References

Lowrance SA, Matchynski JJ, Rossignol J, Dekorver N, Fink K, Salibi P, Dunbar GL (2010) Krx-0501 reduces cognitive deficits in a saporin mouse model of Alzheimer’s disease. Neuroscience 2010 Abstracts 856.8/I14. Society for Neuroscience, San Diego, CA.

Summary: Alzheimer’s disease (AD) is a progressive neurodegenerative disease marked by memory loss and dysfunction of cholinergic neurons. Neurotrophic factors, like nerve growth factor (NGF), have shown to improve cognitive function in AD patients. The inability of NGF to cross the blood brain barrier (BBB) and painful side effects have caused serious concerns over its future use as a treatment. Substituted pyrimidines, such as KRX-0501 (KRX; Keryx Biopharmaceuticals, New York, NY) on the other hand, readily cross the BBB and exert beneficial neurotrophic-like effects in vivo. In this study KRX was administered daily to mice that were given intra-cerebroventricular injections of mu p-75 Saporin (SAP; Advanced Targeting Systems, San Diego, CA) or vehicle (phosphate buffered saline). KRX treatment began at seven weeks of age and continued for 32 days. Doses were set at 10, 15, and 20mg/kg respectively. Animals were tested for cognitive impairment using the Morris water maze (MWM) task, object recognition (OR) and place recognition (PR) tasks while motor deficits were tested using MWM swim speed, rotarod (RR) and the open field (OF) tasks. On day 33 of KRX treatment, mice were sacrificed by transcardial perfusion. In a second experiment, mice received SAP or vehicle surgery and were sacrificed for enzyme-linked immunosorbent assay (ELISA) analysis. MWM results revealed significantly lower escape latencies of control animals relative to SAP animals. In addition mice treated with the low and middle doses of KRX displayed decreased escape latency on the MWM. In the OR task, only mice in the highest treatment group performed significantly above chance levels. No between group differences were seen in the PR task, swim speed, latency to fall from the RR, and distance travelled in the OF. Immunohistochemistry (IHC) using the glial fibrillary acidic protein antibody indicated that astrocyte activation took place primarily around the surgical injection sites. IHC labeling against choline-acetyltransferase revealed a significant decrease in cholinergic neurons of the medial septum. Finally, ELISA protein analysis of midbrain sections revealed that the KRX treatments did not increase levels of endogenous NGF. These results show that SAP injections produced a reproducible destruction of cholinergic neurons, accompanied by memory deficits in the MWM, in the absence of motoric deficits. The KRX treatment attenuated memory deficits, despite unabated cholinergic cell loss in the medial septum, and did so without affecting levels of endogenous NGF.

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

Carvalho AF, Van Bockstaele E (2010) Defining the role of norepinephrine in cannabinoid-induced aversion and anxiety. Neuroscience 2010 Abstracts 833.3. Society for Neuroscience, San Diego, CA.

Summary: In the central nervous system, cannabinoids have been shown to regulate neurotransmitter release, control the hypothalamic-pituitary-adrenal axis and impact several physiological systems, such as food intake, pain and emotion perception. Manipulation of the cannabinoid system using exogenous compounds has been explored as a potential therapeutic for several disorders; however some severe side effects have been reported. Understanding the neural circuits and neurochemical substrates impacted by cannabinoids will provide a better means of gauging their actions within the central nervous system that may contribute to the expression of unwanted side effects. Previous work from our lab had shown that the cannabinoid receptor (CBr) agonist WIN 55,212-2 is able to induce changes in noradrenergic transmission in limbic structures such as prefrontal cortex (PFC) and the nucleus accumbens (Acb). Moreover, we have previously reported that norepinephrine in the nucleus accumbens (Acb) is critical for WIN 55,212-2-induced aversion, as measured by the place conditioning paradigm. In the present study, we further explore the role of norepinephrine in cannabinoid-induced behaviors. More specifically, we investigate whether norepinephrine in the limbic forebrain of rats is important for the anxiety induced by WIN 55,212-2 (3.0 mg/kg, i.p.). Lesion of noradrenergic neurons in the Acb and bed nucleus of the stria terminalis (BNST) was achieved by the intracerebral injection of the toxin saporin conjugated with an antibody that recognizes the enzyme dopamine-beta-hydroxylase (DBH). This toxin yields a specific lesion of noradrenergic neurons. The anxiogenic effects of WIN 55,212-2 were then measured in the elevated zero maze. The results show that depletion of noradrenergic innervation of the Acb and BNST did not reduce the anxiogenic properties of WIN 55,212-2. These results, together with our previous findings, suggest that the anxiogenic and aversive properties of the CBr agonist WIN 55,212-2 are differentially regulated, with the aversive effects being dependent on noradrenergic transmission within the Acb and the anxiogenic effects being regulated by a, yet to be determined, alternative mechanism/circuit.

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

Koppen JR, Winter SS, Cheatwood JL, Wallace DG (2010) Role of the septohippocampal GABAergic system in spatial orientation. Neuroscience 2010 Abstracts 806.16/KKK21. Society for Neuroscience, San Diego, CA.

Summary: Spatial orientation depends on the integrity of multiple neural systems. For example, during the progression of Alzheimer’s Disease, degeneration of the basal forebrain is associated with cognitive impairments including episodes of wandering. The medial septum projects both cholinergic and GABAergic fibers into the hippocampus. Research and therapies have typically focused on enhancing function of the cholinergic component; however, the GABAergic component has also been shown to contribute to hippocampal function. Previous attempts to characterize the role of the GABAergic system in spatial orientation involved non-selective lesion techniques in combination with the water maze task have failed to characterize the nature of the deficit mediating the impaired performance. Development of GAT1-Saporin immunotoxin provides a novel tool to selectively destroy GABAergic neurons in the medial septum. The current study examined the effects of injecting GAT1-Saporin or saline (sham lesion) into the medial septum on spatial orientation using the food-hoarding paradigm. The food-hoarding paradigm involves training rats to search for food pellets on a large circular table and carrying the food pellet directly to a visible refuge. Three probes dissociate the use of environmental and self-movement cues: 1) Hidden probe involved placing the refuge below the surface of the table, limiting rats to use distal environmental or self-movement cues to locate the refuge; 2) Dark Probe involved using the hidden refuge with the room lights off, limiting rats to use self-movement cues to locate the refuge; 3) New probe involved placing the hidden refuge on the opposite side of table, placing environmental and self-movement cues in conflict. Both sham and GAT1-Saporin rats were accurate in returning to the refuge during the Hidden probe. Only sham rats were accurate in carrying food to the refuge during the Dark probe. During the New probe, both groups initially carried the food pellet to the former refuge location. Although sham rats consistently carried the food pellet to the new refuge location after their initial error, GAT1-Saporin rats continued to perseverate to the former refuge location. The current study demonstrates a role for the septohippocampal GABAergic system in spatial orientation related to processing self-movement cues.

Related Products: GAT1-SAP (Cat. #IT-32)

Ljubojevic V, Luu P, De Rosa E (2010) Cholinergic modulation of both visual and olfactory attention with the five-choice serial reaction time test. Neuroscience 2010 Abstracts 535.8. Society for Neuroscience, San Diego, CA.

Summary: The nucleus basalis magnocellularis (NBM) sends acetylcholine (ACh) to neocortical regions that are involved in attentional cognitive processes. Using the five choice serial reaction time task (5CSRTT), the rodent analog of sustained attention in the human cognitive literature, it has been shown that a loss of cholinergic cells in the NBM causes impaired visual attentional performance in rats (Lehmann et al., 2003; McGaughy et al., 2002). The present research examined the neurochemical modulation of attentional processes using both a visual and an olfactory version of the 5CSRTT. To that purpose, we trained 14 male adult Long-Evans rats to attend and react to the briefly presented visual or odor stimuli until they achieved a stable performance under the baseline task conditions, i.e., low attentional demand with stimulus duration (SD) of 1s. Following the successful acquisition of both versions of the 5CSRTT, the rats were subjected to selective cholinergic lesions of the NBM with the cholinergic immunotoxin 192 IgG-saporin to remove the cholinergic innervation from the neocortical mantle. This allowed an examination of the role of ACh in modulation of visual and olfactory attention. After the two week post-surgical recovery period, we compared the attentional performance of the saporin-lesioned (SAP) group (N=8) to that of the sham-lesioned (SHAM) group (N=6) on the two versions of the 5CSRTT task. We observed the impaired attentional performance of the SAP rats on the visual 5CSRTT under the baseline conditions (SD=1s); shortening the SD = 0.5s increased the extent of their deficits. With the olfactory 5CSRTT, the SAP impairment was only observed under the attentional challenge of SD=0.5s. However, in both modalities the difference between two groups trended toward statistical significance due to the low number of the experimental subjects in each group. We are currently performing further parametric manipulations to further challenge the rats in both modalities. We will then collect data from an additional 14 rats to increase the statistical power of our experiment. After the completion of the behavioral data collection, we will conduct acetylcholinesterase histochemistry and choline acetyltransferase immunohistochemistry in order to determine the extent of the loss of cholinergic afferents in fronto-parietal target cortical areas and the loss of cholinergic cell bodies in the NBM, respectively. In addition, parvalbumin immunohistochemistry will be carried out to quantify GABA-releasing neurons colocalized in NBM to confirm the selectivity of our lesion.

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

Chatterjee K, Lemons LL, Wiley RG (2010) Targeting inhibitory neurons in the superficial dorsal horn: Somatostatin-saporin. Neuroscience 2010 Abstracts 585.1/XX15. Society for Neuroscience, San Diego, CA.

Summary: Intrathecal injection of somatostatin (SST), or the long-acting congener, octreotide, have been reported analgesic in humans with intractable pain. The principal SST receptor, sst2a, is expressed by GABAergic neurons in the superficial dorsal horn of the spinal cord. In the present study, we sought to determine the nocifensive behavioral effects of selectively destroying sst2a-expressing dorsal horn neurons using intrathecal injection of the targeted toxin, SST-saporin. SST-sap (500-625 ng) was injected intrathecally into rats followed by thermal plate and thermal preference shuttle box testing for up to three weeks. One of three rats injected with 625 ng of SST-sap developed severe persistent scratching of its lower body. Compared to vehicle controls and rats injected with 500 ng of corticotrophin releasing factor (CRF)-saporin, the SST-sap rats showed initially prolonged latencies and decreased nocifensive reflex responses on the 44 C hotplate that persisted for up to 17 days before returning to control levels. SST-sap rats also showed decreased reflex responses on the 0.3 C cold plate. Lastly, SST-sap rats showed no change in thermal preference in a shuttle box with floor temperatures of 15 C vs 45 C. CRF-sap rats showed delayed onset (after 8 days) of decreased hotplate responding and increased hot side occupancy in the thermal preference shuttle box. These results suggest, at the doses used, that SST-sap produced incomplete depletion of target neurons followed by compensatory plasticity, whereas, CRF-sap produced no primary effect but induced secondary plasticity resulting in long term decrease in responses to aversive heat. Higher dose studies and anatomic analysis of lesions produced by these agents are planned.

Related Products: CRF-SAP (Cat. #IT-13)

Wiley RG, Lemons LL, Chatterjee K (2010) Targeting inhibitory neurons in the superficial dorsal horn: Neurotensin-saporin (NTS-sap) and neurotensin-cholera toxin A subunit (NTS-CTA). Neuroscience 2010 Abstracts 585.2/XX16. Society for Neuroscience, San Diego, CA.

Summary: Neurotensin (NTS) and high affinity neurotensin receptors (NTSR-1) are found in the superficial dorsal horn, primarily lamina II. Intrathecal NTS has been reported to be anti-nociceptive, naloxone does not block the anti-nociceptive effects of intrathecal NTS and NTS acting at the NTSR-1 is excitatory. Based on these facts, we hypothesized that intrathecal neurotensin produces anti-nociception by exciting inhibitory interneurons in the superficial dorsal horn. In the present study, we sought to determine the effects, on modified thermal plate responses, of lumbar intrathecal injections of NTS-saporin, that is expected to selectively kill NTSR-1-expressing dorsal horn neurons, and NTS-Cholera toxin A subunit (NTS-CTA), that is expected to excite the same neurons. NTS-sap (200-625 ng) produced sustained, remarkable, vigorous scratching of hindquarters, often to the exclusion of any other activity. 12-15 ng of NTS-sap produced no scratching and increased lick/guard responding on the 44 C hotplate. Lumbar intrathecal injections of NTS-CTA (500 ng) produced profound decrease in lick/guard responding on the 44.5 C hotplate that lasted for 100-150 hours. This unique pattern of effects is consistent with the hypothesis that NTSR-1-expressing lamina II dorsal horn neurons are both inhibitory and anti-nociceptive. These results also are consistent with the intrathecal injections of NTS-CTA producing sustained excitation of these inhibitory interneurons resulting in inhibition of nociceptive projection neurons. This strategy of exciting NTSR-1-expressing inhibitory interneurons of the superficial dorsal horn is a novel approach to achieve non-opioid-mediated analgesia which may prove valuable in treating refractory chronic pain.

Related Products: Neurotensin-SAP (Cat. #IT-56), Neurotensin-CTA (Cat. #IT-60)

Lemons LL, Chatterjee K, Wiley RG (2010) Neuropeptide receptor co-expression in superficial dorsal horn: Effects of galanin-saporin, neuropeptide y-saporin and dermorphin-saporin. Neuroscience 2010 Abstracts 585.5/XX19. Society for Neuroscience, San Diego, CA.

Summary: We have previously shown that the role of specific neurons in behavioral processes can be fruitfully studied using targeted toxins. Toxins composed of a targeting neuropeptide coupled to the ribosomal-inactivating toxin, saporin, are used to selectively destroy superficial dorsal horn neurons expressing the cognate peptide receptors followed by assessment of changes in pain behavior. In the present study, we sought to compare the anatomic effects of three closely related targeted toxins, each with different nocifensive behavioral effects. Rats were given single lumbar intrathecal injections of either galanin-saporin (Gal-SAP), neuropeptide Y-saporin (NPY-SAP), or dermorphin-saporin (Derm-SAP). Lumbar spinal cord sections from each rat were stained for each of the three receptors, GalR-1, Y1R and MOR (mu opiate) using standard immunoperoxidase technique. Each toxin produced a significant decrease in staining for its cognate receptor. Gal-SAP animals showed no change in either MOR or Y1R staining. NPY-SAP rats showed decreased staining for both GalR1 and MOR, and Derm-SAP rats were assessed for changes in expression of GalR1 and Y1R. These findings suggest overlaps between the populations of neurons that express the GalR1, Y1R, and MOR. Specifically, Y1R-expressing neurons also express GalR1 and MOR, probably by separate subpopulations of Y1R neurons. The results also suggest either that Gal-SAP only kills neurons that do not express either of the other two receptors, or some of the observed loss of receptors after NPY-SAP is due to secondary (transsynaptic) effects. Double- and triple-label fluorescent immunohistochemistry will be used to directly visualize receptor co-expression patterns and targeted toxin effects. These results will be valuable in interpreting the unique nocifensive behavioral effects of each of these targeted toxins.

Related Products: Dermorphin-SAP / MOR-SAP (Cat. #IT-12), Galanin-SAP (Cat. #IT-34), NPY-SAP (Cat. #IT-28)

Roland JJ, Janke KL, Savage LM, Servatius RJ, Pang KCH (2010) Damage of GABAergic neurons in the medial septum-diagonal band (MSDB) reduces behaviorally-activated hippocampal acetylcholine efflux and impairs spatial working memory. Neuroscience 2010 Abstracts 611.13/MMM64. Society for Neuroscience, San Diego, CA.

Summary: The septohippocampal pathway is mostly composed of cholinergic and GABAergic projections and has an established role in learning, memory and disorders of cognition. Most studies have focused on the role of the cholinergic system in learning, memory and disorders of cognition. Although MSDB cholinergic lesions do not result in learning impairments, changes in hippocampal acetylcholine (ACh) levels have been tied to memory functions where deficits or enhancements in memory were correlated with hippocampal ACh decreases or increases, respectively. The activity of MSDB cholinergic neurons is greatly influenced by GABAergic afferents, including those from GABAergic neurons within the MSDB. Recently, we’ve demonstrated that toxins that preferentially damage MSDB GABAergic neurons impair delayed match to position tasks, but not spatial reference memory. Interpretation of these results needs to take into account the fact that a MSDB GABAergic lesion would influence both septohippocampal cholinergic and GABAergic transmission. The current study examined the effect of MSDB GABAergic lesions on spontaneous alternation (Experiment 1) and a non-matching to position task (NMTP; Experiment 2) while concurrently using in vivo microdialysis to measure hippocampal ACh efflux. Adult male Sprague-Dawley rats received vehicle (PBS) or GABAergic (GAT-1 saporin) MSDB lesion and a hippocampal microdialysis cannula. In Experiment 1, treatment groups did not differ in terms of activity, alternation rates, or baseline and maze-activated ACh efflux. In Experiment 2, hippocampal ACh efflux was measured at two time points (early and late) across the acquisition of a delayed NMTP task. Overall, GAT1-saporin treated rats had lower accuracy scores across 10 days of maze training compared to the vehicle treated rats. Basal ACh release in the hippocampus was similar in vehicle and GAT1-saporin rats. During the two microdialysis sampling points, both groups of rats displayed significant increases in ACh efflux while performing the task. However, behaviorally activated ACh efflux was reduced in GABA-lesioned animals compared to vehicle treated rats. The results demonstrate that MSDB GABAergic lesions do not alter basal hippocampal ACh efflux, but can reduce ACh efflux when challenged cognitively. Future studies will attempt to determine whether reduced ACh efflux is due to damage of MSDB GABAergic neurons or a result of impaired working memory performance.

Related Products: GAT1-SAP (Cat. #IT-32)

Hammond R, Shinde A, Gibbs RB (2010) Effects of basal forebrain cholinergic lesions and estradiol on relative levels of estrogen receptor mRNAs in the rat forebrain. Neuroscience 2010 Abstracts 611.16/MMM67. Society for Neuroscience, San Diego, CA.

Summary: Beneficial effects of estradiol on cognitive performance are lost in response to cholinergic denervation of the hippocampus and frontal cortex. Effects of estradiol also decline with age and time following the loss of ovarian function, which parallels naturally-occurring declines in basal forebrain cholinergic function. We hypothesize that cholinergic impairment may alter the expression of estrogen receptors in specific regions of the brain, thereby decreasing estradiol effects. In the present study, quantitative RT-PCR was used to evaluate the effects of septal cholinergic lesions ± estradiol treatment on relative levels of three estrogen receptors, ERα, ERß, and GPR30. Young adult ovariectomized (OVX) rats received intraseptal injections of saline or 192 IgG-saporin (a selective cholinergic immunotoxin). One week later, rats received either silastic capsules containing 17ß-estradiol or a blank capsule, implanted s.c. Seven days later, rats were killed and the brains were dissected. Tissues from the hippocampus, frontal cortex, prefrontal cortex, striatum, and septum were collected. RNA was extracted and relative levels of ER mRNA determined. Levels within each sample were normalized to levels of GAPDH. Differences between treatments and controls were calculated using the ΔΔCt method. Preliminary data indicate that septal cholinergic lesions produced significant decreases in relative levels of ERα and ERß mRNA in the hippocampus, and an increase in ERß mRNA in the frontal cortex. Estradiol alone produced decreases in levels of ERα, ERß, and GPR30 mRNA in the frontal cortex, decreased levels of ERα and ERß mRNA in the septum, and increased levels of ERα mRNA in the striatum. In rats with cholinergic lesions that also received estradiol, decreased levels of ERα mRNA were detected in hippocampus and septum, and decreased levels of ERß mRNA also were detected in septum. Data suggest that some of the effects of cholinergic denervation on ER mRNA expression may be mitigated by estradiol treatment. These data show that cholinergic lesions significantly affect ER mRNA expression in the brain, and that effects are region-specific. Such effects could account for the loss of beneficial effects of estradiol on cognitive performance in association with age and time following menopause, as well as in association with specific neurodegenerative diseases such as Alzheimer’s disease.

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

Wiater MF, Mukherjee S, Dinh TT, Rooney E, Li A-J, Simasko SM, Ritter S (2010) The arcuate nucleus of the hypothalamus controls the circadian distribution of sleep and feeding. Neuroscience 2010 Abstracts 648.16/H17. Society for Neuroscience, San Diego, CA.

Summary: Integration of daily sleep and feeding rhythms is incompletely understood. We examined the role of the hypothalamic arcuate nucleus (Arc) in these processes using Arc microinjections of the targeted toxin, NPY-saporin (NPY-SAP), or control blank-saporin (B-SAP). NPY-sap targets and destroys NPY receptor-expressing neurons. We monitored 24 hr feeding over a 30-day period beginning 2 wks after the Arc injections, and used EEG recordings to assign vigilance states. Vigilance was divided into rapid-eye movement sleep (REMS), non-REMS (NREMS) and wake. NPY-SAP lesioned rats were hyperphagic , consuming up to 225% of pre-injection baseline. They rapidly became obese. While in the sleep-monitoring chambers, their body weight change per week ranged from 56 ± 9 g to 40.5 ± 4.5g, compared to 6 ± 0.4 g/wk for B-SAP rats. Their circadian pattern of food intake was severely disrupted, such that intake in light and dark periods were approximately equal (43% of their total intake was consumed in the light period vs. 25% in B-SAP controls). Sleep patterns were also significantly disrupted in the NPY-SAP animals. The occurrence of rapid eye movement sleep (REMS) was inverted in phase, occurring mainly at night, rather than during the day. NonREMS was distributed equally across day and night, instead of occurring predominantly during the day. However, 24-hr total REMS and NREMS time was normal. B-SAP controls had normal sleep patterns, with NREMS and REMS occurring predominantly in the light phase. To determine if the change in sleep pattern was due to the change in feeding patterns, we restricted access to food to the dark period for 4 days. NPY-SAP treated animals doubled their food intake in the dark period. However, sleep patterns were not changed compared to the ad libitum feeding period in either NPY-SAP or B-SAP rats. After 7 days of ad libitum feeding, we restricted food access to the light period for 4 days. Again, NPY-SAP animals doubled their intake during the feeding period, this time during the light phase, and sleep patterns were not changed in either group by the restricted feeding. By 100 days post-lesion, the NPY-sap animals were still obese, but the patterning and amount of their food intake were becoming similar to controls. However, when evaluated again, sleep patterns were still altered to the same degree as observed early post-lesion. These results confirm the importance of NPY-receptive Arc neurons in controlling food intake. They also reveal an unexpected role for the Arc in the timing of both NREMS and REMS that appears to be independent of the patterning of food intake.

Related Products: NPY-SAP (Cat. #IT-28), Blank-SAP (Cat. #IT-21)