evidence suggests that tumor necrosis factor alpha (TNF) is a leading cause of dopaminergic neuronal cell death. TNF also, however, has neuroprotective effects. Thus, TNF might have a dual role following injury: immediate release after injury is protective, whereas chronic increases are detrimental. In the present study, 6-hydroxydopamine was used to lesion the dorsal striatum in male Fisher 344 rats at 2 different time points. Group 1 received a daily injection of TNFalpha antisense oligodeoxyribonucleotide (ODN) or control on days 1 through 7 post-lesion. Group 2 received a daily injection of TNF antisense ODN or control on days 5 through 15 post-lesion. Rats were killed on the day following the last injection of TNF antisense ODN. Injection of TNF antisense ODN on days 1 through 7 increased the area of the tyrosine-hydroxylase-negative zone ipsilateral to the injection when compared to controls. In contrast, when inhibition of TNF was delayed, the area of tyrosine hydroxylase loss was significantly reduced. These findings suggest that TNF release is neuroprotective in the early stages of injury but becomes neurotoxic when chronically induced.

Hippocampal Neurogenesis: Effects of Psychedelic Drugs

Abstract Neurogenesis, or the birth of new neurons, occurs throughout the human life span in the hippocampus, a structural node in the neural circuitry responsible for memory and learning. The process of neurogenesis involves proliferation of neural stem/progenitor cells and their differentiation into mature neurons, followed by integration into hippocampal circuitry. The function of new neurons in the hippocampus is not completely understood. The formation of new synaptic connections (and pruning of synapses) between neurons in the hippocampal dentate gyrus and fibers to and from the cerebral cortex is important in the acquisition of new associations (learning), recall of those associations (memory), and extinction of associations (forgetting). Very likely, the new neurons play a role in encoding temporal aspects of episodic memory. Neurogenesis is influenced by many factors, including physical activity, stress, depression, seizures, irradiation, aging, and a variety of psychoactive drugs. Many psychedelic drugs are shown to have an impact on hippocampal neurogenesis in a dose-dependent manner and to alter some aspects of memory and learning. Drug-induced alterations in hippocampal neurogenesis have been shown to alleviate depression and to have beneficial effects on conditioned fear. In light of abundant preclinical data and the loosening of governmental restrictions on psychedelic drug research, these agents should be explored for their therapeutic potential in depression, posttraumatic stress disorders, and drug dependence.

Cannabinoids for the Treatment of Movement Disorders.

Opinion statementUse of cannabinoids as medications has a long history. Unfortunately, the prohibition of cannabis and its classification in 1970 as a schedule 1 drug has been a major obstacle in studying these agents in a systematic, controlled manner. The number of class 1 studies (randomized, double-blind, placebo-controlled) in patients with movement disorders is limited. Hence, it is not possible to make recommendations on the use of these cannabinoids as primary treatments for any of the movement disorders at this time. Fortunately, there is an expanding body of research in animal models of age-dependent and disease-related changes in the endocannabinoid system that is providing new targets for drug development. Moreover, there is growing evidence of a “cannabinoid entourage effect” in which a combination of cannabinoids derived from the plant are more effective than any single cannabinoid for a number of conditions. Cannabis preparations may presently offer an option for compassionate use in severe neurologic diseases, but at this point, only when standard-of-care therapy is ineffective. As more high-quality clinical data are gathered, the therapeutic application of cannabinoids will expand.