targeted-toxins

Li A-J, Wang Q, Davis H, Ritter S (2014) Contribution of hindbrain catecholamine neurons to orexin-induced feeding. Neuroscience 2014 Abstracts 834.08. Society for Neuroscience, Washington, DC.

Summary: Both lateral hypothalamic orexinergic neurons and hindbrain catecholaminergic neurons contribute to feeding behavior. In addition, both phenotypes are widely distributed in the brain and their terminal sites are in many cases overlapping. In the hindbrain, both orexin receptor subtypes (OX1R and OX2R) have been found in close proximity to dopamine-β-hydroxylase (DBH)-expressing cell bodies, raising the question of whether orexin stimulates feeding by activating catecholamine neurons. We tested this hypothesis in the present study. First, we implanted rats with fourth ventricular (4V) cannulas and tested feeding in response to 4V injection of orexin (0.5 nmol). Orexin stimulated feeding in rats, and this stimulation was abolished in rats given paraventricular hypothalamic injections of the retrogradely-transported immunotoxin, anti-DBH-saporin, which targets and destroys DBH-expressing neurons. We then examined hindbrain c-Fos expression in normal rats in response to 4V injection of the same orexin dose that stimulated food intake. Using multiple immunofluorescent labels and confocal microscopy we found that most of the orexin-induced c-Fos-immunoreactive (-ir) neurons in the dorsomedial and ventrolateral medulla were DBH-ir and, moreover, that orexin-ir varicosities were situated in close proximity to the Fos-expressing DBH-ir soma. Together these results suggest that orexin stimulates feeding, at least in part, by activating hindbrain catecholamine neurons.

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

Hulsey D, Hays S, Khodaparast, N, Casavant R, Ruiz A, Das P, Nutting E, Carrier X, Iyengar M, Quareshi I, Sultana S, Rennaker R, Kilgard M (2014) Vagus nerve stimulation dependent enhancement of cortical plasticity requires cholinergic innervation of the cortex. Neuroscience 2014 Abstracts 542.20. Society for Neuroscience, Washington, DC.

Summary: Primary motor cortex (M1) transiently reorganizes in response to motor skill learning. Pairing forelimb movements with Vagus Nerve Stimulation (VNS) drives enhanced and robust analogous plasticity within M1. These changes occur outside of the typical period for motor plasticity and are independent of new skill learning. The mechanism by which VNS enhances M1 plasticity is not well understood. Skill learning and the associated cortical plasticity is dependent on cholinergic innervation of the cortex. VNS may enhance plasticity by engaging neuromodulatory systems necessary for plasticity. We hypothesize that cholinergic innervation of M1 is necessary for motor plasticity associated with VNS pairing. To test this hypothesis, we trained female Sprague Dawley rats on a skilled lever pressing task emphasizing use of the proximal forelimb. After task acquisition, one group of rats received a lesion to the cholinergic neurons of the basal forebrain using 192-IgG-Saporin, while another group received a control injection. All subjects also received a VNS cuff implant during the surgery. After one week of recovery, all subjects receive VNS paired to successful task performances for five days. Intracortical microstimulation was performed to derive M1 maps of each group 24 hours after their final VNS paired session. Subjects with an intact cholinergic system show significant expansion of proximal forelimb representation over naïve animals within the cortex. Subjects without cholinergic innervation of the cortex show no difference in M1 organization when compared to naïve animals. We conclude that cholinergic innervation is necessary for the effects of VNS on motor plasticity.

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

Fraley GS (2014) Immunolesions of melanopsin receptive neurons in the adult Pekin drake attenuates the hormonal reproductive axis. Neuroscience 2014 Abstracts 543.01. Society for Neuroscience, Washington, DC.

Summary: Several light sensitive receptors have been described in the avian brain that are thought to regulate the reproductive axis independently from the eyes and pineal gland. Recently, my lab has described the presence of three of these photoneuroendocrine systems in the Pekin duck: opsin, opsin 5, and melanopsin. I set out to test the hypothesis that melanopsin receptive neurons are necessary to maintain seasonal reproductive status in the Pekin drake. To accomplish this, 50-week-old Pekin drakes were housed in the aviary at Hope College under long day length (18 hrs lights on) conditions in floor pens (5 drakes per pen). To specifically lesion melanopsin-receptive neurons, drakes were anethestized (8 mg/kg Propofol, IV), given analgesics (2 mg/kg ketfen, SC) skin incised and a trephine hole drilled 10 mm caudal to bony orbits and 1 mm to the left of midline. A 33 gauge stainless steel needle attached to a Hamilton syringe was lowered stereotactically 3.5 mm ventral to dura into the lateral ventricle. Three microliters of an anti-melanopsin-saporin conjugate (MSAP, 100 ng/ul) was injected into the lateral ventricle (n = 10). Control drakes were injected with 3 ul of equimolar unconjugated anti-melanopsin and saporin (SAP, n = 10). The incision was closed with VetBond, and the drakes returned to the aviary after complete recovery from anesthesia. After 4 weeks, birds were euthanized (400 mg/kg FatalPlus, IP) and body weight measured, and brains, pituitaries, and testes collected and stored for analyses. MSAP-treated drakes had significantly (p < 0.001) reduced relative teste weights compared to SAP controls. qRT-PCR analyses (n = 5 per treatment) of anterior pituitary showed a significant reduction (p < 0.001) in both LH-beta and FSH mRNA’s. Immunoctyochemical analyses (n = 5 per treatment) showed a significant reduction in melanopsin and GnRH-immunoreactivities. These data underscore the importance of the photoneuroendocrine system in maintaining the reproductive axis in seasonally breeding birds.

Related Products: Melanopsin-SAP (Cat. #IT-44)

Helena CV, Toporikova N, Kalil B, Stathopoulos AM, Anselmo-Franci JA, Bertram R (2014) Involvement of kndy neurons in luteinizing hormone surges induced by steroids. Neuroscience 2014 Abstracts 543.11. Society for Neuroscience, Washington, DC.

Summary: A subset of hypothalamic arcuate neurons that coexpress kisspeptin, neurokinin B and dynorphin (KNDy neurons) has been postulated to be critical for puberty onset and regulation of luteinizing hormone (LH) secretion. A method for targeted ablation of KNDy neurons was recently developed using the molecular neurotoxin saporin conjugated to the selective NK3R agonist [MePhe7]Neurokinin B (Nk3-SAP). Ovariectomized rats were microinjected bilaterally into the arcuate nucleus with Blank-SAP or Nk3-SAP. One set of rats was transcardiacally perfused 1, 2 or 3 weeks after the injections and immunocytochemistry for kisspeptin was performed in the arcuate nucleus region. The number of KNDy neurons was significantly decreased after 1 week of the toxin injection, however maximal fiber ablation was only achieved 3 weeks after the microinjections. Another group of rats was treated with oil (OVO), estradiol (OVE) or estradiol plus progesterone (OVEP). One week later, rats had their jugular vein cannulated and blood samples were taken at 10am and hourly from 3 until 6pm. Selective ablation of KNDy neurons of OVO rats significantly reduced basal LH levels at all time points studied. Basal LH levels in OVE and OVEP animals did not differ between groups, yet KNDy ablation increased peak LH levels in the afternoon of OVE and OVEP rats. A third group of OVE animals was microinjected with norbinaltorphimine (nor-BNI), a kappa opioid receptor antagonist, directly into the anteroventral periventricular nucleus (AVPV) one hour before the expected LH surge. The blockage of dynorphin receptors intra-AVPV significantly increased the LH surge, similar to the effect of KNDy ablation in OVE rats. Our results suggest that KNDy neurons provide inhibition to AVPV kisspeptin neurons through dynorphin and thus regulate the size of the LH surge induced by estradiol or estradiol plus progesterone.

Related Products: NKB-SAP (Cat. #IT-63)

Kohls MD, Lappi DA, Ancheta LR (2014) Properties of recombinant isolectin B4 (IB4): Binding and immunostaining. Neuroscience 2014 Abstracts 627.07. Society for Neuroscience, Washington, DC.

Summary: Isolectin B4 (IB4) is a protein found in the seeds of Griffonia simplicifolia, a woody climbing shrub native to western and central Africa. Although initially used as an identifier and agglutination agent for B-type red blood cells, it has since become widely used in the neurosciences as a neuronal tracer, for labeling specific populations in the spinal cord, and as a targeting moiety for delivering toxins to specific cells. Recent developments in response to competition from the nutritional supplement industry have reduced the available supply of seeds from which the native protein is purified. In order to create a consistent supply of pure and active IB4 we have determined the full nucleotide sequence of the IB4 gene, cloned it from Griffonia genomic DNA, and expressed recombinant IB4 in E. coli. The recombinant IB4 (rIB4) was purified and tested in several activity assays against the native protein. A fusion protein of rIB4 and GFP was created to demonstrate the use of this protein in immunostaining. Griffonia also contains isolectin A that agglutinates A-type red blood cells – the A and B lectins form tetramers with varying subunit combinations. These tetramers are potential sources of contamination in preparations of the native protein. rIB4 is completely free of any A lectin contamination. The rIB4 is highly pure, and has identical activity to the native protein.

Related Products: IB4-SAP (Cat. #IT-10)

Li J, Nelson D, Gibbs R (2014) Cholinergic regulation of aromatase in brain. Neuroscience 2014 Abstracts 640.10. Society for Neuroscience, Washington, DC.

Summary: Our goal is to understand mechanisms by which estrogens can influence brain function and cognition. Estrogens have been shown to influence neuronal plasticity and cognitive performance. Recent studies suggest that, in some cases, local estrogen synthesis can have a greater impact on neuronal survival and plasticity than systemic estrogen administration. Cholinergic projections also have a significant impact on neuronal plasticity in the brain, and recent studies demonstrate critical links between effects of estrogens and effects mediated by cholinergic inputs. In this project we are investigating whether aromatase expression and activity in specific regions of the adult brain are regulated by cholinergic activity. In one experiment, ovariectomized (OVX) rats were treated with the cholinesterase inhibitors donepezil (3 mg/Kg) or galantamine (5 mg/Kg) daily for one week prior to tissue collection. In a second experiment, OVX rats received intraseptal infusions of 192IgG-saporin (SAP) to selectively destroy cholinergic inputs to the hippocampus. Tissues were collected two weeks following the infusions. Different groups of rats were used to evaluate effects on aromatase mRNA and aromatase activity. Effects on aromatase mRNA were evaluated using qRT-PCR. Effects on aromatase activity were evaluated using a novel microsomal assay in which brain tissue microsomes were extracted and activity was measured in vitro by measuring conversion of testosterone to estradiol. Results show an increase in aromatase mRNA in the preoptic area following treatment with galantamine, but no effect in the hippocampus, frontal cortex, or amygdala. Galantamine also produced an increase in aromatase activity in the amygdala, but no significant effect in other brain regions. Donepezil had no significant effects on either aromatase mRNA or activity. Effects of the cholinergic lesions are still being evaluated; however, preliminary results suggest no significant effect on relative levels of aromatase mRNA in the hippocampus. These results indicate that cholinergic manipulations can affect aromatase expression and activity in specific regions of the brain such as the preoptic area and amygdala, with little or no effect in the hippocampus and frontal cortex. This could have important implications for the effects of cholinergic and anticholinergic medications on local estrogen production in the brain.

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

Patrone LA, Biancardi V, Bicego KC, Gargaglioni LH (2014) Medullary catecholaminergic (CA) neurons modulate hypoxic ventilatory response in neonatal rats (P7-8). Neuroscience 2014 Abstracts 643.10. Society for Neuroscience, Washington, DC.

Summary: It is known that catecholaminergic (CA) neurons are involved in autonomic and respiratory regulation during low O2 conditions in adult mammals. We evaluated the participation of medullary CA neurons of male and female neonatal rats (P7-8) in mediating the hypoxic ventilatory response (HVR) by specifically lesioning them with antidopamine beta-hydroxylase-saporin (DBH-SAP, 42ng / 100nL) injected into the 4th ventricle. We also quantified rates of O2 consumption (VO2) of control and lesioned neonates (P7-8) exposed to hypoxia. Minute ventilation (VE) of neonates was recorded by pressure-plethysmography from the body chamber during normoxia and hypoxia (10% O2), and the VO2 measurement by open flow respirometry. The mammalian HVR typically results in increased VE upon exposure to acute hypoxia. HVR was significantly reduced in male and female lesioned neonatal rats by about 23 and 15%, respectively, (male- control group: 137.3±7.9 (% of baseline) vs. lesioned group: 105.3±2.4 (% of baseline), p<0.01; female- control group: 127.0±3.0 (% of baseline) vs. lesioned group: 108.6±1.7 (% of baseline) p<0.02). The VO2 was decreased in the lesioned newborns, but only the lesioned male group was significantly lower (control group: 76.8±12.14 (% of baseline) vs. lesioned group: 45.3±13.3 (% of baseline) p<0.03). These results suggest that catecholaminergic neurons, specifically from medullary nuclei, exert an excitatory modulation of O2 chemosensitivity in neonatal rats.

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

Shim H, Park H-J, Lee H, Shim I (2014) The role of the supramammillary area in spatial learning and memory. Neuroscience 2014 Abstracts 652.05. Society for Neuroscience, Washington, DC.

Summary: The supramammillary area (SuM) of the hypothalamus, although small in size, has wide spread connection with numerous brain structures. It is known that the SuM can control the frequency of the hippocampal theta rhythm, which plays a role in the cognitive functions of the hippocampal formation. In order to examine the role of the specific cells of the SuM in learning and memory, selective cholinergic neurotoxic or excitotoxic lesioned rats of the SuM were tested for spatial memory on the Morris water maze (MWM) test. After the behavior tests, the expression of acetylcholine esterase (AChE) in the hippocampus was studied using the immunohistochemistry. In the MWM test, both lesion of the SuM with 192 IgG-saporin and ibotenic acid produced the impairment of spatial learning and memory. In the immunohistochemistry, the SuM-lesioned rat model by selective cholinergic neurotoxin showed decrease in the AChE expression in the hippocampal CA3. These findings suggest that cholinergic cells of the SuM area play a critical role in the process of consolidation of memory.

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

Tiwari D, Haynes J, Short J, Pouton C (2014) Investigating the potential of stem cell based therapy in an immunotoxin mouse model of Alzheimer’s disease. Neuroscience 2014 Abstracts 295.14. Society for Neuroscience, Washington, DC.

Summary: Purpose: To characterize a dual reporter embryonic stem (ES) cell line and validate an immunotoxin mouse model of Alzheimer’s disease for future transplantation experiments. Methods: A dual (mcherry and Lhx8+) reporter ES cell line was derived from E14Tg2a mouse ES cells assessed for differentiation capability and characterized using immunocytochemistry. For the immunotoxin model, 6-8 weeks C57BL/6 male mice (n = 12) were treated with bilateral intracerebroventricular injections of saline or mu-p75-saporin toxin (0.4µg/µl/mouse) to cause cholinergic neuronal lesions. Mice were cognitively assessed using a novel water maze (WM) protocol and novel object recognition (NOR) paradigm. Immunohistochemistry was performed to detect toxin dependent neuronal loss. Results: A significant difference in learning the WM task was observed during cued and spatial trials, with toxin-treated mice showing longer latency to platform than controls (two way ANOVA; p<0.01). Also performance during probe trial was significantly reduced in treated mice (t-test; p<0.05), indicating memory loss by toxin. No memory impairment was detected using the NOR test. Immunohistochemistry for choline acetyltransferase (ChAT) confirmed a significant loss (p<0.001; t test) of cholinergic neurons in the medial septum. These data indicate that the model is appropriate for future transplantation studies. FACS analysis of reporter cell line showed a small population of Lhx8+ cells at day 6 and 10 of differentiation. Immunocytochemistry for ChAT on day 18 cells revealed few cholinergic positives neurons as compared to wild type controls. Conclusion: Literature suggests a possible role of Lhx8 in cholinergic development and these cells are being further investigated by transplantation.

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

Llorente A, Gonzalez De San Roman E, Moreno M, Manuel I, Giralt M, Rodriguez R (2014) Activity mediated by neurolipid (CB1 and LPA1) and neuropeptide (GAL1) receptors in a rat model with cholinergic basal forebrain lesion. Neuroscience 2014 Abstracts 307.25. Society for Neuroscience, Washington, DC.

Summary: The cholinergic basal forebrain neurons (CBFN) which innervate cortical, hippocampal and amygdaloid areas, control learning and memory processes and are damaged in Alzheimer´s disease. An intraparenquimal injection of the 192IgG-saporin (SAP) immunotoxin, specifically eliminates CBFN. The present study examined the activity of endocannabinoid (CB1), lysophosphatidic acid (LPA1), galanin (GAL1) and muscarinic (MR) receptors, measuring Gi/o protein activation by [35S]GTPγS autoradiography in rats after the selective cholinergic basal forebrain lesion. CB1 immunoreactivity (CB1-ir) was also analyzed in the SAP administration area. We observed a high CB1-ir in the basal forebrain of the lesioned rats. The autoradiographic assays revealed that WIN55,212-2 (10 μM) evoked stimulation (CB1 activity) was increased in lateral olfactory tract (data expressed in % stimulation over basal; CSF vs SAP; 55 ± 11% vs 128 ± 13%, p<0.05) and in entorhinal cortex (156 ± 17% vs 277 ± 30%, p<0.01), but decreased in hippocampal dentate gyrus (299 ± 37% vs 166 ± 21%, p<0.05) and in medial amygdala (116 ± 20% vs 50 ± 7%, p<0.05). LPA (10 μM) induced stimulation (LPA1 activity) showed an increase in the internal capsule (60 ± 10% vs 137 ± 19%, p<0.01). The MR activity that was measured using carbachol (100 μM) was increased in hippocampal dentate gyrus (27 ± 6% vs 62 ± 7%, p<0.05) and in entorhinal cortex (55 ± 10% vs 94 ± 11%, p<0.05) but decreased in the nucleus basalis of Meynert (nbM) (46 ± 10% vs 15 ± 6%, p<0.05). Finally, there was an increased stimulation (GAL1 activity) of galanin (1 μM) in the nbM (45 ± 13% vs 80 ± 12%, p<0.05). The CB1-ir and GAL1 activity was increased in the lesioned area where the cholinergic neurotransmission was impaired, indicating a possible neuroprotective action on the surviving CBFN.

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