References

Prakash N, Cohen-Cory SC, Frostig RD (2000) NGF-induced rapid functional plasticity in the adult rat somatosensory cortex is mediated by fibers originating in the basal forebrain cholinergic system. Neuroscience 2000 Abstracts 722.6. Society for Neuroscience, New Orleans, LA.

Summary: We have previously demonstrated, by using intrinsic signal optical imaging in vivo, that topical application of nerve growth factor (NGF) to the somatosensory cortex of an adult rat augments the functional representation of a whisker, within minutes after NGF application (Prakash et al. Nature 381:702-6, 1996). In addition, we have shown that the NGF receptor, TrkA is found on fibers projecting to the cortex. We have now tested the hypothesis that these TrkA-positive fibers originate in basal forebrain cholinergic system (BFCS) and that NGF augments the size and amplitude of a cortical representation by enhancing the release of ACh from these fibers. To this end we demonstrate: 1) that BFCS fibers indeed express TrkA receptors by co-localizing TrkA and ChAT immunostaining to single cortical fibers; 2) that removal of these cortical BFCS-fibers by injection of a specific cytotoxin, 192 IgG-saporin, prevented the NGF-induced augmentation; and 3) that topical application of the ACh agonist carbachol induced a rapid augmentation of the whisker functional representation similar to the one observed with NGF. Thus, these results firmly support our hypothesis that NGF-induced effects on cortical functional representations are mediated by the BFCS projection fibers and provide a mechanism for NGF-induced rapid plasticity in vivo.

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Khasabov SG, Rogers SD, Mantyh PW, Simone DA (2000) Responses of spinal dorsal horn neurons to capsaicin following intrathecal pretreatment with substance p-saporin toxin. Neuroscience 2000 Abstracts 635.13. Society for Neuroscience, New Orleans, LA.

Summary: Intrathecal (i.t.) application of the cytotoxic substance P-saporin (SP-SAP) conjugate is internalized by dorsal horn neurons expressing the SP receptor (SPR) and results in loss of SPR-expressing neurons. Loss of SPR+ neurons attenuates the nocifensive behavior and hyperalgesia produced by intraplantar injection of capsaicin (CAP). Here we determined the effect of SP-SAP on CAP-evoked excitation and sensitization of dorsal horn neurons to heat and mechanical stimuli. Separate groups of rats were given i.t. injection of vehicle (VEH) or SP-SAP (5´10-6mM in 10ml) 10 or 30 days prior to electrophysiological experiments. Extracellular recordings were obtained from nociceptive dorsal horn neurons classed as high threshold (HT) or wide dynamic range (WDR). Responses to mechanical (von Frey monofilaments) and heat (35°C-51°C) stimuli were obtained before and after injection of 10 mg CAP into the receptive field. In VEH-treated animals, CAP produced an intense activation of HT and WDR neurons with a mean peak discharge rate of 52.2±11.2 Hz. In addition, the mean number of impulses evoked by mechanical stimuli increased 267±33% following CAP and mean heat thresholds decreased from 44.7±1.6°C to 37.7±0.7°C. In SP-SAP treated animals, however, the peak response evoked by CAP was decreased by 61±11% as compared to control. Moreover, CAP did not significantly alter responses to mechanical or heat stimuli. These data suggest that dorsal horn neurons that possess the SPR play a critical role in the development of sensitization to mechanical and heat stimuli following CAP.

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Tarpley JW, Martin WJ, Baldwin BS, Forrest MJ, MacIntyre DE (2000) Contribution of IB4-positive sensory neurons to NGF-induced hyperalgesia in the rat. Neuroscience 2000 Abstracts 633.18. Society for Neuroscience, New Orleans, LA.

Summary: Sensory information is transmitted from the periphery to the spinal cord by distinct subsets of primary afferent neurons, including two major classes of C-fibers that are distinguished by their ability to bind the lectin IB4. IB4-positive neurons are primarily non-peptidergic, express the receptor tyrosine kinase, Ret, and are preferentially sensitive to the neurotrophic factor, GDNF. By contrast, the nerve growth factor (NGF) receptor tyrosine kinase, trkA, is predominantly expressed in IB4-negative neurons that contain substance P. Previous work suggested that depletion of IB4-positive neurons increases acute nociceptive thresholds to noxious thermal stimuli. The extent to which these non-peptidergic neurons mediate changes in nociception after injury is unknown. Here, we examined the contribution of IB4-positive, non-peptidergic, neurons to thermal and mechanical sensitivity after acute tissue injury. Baseline thermal (radiant heat) and mechanical (von Frey) thresholds were measured in rats prior to injection of IB4-saporin (5 ug/5 ul) into the left sciatic nerve. By two weeks, IB4-saporin-treated animals exhibited pronounced increases in their nociceptive thresholds to thermal and mechanical stimuli. At this time, treatment with NGF (5 ug/50 ul, i.pl.) increased paw thickness in both control and IB4-saporin-treated rats. However, nociceptive thresholds were significantly lowered in control rats, but not in those treated with IB4-saporin. This suggests that IB4-positive neurons contribute to injury-induced changes in thermal and mechanical sensitivity and provide insight into the function of this unique set of primary afferent neurons.

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Yezierski RP, Yu CG, Wiley RG (2000) Prevention and treatment of a spontaneous pain-like behavior following excitotoxic spinal cord injury (SCI) by ablation of neurons expressing the substance P receptor. Neuroscience 2000 Abstracts 733.9. Society for Neuroscience, New Orleans, LA.

Summary: Intraspinal injection of the AMPA/metabotropic agonist quisqualic acid (QUIS) leads to the onset of excessive grooming behavior with an average onset time of 11-15 days. This behavior has been proposed as a model of chronic central pain following SCI (Yezierski et al., 1998). An important histological correlate of this behavior is a pattern of neuronal loss that includes the neck of the dorsal horn with sparing of the superficial laminae. Previously, we speculated that laminae I projection neurons might be part of the substrate responsible for the onset and progression of injury induced excessive grooming behavior. To test this hypothesis we evaluated the effects of the [Sar9,Met(OH)11]substance P-saporin (SSP-SAP) neurotoxin delivered directly to the dorsal surface of the cord in ‘prevention’ and ‘treatment’ protocols. Two groups of animals were injected with 125mM QUIS. One group received a treatment of SSP-SAP (10μl; 15 or 30ng/μl) for ten minutes immediately after QUIS injection. The second group was treated with 30ng/μl within 5 days after the onset of excessive grooming behavior. The results showed that only 30% (3/10) of the animals receiving SSP-SAP in the prevention protocol developed excessive grooming behavior compared to a norm of 80-90%, and those that developed the behavior had a delayed onset (18-26 days) and small skin area targeted for grooming. Animals receiving SSP-SAP treatment after the onset of grooming had significantly less grooming than animals not receiving treatment. Staining for the NK-1R receptor showed that animals with minimal grooming behavior had a significant decrease in lamina I staining with normal staining around the central canal and IML. In conclusion the results have shown that ablation of lamina I substance P receptive neurons significantly delayed the onset and progression of a spontaneous pain-like behavior induced by excitotoxic SCI.

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Mazei MS, Wiley RG, Deutch AY (2000) Intracortical injection of DBH-saporin targets noradrenergic axons in the medial prefrontal cortex of the rat. Neuroscience 2000 Abstracts 639.8. Society for Neuroscience, New Orleans, LA.

Summary: The medial prefrontal cortex (mPFC) is innervated by both dopaminergic and noradrenergic neurons. While the densities of the two types of catecholamine axons are different in subregions of the mPFC, axons of both types are present in most of the mPFC. The goal of this study was to selectively lesion noradrenergic axons in the rat mPFC while sparing dopaminergic axons, using microinjection of the immunotoxin dopamine β-hydroxylase (DBH)-saporin. DBH-saporin (10- 100 ng/μ1) was unilaterally injected into three brain regions, the mPFC, caudate-putamen (CP) and cerebellum. Rats were sacrificed 2-10 days post-injection and the lesion was characterized by tyrosine hydroxylase (TH), DBH, and norepinepherine transporter (NET) immunohistochemistry. DBH-saporin administration resulted in discrete lesions. There appeared to be a decrease in the number of immunoreactive (ir) axons after DGH-saporin infusion into the mPFC: surviving axons were swollen and dystrophic. However, the effect of DBH-saporin appears more pronounced when examining DBH-ir than with NET-ir. Intrastriatal injections of DBH-saporin did not decrease TH-ir, suggesting that dopaminergic axons were spared. Since DBH-saporin acts by entry into DBH-containing vesicles, a longer time course may be necessary to observe loss of the NET marker than DBH. Studies are in progress to examine this possibility.

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Mattsson A, Ögren SO, Olson L (2000) 192 IgG-saporin immunolesioning causes marked facilitation of dopamine-mediated locomotor activity in adult rats. Neuroscience 2000 Abstracts 563.7. Society for Neuroscience, New Orleans, LA.

Summary: Recent studies have indicated a possible link between changes in cholinergic mechanisms and schizophrenia. However there is limited information regarding the functional consequences of changes in ACh transmission on DA functions, which in turn are believed to be involved in schizophrenic symptoms. 192 IgG-saporin targets cells that express the low-affinity p75 neurotrophin receptor. Intracerebroventricular injection causes severe lesions of the cholinergic projections and may also damage Purkinje neurons. We have compared intracerebroventricular injections of 192 IgG SAP to adult rats (5 μg) with injections to neonate rats (0.4 μg day 4 or 0.4 μg day 4 + 0.8 μg day 13). As expected, treated adult rats are markedly impaired in the Morris swim maze both in terms of time to find the platform and in search behavior when the platform is removed, i.e. memory impairment. When tested as adults, neonatally treated animals were only modestly impaired. Interestingly, adult treated animals showed increased spontaneous motility and locomotion and markedly increased locomotor responses to amphetamine (1.5 mg/kg) as evidenced by increased rearing, motility and locomotion. These animals also responded to apomorphine (1 mg/kg) with an increased amount of rearing. There were no marked changes of locomotor activity in rats treated with 192 IgG SAP at 4 days or 4 and 13 days of age. Our results suggest that cholinergic denervation of the forebrain causes a marked enhancement of the behavior responses related to increased dopaminergic activity. However, it cannot be fully excluded that damage to non-cholinergic systems, e.g. Purkinje cells, might contribute to the effects. The striking overreaction to dopaminergic stimuli presumably caused by the cholinergic deficit is possibly relevant in relation to the role of cholinergic malfunctioning in schizophrenia.

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De Rosa E, Hasselmo ME, Baxter MG (2000) Contribution of the cholinergic basal forebrain to proactive interference between stored odor memories during associative learning in rats: 192 IgG-saporin immunotoxic lesions. Neuroscience 2000 Abstracts 563.8. Society for Neuroscience, New Orleans, LA.

Summary: Previous electrophysiological studies and a computational model suggest that cholinergic neuromodulation may reduce olfactory associative interference during learning (Hasselmo & Bower, 1993; Hasselmo et al., 1992). Using a simultaneous discrimination task where rats were required to learn a baseline odor pair (A+B-) and then two novel odor pairs: A-C+ (with an overlapping component A) and D+E- (with no overlapping component), De Rosa & Hasselmo (2000) demonstrated that a 0.25 mg/kg systemic dose of scopolamine (SCOP) selectively increased proactive interference. Under the influence of SCOP, the rats were impaired on acquiring the odor pair AC and not the odor pair DE relative to their normal saline performance. To localize this effect male Sprague-Dawley rats, with bilateral selective cholinergic lesions of the horizontal limb of the diagonal band of Broca (HDB group) or of all of the cholinergic nuclei of the basal forebrain (BF group), were tested on our task. Neither lesion impaired normal acquisition of either odor pair relative to the sham-operated control rats. However, the BF group, but not the HDB and control groups, were sensitive to a lower dose of SCOP (0.125 mg/kg) than in the previous study: this dose selectively impaired the BF group on acquiring the odor pair AC and not the odor pair DE relative to their normal saline performance, suggesting that weaker cholinergic modulation after removing the majority of cholinergic neurons in the basal forebrain makes the system more sensitive to proactive interference during blockade of remaining cholinergic effects.

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Rogers SD, Salak-Johnson JL, Schwei MJ, Pomonis JD, Mantyh PW (2000) Reduced anxiety related behavior following ablation of amygdala neurons expressing substance P receptor. Neuroscience 2000 Abstracts 571.2. Society for Neuroscience, New Orleans, LA.

Summary: The neurokinin substance P (SP) is localized in brain regions that coordinate stress response and may play a role in modulating anxiety. Effects of ablation of substance P receptor (SPR)-expressing neurons by administration of a substance P-toxin conjugate, substance P-saporin (SP-SAP), in the amygdala (a brain region known to modulate stress and anxiety responses) were examined immunohistochemically and behaviorally thirty days following SP-SAP treatments. Rats were bilaterally injected in basolateral amygdala nuclei with 5μl of sterile saline, 1 μM saporin (SAP), or 1 μM SP-SAP. SPR-immunofluoresence levels and number of SPR-IR positive neurons in amygdalar subnuclei decreased following SP-SAP treatment. SP-SAP did not induce significant gliosis or non-specific neuronal death. Interestingly, after SP-SAP treatment, the number of NPY-IR neurons were also decreased, and combined SPR and NPY immunofluorescence demonstrated a large number of NPY-IR neurons colocalize with SPR-IR neurons in the amygdala. Thirty days following SP-SAP treatment, rats were tested in elevated plus maze (EPM) and open field (OF). Anxiety level and exploratory behavior displayed by SP-SAP treated rats were altered; they had significantly more entries into and spent more time in EPM open arms than did saline- or SAP-injected rats. In the OF, SP-SAP treated rats spent less time frozen than saline or SAP treated rats. These results suggest that SPR expressing neurons in the amygdala plays a pivotal role in generation of anxiety behaviors and that SP may play a modulatory role in stress-induced anxiety behavior.

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McGaughy JA, Dalley JW, Robbins TW, Everitt BJ (2000) The behavioral and neurochemical effects of acute and incremental cholinergic lesions on visual attention during a 5-choice serial reaction time task. Neuroscience 2000 Abstracts 563.1. Society for Neuroscience, New Orleans, LA.

Summary: Previously studies have shown that infusions of 192 IgG-saporin (SAP)into the nucleus basal magnocellularis (nbm) produce severe,persistent impairments in visual attention that correlate with the extent of cortical cholinergic deafferentation. After one bilateral infusion of a low dose (0.15 μg/μl; LX1) of SAP into the nbm, rats performing in a 5 CSRTT show specific behavioral impairments when tested with an increased event rate (ITI=2sec). In vivo microdialysis performed while rats were tested under standard conditions (ITI=5sec) in the 5CSRTT showed that LX1 rats had an increased basal acetylcholine (ACH) efflux in the prefrontal cortex (PFC) relative to sham-lesioned animals on the first day of testing, but no difference in task related efflux on either day of testing. The current study investigated the effects of larger cholinergic lesions on attentional perfomance to determine if they would produce large decreases in cortical ACH efflux and consequently impair attention. Rats were trained in a 5 CSRTT prior to receiving intra-nbm infusions of SAP or vehicle (VEH). Lesioned animals were subjected to repeated infusions of a low dose of the toxin (0.15 μg/μl), a single high dose (0.45 μg/μl) or vehicle. The (0.45 μg/μl) dose of SAP produced profound impairments under baseline conditions that correlated with low levels of ACH efflux in the PFC. These impairments were not attenuated by systemic nicotine or physostigmine. The cumulative lesions were hypothesized to increase sensitivity to attentional demands and pharmacological intervention.

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Janni G, Moallem T, Lappi DA, Ohara PT, Jasmin L (2000) Schwann cells are removed from the rat spinal cord after effecting recovery from paraplegia. Neuroscience 2000 Abstracts 516.8. Society for Neuroscience, New Orleans, LA.

Summary: Remyelination of the CNS is necessary to restore neural function in a number of demyelinating conditions such as multiple sclerosis. Schwann cells, the myelinating cells of the periphery, are good candidates for this purpose, having more robust regenerative properties than their central homologues, the oligodendrocytes. While the ability of Schwann cells to remyelinate the CNS and effect functional recovery has been demonstrated, their long term survival in the CNS after myelinating central axons is largely unknown. We use saporin conjugated to the cholera toxin B-subunit to demyelinate the rat lumbar spinal cord, remove macroglia, and produce paraplegia. This treatment is followed by a spontaneous proliferation of large numbers of endogenous Schwann cells which remyelinate spinal cord axons with concomitant functional recovery from paraplegia within 75 days. During the following weeks, however, quantification on thin sections shows that Schwann cells are progressively replaced by oligodendrocytes, without any lapse in behavioral recovery. This removal of Schwann cells is confirmed by ultrastructural examination and by immunocytochemistry for Schwann cells and oligodendrocytes. Our results indicate that Schwann cell remyelination of the spinal cord might not be permanent. They can be induced to demyelinate and desheath through endogenous mechanisms that remain to be characterized.

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