17 entries

CD4+ T lymphocytes interact with microglia to modulate hippocampal neurogenesis.

Khan D, Owens E, Zaben M, Dunnett SB, Gray WP (2013) CD4+ T lymphocytes interact with microglia to modulate hippocampal neurogenesis. Neuroscience 2013 Abstracts 699.04. Society for Neuroscience, San Diego, CA.

Summary: Hippocampal neurogenesis occurs within the subgranular zone of the dentate gyrus and is important for learning and memory. Neurogenesis is impaired in patients with chronic temporal lobe epilepsy, an observation that may account for the learning and memory deficits that these patients commonly have. Emerging literature demonstrates that CD4+ T lymphocytes increase neurogenesis and enhance cognition; however, the exact mechanisms remain undetermined. Vasoactive Intestinal Peptide (VIP) receptors are expressed on T lymphocytes, microglia and hippocampal progenitor cells, hence this study was designed to investigate VIP’s role in mediating neuro-immune modulation. Hippocampal cultures (P7-10 Sprague Dawley rats) were generated and maintained for 3 days in vitro (DIV) and treated with 5% supernatant generated from C57/Bl6 mouse spleen using a CD4+ T lymphocyte isolation kit. BrdU and experimental conditions were added for the terminal 6 hours before fixation and then processed for BrdU and nestin. For phenotype analysis, experimental conditions were added at 3DIV and fixed at 6DIV to be processed for nestin and TuJ1. To deplete microglia, Mac-1-SAP was added at 2DIV for 24 hours before experimental conditions were added. 5% T lymphocytes supernatant increased proliferation of hippocampal nestin-expressing cells; an effect that is further enhanced under VIP treatment via VPAC1 receptor subtype. Examining potential cytokine mediators of this effect, PCR analysis showed 6-fold increase in IL-4 mRNA expression, and IL-4 antagonist abolished VIP proliferative effects. Using Mac-1-SAP to account for microglial involvement by depleting microglia, VIP proliferative effects were abolished. Our phenotyping studies also demonstrated an additional neurogenic effect under VIP treated supernatant compared to standard control conditions. Taken together, these results show VPAC1 receptor subtype expressed by CD4+ T lymphocytes mediates VIP proliferative effects on hippocampal cells via IL-4 cytokine release. Microglia mediates VIP proliferative effects. While we demonstrated before that VPAC2 mediates hippocampal progenitor cell survival, the findings of this study strongly implicate VPAC1 receptor as a neuro-immune mediator of hippocampal neurogenesis, and from a therapeutic perspective, shows that the effect can be pharmacologically manipulated.

Related Products: Mac-1-SAP rat (Cat. #IT-33)

ATS Poster of the Year Winner

Investigating the potential of stem cell based therapy in an immunotoxin mouse model of Alzheimer’s disease.

Tiwari D, Warden H, Haynes JM, Nicolazzo JA, Pouton CW, Short JL (2013) Investigating the potential of stem cell based therapy in an immunotoxin mouse model of Alzheimer’s disease. Neuroscience 2013 Abstracts 712.19. Society for Neuroscience, San Diego, CA.

Summary: Purpose: Alzheimer’s disease (AD) is a neurodegenerative disorder characterized by reduced cognitive function. Stem cell based therapeutic approaches are a potential therapeutic option. In order to investigate this possibility the study focuses on the characterization of a dual reporter embryonic stem (ES) cell line and validation of an immunotoxin mouse model of AD for future transplantation experiments. Methods: A dual (mcherry and Lhx8+) reporter ES cell line was derived from the E14Tg2a mouse ES cell line. The ES cells were assessed for their differentiation capability and characterized using mmunocytochemistry. For the immunotoxin model, 6-8 week old C57BL/6 male mice (n = 12) were treated with bilateral intracerebroventricular injections of saline (control) or mu-p75-saporin toxin (0.4µg/µl/mouse) to cause cholinergic neuronal lesions. Mice were cognitively assessed using a novel three day water maze (WM) protocol and the novel object recognition (NOR) paradigm. Immunohistochemistry was done to detect the toxin dependent loss of cholinergic neurons. Results and conclusions: A significant difference in learning the WM task was observed during cued and spatial trials, with toxin-treated mice taking longer to reach the platform than control mice (two way ANOVA; p<0.01). Performance in the WM during the probe trial was also significantly reduced in toxin-treated mice, compared to control mice (t-test; p<0.05), indicating memory loss in toxin-injected mice and better learning in the saline-treated controls. However, no memory impairment was detected using the NOR test. Immunohistochemistry for choline acetyltransferase (ChAT) confirmed a significant loss (p<0.0001; t test) of cholinergic neurons in the medial septum. These data indicate that the toxin model is appropriate for use in subsequent transplantation studies. FACS analysis of the reporter cell line showed the presence of a small population of Lhx8+ cells at day 6 and 10 of differentiation. Immunocytochemistry for ChAT on day 18 cells revealed the presence of a few cholinergic positives neurons as compared to wild type controls. Literature suggests a possible role of Lhx8 in cholinergic development and these cells will be investigated further in order to select cholinergic progenitors for transplantation.

Related Products: mu p75-SAP (Cat. #IT-16)

Activation of NF-κB signaling in the hippocampus without cholinergic input was aggravated by chronic stress

Lee S-Y, Kim M-S, Han J-S (2013) Activation of NF-κB signaling in the hippocampus without cholinergic input was aggravated by chronic stress. Neuroscience 2013 Abstracts 717.18. Society for Neuroscience, San Diego, CA.

Summary: Previous studies have demonstrated that loss of cholinergic input to hippocampus contributes dysfunction of HPA axis and alters GR-PKA-NF-κB signaling in hippocampus. In the hippocampus without cholinergic input, interactions of GR and PKA are decreased, whereas interactions of PKA and NF-κB are increased and phosphorylations on Ser276 of NF-κB p65 are increased. On the other hand, activation of NF-κB p65 is associated with behavioral action of stress and depression. The present research was conducted to examine whether NF-κB activation induced by cholinergic lesions is aggravated in response to chronic stress. Young adult rats received immunotoxic lesions of basal forebrain cholinergic neurons by intracranial injections of 192 IgG-saporin into the medial septum/vertical limb of the diagonal band and substantia innominata/nucleus basalis. After 2 weeks recovery from surgery, rats with cholinergic lesions and vehicle-injected control rats were subjected to 1 hr restraint stress per day for 2 weeks. We examined that cholinergic deafferentation induced alterations in GR and NF-κB p65 expression in hippocampus and prefrontal cortex. Rats with cholinergic deafferentation and chronic stress showed more activation of NF-κB p65 signaling in the hippocampus compared with rats with cholinergic deafferentation only. Thus the loss of cholinergic integrity during aging and in AD might increase proneness to chronic stress.

Related Products: 192-IgG-SAP (Cat. #IT-01)

Compensatory feeding after reversing dehydration-anorexia: Is it analogous to glucoprivic or food deprivation-induced feeding?

Vargas SL, Watts AG (2013) Compensatory feeding after reversing dehydration-anorexia: Is it analogous to glucoprivic or food deprivation-induced feeding?. Neuroscience 2013 Abstracts 757.04. Society for Neuroscience, San Diego, CA.

Summary: We use dehydration (DE)-anorexia to identify the neural networks associated with feeding behavior. How these networks are organized and interact to control ingestive behavior in both the normal and anorexic states allows us to determine how they function in health and disease. DE-anorexia involves replacing drinking water with hypertonic saline (HS) for up to 5 days. This leads to cellular dehydration, and a reduction in food and body weight. Reversing DE-anorexia by removing HS and reinstating drinking water leads to a robust feeding episode. Here we used two experiments to determine whether this water-activated compensatory feeding is functionally related to 2-deoxyglucose (2DG)-activated (glucoprivic) or to food deprivation-induced feeding. First, we determined whether forebrain-projection catecholamine (CA) neurons in the hindbrain are required for water-activated compensatory feeding. These neurons project to the paraventricular nucleus of the hypothalamus (PVH) and are required for 2DG feeding. To do this we lesioned this pathway with the retrogradely-transported immunotoxin, anti-dopamine beta-hydroxylase (DBH) Saporin (DSAP). Anesthetized adult male Sprague-Dawley rats (300g) were injected into the PVH with either a control SAP (MIgSAP) or DSAP. Three weeks later animals were housed in BioDaq monitoring cages to record their feeding behavior. All animals were given HS for 5 days. They were then given drinking water back on the 5th day, and euthanized 75 minutes later. Lack of immunohistochemical staining (IHC) for DBH in the PVH confirmed complete lesions. DSAP lesions had no significant effect on the amount eaten or the latency to begin feeding. Forebrain-projecting CA neurons are therefore not required for water-activated compensatory feeding. Second, we compared the feeding behavior of DE-rats given back water to that of food-deprived rats given food. We also examined the neuronal activity in the hindbrain of these animals using Fos. Meal pattern analysis showed little difference between groups, once feeding was initiated. Dual IHC labeling for Fos and DBH showed no colocalization following drinking water and deficit induced feeding. This contrasts with 2DG stimulated feeding. Furthermore, we show that the Fos expression in particular parts of the nucleus of the solitary tract and the parabrachial nucleus is consistent their roles in projecting visceral and gustatory information to the hypothalamus to coordinate feeding. Thus water-activated compensatory feeding engages mechanisms similar to those used during food deprivation-induced feeding rather than glucoprivic feeding.

Related Products: Anti-DBH-SAP (Cat. #IT-03)

Assessment of the contributions of baseline performance and prefrontal cortical cholinergic projections to orexin A-induced attentional enhancement.

Zajo KN, Fadel JR, Burk JA (2013) Assessment of the contributions of baseline performance and prefrontal cortical cholinergic projections to orexin A-induced attentional enhancement. Neuroscience 2013 Abstracts 854.02. Society for Neuroscience, San Diego, CA.

Summary: Orexinergic neurons innervate several brain regions including the basal forebrain, a structure known to be crucial for normal attentional performance in rats. Our previous research demonstrated that orexin receptor blockade impairs attention and that infusions of orexin A into the lateral ventricle enhance attentional performance in animals that have just reached criteria for stable performance levels on a sustained attention task. Our current research investigated whether more highly trained animals show orexin A-induced enhancement of attentional performance and whether basal forebrain cholinergic inputs to the medial prefrontal cortex were necessary for orexin A-induced attentional enhancement. Male FBNF1 hybrid rats were trained in a sustained attention task that required discrimination of visual signals (500, 100 or 25-ms illumination of a central panel light) from trials when no signal was presented. After stable performance levels were established, rats received both intraventricular guide cannula implantation and infusions of either the immunotoxin 192IgG-saporin or vehicle into the medial prefrontal cortex. Postsurgically, rats were retrained to stable performance levels and then received infusions of 0 (vehicle), 10, 100 or 1000pM orexin A in a counterbalanced order prior to task performance. On infusion days, rats were exposed to a version of the task which increased attentional demands by presenting a visual distracter during the middle block of trials within a testing session. In rats trained to higher performance levels, intraventricular orexin A infusions did not significantly enhance attentional performance. Loss of cholinergic projections to the medial prefrontal cortex decreased attentional performance, particularly when a visual distracter was presented. Attentional performance was unaffected in lesioned rats when orexin A was infused into the lateral ventricle. Our findings suggest that orexin A-induced attentional enhancement may be dependent upon baseline performance levels and possibly the integrity of the basal forebrain cholinergic projections to the medial prefrontal cortex.

Related Products: 192-IgG-SAP (Cat. #IT-01)

Male and female mice use distinct spinal immune cells to mediate chronic pain.

Sorge RE, Martin LJ, Alexander J, Beggs S, Rosen S, Zhang J, Salter MW, Mogil JS (2013) Male and female mice use distinct spinal immune cells to mediate chronic pain. Neuroscience 2013 Abstracts 642.11. Society for Neuroscience, San Diego, CA.

Summary: There are clear sex differences in the sensitivity to painful stimuli and analgesics in humans and animals. Some data suggest that pain processing is mediated by separable pathways in male and female mice, for example we recently demonstrated that spinal cord toll-like receptor 4 is used to mediate chronic pain in male, but not female mice. Here, we sought to investigate the sex-dependent pathways involved in spinal mediation of pain in male and female mice. First, we found that allodynia induced by complete Freund’s adjuvant (CFA) or spared nerve injury (SNI) was reversible via intrathecal glial inhibitors (minocycline, 0-300 μg; fluorocitrate, 0-1.5 nmol; propentofylline, 0-75 μg), or glial cell depletion using Mac1-saporin, only in male mice and never in intact female mice. This suggests that female mice utilize a microglia-independent spinal pathway to mediate chronic pain. To investigate whether T cells might mediate chronic pain in female mice, we used two strains of T cell-deficient animals; Rag1 (Rag1tm1Mom) and nude CD1 (Crl: CD1-Foxn1nu). In both strains, SNI- or CFA-induced allodynia was reversible in female mice by glial inhibitors, similar to male mice. This effect was prevented through adoptive transfer of wild type (C57BL/6) splenocytes to Rag1 female mice, suggesting T-cell involvement. T-cell infiltration into the CNS was reduced with an antibody to β1-integrin; this manipulation transiently reversed allodynia in female mice, but not male mice, further confirming that T cells mediate chronic pain in females. Finally, castration was found to reduce the anti-allodynic effect of glial inhibitors and enhanced the potential of anti-β1 integrin in male mice. In contrast, ovariectomy with testosterone replacement in female mice eliminated the effect of anti-β1 integrin and enhanced the effect of glial inhibitors. We have uncovered a robust, qualitative, and previously unknown sex difference in spinal mediation of chronic pain in mice. Attention to this critical sex difference in pain mediation may be vital to future pharmaceutical development and to interpretation of clinical pain treatments that focus on one system or the other in a mixed-sex population.

Related Products: Mac-1-SAP mouse/human (Cat. #IT-06)

The anterior claustrum and flexible behavior in the rat: A comparison of NMDA and dynorphin-saporin lesions.

Talk AC, Bernasconi D, Stevens Z, Grasby K, Edelstein L, Smythies J, Russell B (2013) The anterior claustrum and flexible behavior in the rat: A comparison of NMDA and dynorphin-saporin lesions. Neuroscience 2013 Abstracts 574.20. Society for Neuroscience, San Diego, CA.

Summary: The claustrum is a small structure of poorly understood function situated subcortically in the basal forebrain. The fact that it is extensively and reciprocally connected with the cerebral cortex has led to suggestions that it is involved in coordination of cortical activity. Here we created lesions to the anterior claustrum of rats and tested performance on tasks that involve neural processing in one or more frontal or limbic cortical structures. The excitotoxin NMDA was used to create partial lesions to the anterior claustrum. Lesions were constrained to the claustrum except in a minority of subjects. Taking into account the fact that some of the highest densities of kappa-opioid receptors in the mammalian brain are in the claustrum, in a separate study we used a custom dynorphin-saporin conjugate supplied by Advanced Targeting Systems to create lesions. We found that the claustral lesions using the targeted immunotoxin could be more complete than those provided by NMDA. In our first study, after excitotoxic lesions created by infusions of NMDA, we tested spatial reversal learning in a water maze. Lesioned rats were not impaired at acquiring the initial location of a goal platform in the maze, but were impaired at acquiring a switched location in the reversal phase. The lesioned rats also exhibited more perseverance errors compared to control rats during reversal. These same rats were not impaired at latent inhibition or working memory tasks, suggesting the effect of anterior claustral lesions may be related to behavioral flexibility. This finding is consistent with theories of claustral function that suggest it may help coordinate information necessary for cortical-dependent tasks. We are currently assessing the role of the anterior claustrum on other measures of behavioral flexibility using a cohort of rats that have been subjected to immunotoxic lesions.

Related Products: Dyno-SAP (Dynorphin-SAP) (Cat. #IT-68)

Increased hippocampal neurogenesis and prolonged amelioration of memory deficits by chronic oxotremorine treatment in a rodent model of Alzheimer’s disease.

Nair DV, Al-Badri MM, Rogido M, Pacheco-Quinto J, Peng H, Iacono D, Eckman CB, Eckman EA (2013) Increased hippocampal neurogenesis and prolonged amelioration of memory deficits by chronic oxotremorine treatment in a rodent model of Alzheimer’s disease. Neuroscience 2013 Abstracts 599.01. Society for Neuroscience, San Diego, CA.

Summary: Cholinergic transmission plays a predominant role in memory processes, and loss of basal forebrain cholinergic innervation of the hippocampus has been correlated with memory impairment in Alzheimer’s disease (AD), as well as in decreased hippocampal neurogenesis in rats. Using a rat model of AD-like basal forebrain cholinergic cell loss, our lab has previously shown that central administration of a muscarinic receptor agonist, oxotremorine, for 4 weeks could reverse the spatial working memory deficit triggered by cholinergic denervation and induce hippocampal neurogenesis. The goal of the present study was to examine whether effects of chronic oxotremorine treatment persist beyond the treatment period, possibly indicating a disease-altering effect of the drug, particularly on memory function. Adult female Sprague Dawley rats were injected intracerebroventricularly (icv) with the immunotoxin 192-IgG-saporin (SAP), to induce AD-like basal forebrain cholinergic cell loss. After a 5 week recovery period, the rats then received 8 weeks of icv infusion of either oxotremorine or saline via osmotic minipump. Behavioral testing in a partially baited radial arm maze began 4 weeks after oxotremorine treatment was discontinued. To analyze cell proliferation, rats received intraperitoneal injections of BrdU either during the first 2 weeks of treatment, or at the end of behavioral testing. One month after oxotremorine treatment was discontinued, SAP-lesioned rats showed persistent improvements in radial arm maze acquisition, such that there was no difference in performance among sham/saline, sham/oxotremorine, and SAP/oxotremorine groups. SAP-lesioned rats treated with saline, however, still showed significant impairments compared to the other groups. Neuropathological and stereological analyses of these brains are ongoing, including analysis of hippocampal neurogenesis and neuronal cell counts in both basal forebrain and hippocampal regions. In a parallel cohort of rats analyzed at the end of the 8 week treatment period, initial results indicate no change in cholinergic cell density but a modest increase in the number of GABAergic cells in medial septum/diagonal band of lesioned rats treated with oxotremorine compared to saline. In the dentate gyrus (DG) of the hippocampus, increased numbers of cells labeled with BrdU during the first 2 weeks of treatment persisted to the end of the experiment, with an overall 1.5-fold increase in the number of BrdU labeled cells detected in the DG. These findings demonstrate that muscarinic stimulation is a promising target in the development of drugs to treat disorders involving cholinergic loss, such as AD.

Related Products: 192-IgG-SAP (Cat. #IT-01)

The effect of noradrenaline depletion on motor impairment and dopamine cell loss in a rat model of Parkinson’s disease.

Shin EJ, Rogers, J, Björklund A, Carta M (2013) The effect of noradrenaline depletion on motor impairment and dopamine cell loss in a rat model of Parkinson’s disease. Neuroscience 2013 Abstracts 623.12. Society for Neuroscience, San Diego, CA.

Summary: Objective: Parkinson’s disease (PD) has been mainly known as a neurodegenerative disease with loss of dopaminergic (DA) neurons in the substantia nigra. However, studies of post mortem PD brains have shown that not only DA neurons but also the noradrenergic (NA) neurons in the locus coeruleus degenerate, and that the NA neurodegeneration may be as profound, and also precedes degeneration of the midbrain DA neurons. The early involvement of the NA system is also in line with the caudal-to-rostral disease progression predicted by the model proposed by Braak et al. Hence, we have investigated the effect of NA depletion on motor deficits and DA cell loss in a rat PD model. Methods: To generate two lesion paradigms, rats were injected with a dopamine toxin, 6-OHDA in striatum and/or a NA toxin, DBH-saporin in lateral ventricles. Animals have been tested in a battery of behavioural tests to check the degree of motor impairment. Perfused tissues were then subjected to immunohistochemistry to assess the amount of degeneration in striatal DA fiber and nigral DA neurons. Results: In three motor tests (cylinder, amphetamine-induced rotation, and corridor tests) there was no significant difference in motor deficit between groups. However, the DA- and NA-lesioned animals showed more severe motor deficits than the DA-lesioned animals in stepping, staircase, and rotarod tests. Post mortem analysis revealed that NA depletion did not affect the degree of DA loss in striatum and substantia nigra determined by optical densitometry with tyrosine hydroxylase staining and stereological cell estimation with vesicular monoamine transporter staining, respectively. These results suggest that Parkinsonian-like motor symptoms could be worsened by NA degeneration but it is not due to more profound DA cell degeneration upon NA removal but maybe by dysregulated DA cell function.

Related Products: Anti-DBH-SAP (Cat. #IT-03)

Effect of medial prefrontal subregions electrical stimulation on the neuronal activity of the primary visual cortex and basal forebrain.

Nguyen HN, Huppé-Gourgues F, Vaucher E (2013) Effect of medial prefrontal subregions electrical stimulation on the neuronal activity of the primary visual cortex and basal forebrain. Neuroscience 2013 Abstracts 639.04. Society for Neuroscience, San Diego, CA.

Summary: The cholinergic system and the medial prefrontal cortex (mPFC) play an important role in visual attention through the modulation of neuronal responses in the primary visual cortex (V1). The mPFC doesn’t project directly to V1, but does project to the horizontal limb of the diagonal band of Broca (HDB), which contains cholinergic neurons and projections to V1. Here, we investigated a possible involvement of the mPFC subregions in the activation of basal forebrain cholinergic neurons to enhance cholinergic transmission in V1. The different subregions of the mPFC, the anterior cingulate (Cg1), the prelimbic (PrL) and the infralimbic (IL) cortices, have anatomical and functional differences. Therefore the objective of this study was to determine if electrical stimulation of the different regions of the PFC activated V1 neurons in mice and if this activation was mediated through the HDB cholinergic pathway. The neuronal activity was evaluated by early gene c-Fos immunoreactivity in V1 and HDB after unilateral electrical stimulation of mPFC subregions (trains of 100 Hz for 0.3s every 2s, 50 μA, 30 mins) provided through a tungsten electrode in urethane anesthetized mice (n=4 mice per subregion). After the mPFC stimulation, mice were kept in darkness for 1h and brains were harvested after 4% paraformaldehyde intracardiac perfusion. The c-Fos expression was quantified on 35 µm coronal brain sections in V1 and HDB: an equivalent threshold was applied to all microphotographs and a c-Fos automated particle analysis tools was used (ImageJ). Moreover, the effect of the selective lesion of cholinergic fibers by the immunotoxin mu p75-saporin (1 μg/μl injections) was evaluated. The results show that electrical stimulation of PrL (Mann-Whitney U, p=0.021) and IL (p=0.021) cortices significantly induced a higher expression of c-Fos neurons in V1 of the stimulated hemisphere, but not in the HDB. Electrical stimulation of Cg1 did not elicit V1 nor HDB c-Fos immunoreactivity (p=0.248). Furthermore, selective lesions of basal forebrain cholinergic neurons did not eliminate the IL-induced c-Fos expression in the ipsilateral V1. Therefore, the mPFC stimulation seems to activate V1 neurons without the contribution of the HDB cholinergic neurons. This suggests there is a functional link between the mPFC and V1 independent from HDB cholinergic projections.

Related Products: mu p75-SAP (Cat. #IT-16)

Shopping Cart
Scroll to Top