Acute and chronic effects of the neurolytic agent ricin on dorsal root ganglia, spinal cord, and nerves

Intraneural OX7-saporin for neuroma-in-continuity in a rat model

We employed 54 rats to devise a model of neuroma-in-continuity and explore the effect of the immunotoxin OX7-saporin on the neuroma. The left common peroneal, tibial or sciatic nerves were crushed by one 10-s application of a micro-artery forceps. At 3 and 6 weeks, the nerve was cut distal to the site of nerve crush, and retrograde fluorescent labeling was done. Pressure microinjection of 2 μl of natural saline or 2 μl of the immunotoxin conjugate OX7-saporin was done at the nerve stump 2 days later. Sacrifice was done after 3 weeks. In all control and saline-injection nerve specimens, gross observation and histology showed a neuroma-in-continuity. In 19 of the 24 OX7-saporin nerve specimens, gross observation showed a narrowed area at the site of nerve crush. Histology showed inhibition of neuroma-in-continuity formation. Fluorescent microscopy showed ablation of the labeled neurons in the dorsal root ganglia corresponding to the OX7-saporin subgroups.

Differential expression of the p75 nerve growth factor receptor in glia and neurons of the rat dorsal root ganglia after peripheral nerve transection

Sympathetic nerve terminals on blood vessels within the dorsal root ganglia sprout after sciatic nerve lesions in the rat. The mechanism underlying this phenomenon is not clear, but might be predicted to involve nerve growth factor or its homologs because these factors are known to trigger collateral sprouting of undamaged sympathetic noradrenergic terminals. We have found that sciatic nerve lesions lead to a decreased expression of neuronal p75, the low-affinity receptor for the neurotrophins, but an increased expression of glial p75 in ipsilateral dorsal root ganglia. Intriguingly, the increased expression of p75 was found primarily in association with glia surrounding large-diameter neurons, which are those associated with the noradrenergic sprouts. A smaller but significant glial response was also found in contralateral ganglia. The glial response in ipsilateral ganglia could be mimicked by ventral, but not dorsal, root transection. The dorsal root lesion-induced glial responses in contralateral ganglia were greater than those induced by ventral root or sciatic nerve lesions. Combined lesions of dorsal root and either ventral root or sciatic nerve did not prevent the glial responses of ipsilateral ganglia, suggesting that a peripheral signal is involved. Colocalization studies indicate that tyrosine hydroxylase-immunoreactive nerve sprouts were associated with p75-immunoreactive glial cells. Thus, increased glial synthesis of p75 might provide an explanation for the abnormal growth of sympathetic fibers in dorsal root ganglia after peripheral nerve injury.

Influence of the postsynaptic target on the functional properties of neurons in the adult mammalian central nervous system

In this review we have attempted to summarize present knowledge concerning the regulatory role of target cells on the expression and maintenance of the neuronal phenotype during adulthood. It is well known that in early developmental stages the survival of neurons is maintained by specific neurotrophic factors derived from their target tissues. Neuronal survival is not the only phenotype that is regulated by target-derived neurotrophic factors since the expression of electrophysiological and cytochemical properties of neurons is also affected. However, a good deal of evidence indicates that the survival of neurons becomes less dependent on their targets in the adult stage. The question is to what extent are target cells still required for the maintenance of the pre-existing or programmed state of the neuron; i.e., what is the functional significance of target-derived factors during maturity? Studies addressing this question comprise a variety of neuronal systems and technical approaches and they indicate that trophic interactions, although less apparent, persist in maturity and are most easily revealed by experimental manipulation. In this respect, research has been directed to analyzing the consequences of disconnecting a group of neurons from their target-by either axotomy or selective target removal using different neurotoxins-and followed (or not) by the implant of a novel target, usually a piece of embryonic tissue. Numerous alterations have been described as taking place in neurons following axotomy, affecting their morphology, physiology and metabolism. All these neuronal properties return to normal values when regeneration is successful and reinnervation of the target is achieved. Nevertheless, most of the changes persist if reinnervation is prevented by any procedure. Although axotomy may represent, besides target disconnection, a cellular lesion, alternative approaches (e.g., blockade of either the axoplasmic transport or the conduction of action potentials) have been used yielding similar results. Moreover, in the adult mammalian central nervous system, neurotoxins have been used to eliminate a particular target selectively and to study the consequences on the intact but target-deprived presynaptic neurons. Target depletion performed by excitotoxic lesions is not followed by retrograde cell death, but targetless neurons exhibit several modifications such as reduction in soma size and in the staining intensity for neurotransmitter-synthesizing enzymes. Recently, the oculomotor system has been used as an experimental model for evaluating the functional effects of target removal on the premotor abducens internuclear neurons whose motoneuronal target is destroyed following the injection of toxic ricin into the extraocular medial rectus muscle. The functional characteristics of these abducens neurons recorded under alert conditions simultaneously with eye movements show noticeable changes after target loss, such as a general reduction in firing frequency and a loss of the discharge signals related to eye position and velocity. Nevertheless, the firing pattern of these targetless abducens internuclear neurons recovers in parallel with the establishment of synaptic contacts on a presumptive new target: the small oculomotor internuclear neurons located in proximity to the disappeared target motoneurons. The possibility that a new target may restore neuronal properties towards a normal state has been observed in other systems after axotomy and is also evident from experiments of transplantation of immature neurons into the lesioned central nervous system of adult mammals. It can be concluded that although target-derived factors may not control neuronal survival in the adult nervous system, they are required for the maintenance of the functional state of neurons, regulating numerous aspects of neuronal structure, chemistry and electro-physiology.(ABSTRUCT TRUNCATED)

Selective inhibition of neuronal protein synthesis by retrogradely transported ricin

The ability of the lectin, ricinus communis agglutinin I (ricin120), to undergo retrograde axonal transport and cause degeneration of neuronal cell bodies has been frequently exploited to establish the origin of peripheral axons. Since this cytotoxic action of ricin results from its inactivation of ribosomes, the retrogradely transported lectin was employed in the present study to inhibit protein synthesis in dorsal root ganglion (DRG) neurons whose axons project into the lumbar nerve trunk of bullfrog tadpoles. The procedure was developed to examine, during tadpole metamorphosis, the ratio of fast-transported radiolabeled protein accumulating at the proximal side of a nerve trunk ligature to the total newly synthesized protein in the cell bodies of origin. The relatively small diameter and fragility of the developing lumbar nerve trunks necessitated introduction of ricin by bath application to the cut nerve end rather than by intraneural injection. Consistent uptake of ricin was achieved by pretreatment with the phospholipase A2 inhibitor, mepacrine, that blocks resealing of severed nerve fibers. Optimal time and dosage of ricin were established by determining the maximal achievable inhibition of [35S]methionine into DRG protein. In stage XVI tadpoles, maximal inhibition of approximately to 65% was observed after 16 h incubation in 2.5 mg/ml ricin. As evidence that neuronal protein synthesis was effectively suppressed, there was no detectable anterograde axonal transport of [35S]protein subsequent to ricin treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

Ultrastructural alterations induced in quail ciliary neurons by postganglionic nerve crush and by Ricinus toxin administration, separately and in combination

The response to postganglionic nerve crush and Ricinus toxin administration by the ciliary neurons of the quail ciliary ganglion was investigated at the ultrastructural level. The toxin was either applied at the crush site on the postganglionic nerves or injected into the anterior eye chamber without any other operative intervention. Crush of postganglionic nerves without toxin administration and saline injection into the anterior eye chamber served as controls for the two toxin administration procedures. Postganglionic nerve crush caused a distinct chromatolytic reaction, accompanied by massive detachment of the preganglionic axon terminals from the ciliary neurons and loss of most of the synapses, both chemical and electrical. This process does not induce cell death and is reversible. Saline injection in the anterior eye chamber caused a moderate retrograde reaction in some of the ciliary neurons, presumably as a consequence of paracentesis. The changes consisted mainly of an increase of perikaryal neurofilaments with, at most, a minor detachment of the preganglionic boutons from a small portion of the cell body at the nuclear pole. Ricinus toxin administration induced neuronal degeneration following a pattern common to both delivery modes. The degenerative process consisted of disruption and detachment of polyribosomes from the rough endoplasmic reticulum, an increase of smooth cisterns and tubules, a dramatic increase of neurofilament bundles, compartmentalization of the cytoplasmic organelles and, finally, karyorrhexis and cell lysis. The final stages of Ricinus toxin degeneration involve a progressive accumulation of extracellular flocculo-filamentous material and cell lysis. After administration of Ricinus toxin to the crush site, ricin-affected neurons showed withdrawal of the preganglionic boutons from a portion of the ciliary neuron, especially at the nuclear pole. After Ricinus toxin injection into the anterior eye chamber, however, the bouton shell surrounding the affected ciliary neurons remained intact in the early stages of degeneration. Detachment of the preganglionic terminals and disruption of the cell junctions, therefore, is the consequence of nerve crush and not of the toxin itself. This study demonstrated that quail ciliary neurons are a suitable model for experimental neuropathology and neurotoxicology.

Satellite cell proliferation in the adult rat trigeminal ganglion results from the release of a mitogenic protein from explanted sensory neurons

Explant of trigeminal ganglia neurons in adult rats induces perineuronal glial proliferation of primarily satellite cells as opposed to Schwann cells. This proliferation begins at 15 h after explant culture and by 27 h there is a significant increase in glial proliferation as measured by scintillation counts of [3H]thymidine. Blocking protein synthesis between 0 and 3.5 h after explant culture (early) results in an enhanced proliferative response, while blocking protein synthesis between 3.5 and 7 h (late) causes a complete block of the proliferative response assessed at 27 h. Conditioned media experiments demonstrate that both the mitogenic and inhibitory signals are diffusible and heat labile. Finally, the addition of neurotrophic factors to rescue injured ganglionic neurons attenuates the proliferative glial response suggesting that injured neurons produce and release signals that induce glial proliferation.

Effects of target depletion on adult mammalian central neurons: functional correlates

The physiological signals and patterns of synaptic connectivity that CNS neurons display after the loss of their target cells were evaluated in adult cats for one year. Abducens internuclear neurons were chosen as the experimental model because of their highly specific projection onto the medial rectus motoneurons of the oculomotor nucleus. Selective death of medial rectus motoneurons was induced by the injection into the medial rectus muscle of ricin, a potent cytotoxic lectin that leaves the presynaptic axons intact. The electrical activity of antidromically identified abducens internuclear neurons was recorded in chronic alert animals, during both spontaneous and vestibularly induced eye movements, before and after target removal. During the three weeks that followed ricin injection, abducens internuclear neurons exhibited several firing-related abnormal properties. There was an overall reduction in firing rate with a corresponding increase in the eye position threshold for recruitment. In addition, neuronal sensitivities to eye position and velocity were significantly decreased with respect to control data. Bursting activity was also altered since low-frequency delayed burst accompanied the saccades in the on-direction and, occasionally, internuclear neurons exhibited low-frequency discharges associated with off-directed saccades. Intracellular recordings carried out seven and 15 days after ricin injection demonstrated no significant changes in their electrical properties, although a marked depression of synaptic transmission was evident. The amplitude of both excitatory and inhibitory postsynaptic potentials of vestibular origin was reduced by 60-85% with respect to controls. However, postsynaptic potentials recorded one month after ricin injection showed normal amplitude values which persisted unaltered one year after target loss. Recovery of synaptic transmission occurred at the same time as the re-establishment of normal eye-related signals in the discharge pattern of abducens internuclear neurons recorded in alert cats from days 25-30 post lesion. The functional restoration of firing properties was maintained in the long term (one year). Conversely, abducens motoneurons showed normal firing and synaptic patterns at all time intervals analysed. These results demonstrate that, after an initial period of altered physiological properties, abducens internuclear neurons survive the loss of their target motoneurons and regain a normal discharge pattern and afferent synaptic connections.

Long-term effects of selective target removal on brainstem premotor neurons in the adult cat

The electrical activity of antidromically identified abducens internuclear neurons selectively deprived of their target motoneurons was recorded in chronic alert cats. Target motoneurons were killed by the injection of the cytotoxic lectin of Ricinus communis into the medial rectus muscle. Following target removal, the discharge pattern of abducens internuclear neurons showed an overall decrease in firing rate, a significant reduction in their sensitivity to eye position and velocity, and the presence of anomalous responses such as bursts of spikes associated with off-directed saccades. The decreased excitability of abducens internuclear neurons correlated well with a marked reduction in the synaptic efficacy of their inputs. Thus, both excitatory and inhibitory synaptic potentials of vestibular origin showed a noticeable decrease in amplitude. The alterations in firing properties and synaptic transmission were only observed during an initial period of 3 weeks following ricin injection. Within 1 month the electrophysiological parameters returned to control values and remained unaltered for 1 year. Retrograde labelling of abducens internuclear neurons revealed that no cell death occurred after target loss. The anterograde axonal labelling of these neurons showed a progressive decrease in the density of their axonal terminals, and no sign of redistribution to other areas was found. These findings indicate that abducens internuclear neurons are not dependent on the presence of their natural target cells, either for the survival or for the maintenance of appropriate physiological signals.

The use of a neurotoxic lectin, volkensin, to induce loss of identified motoneuron pools

In this study we investigated degeneration of defined motor pools in the adult rat spinal cord and the associated changes in spinal cord in dorsal root ganglia and peripheral nerve. Degeneration of motoneurons was induced by the neurotoxic lectin, volkensin. This substance is taken up by the axons and retrogradely transported to the cell body, where it inhibits proteosynthesis and kills the neuron. Accordingly, in adult Wistar rats the peroneal or the sciatic nerve was injected with 5.0 ng volkensin, and the effect of this single injection was investigated at different intervals after the operation. Retrograde labelling by horseradish peroxidase was used to reveal the extent of cell death and glial repair was studied by immunostaining with different glial cell markers. Degenerating cells were observed in the ventral horn of the lumbar spinal cord and L4 and L5 dorsal root ganglia as early as four days after volkensin treatment and by two weeks no retrogradely labelled motoneurons could be found in the treated peroneal pool. These changes were accompanied by severe muscle weight loss. Examination of the ventral horn of the spinal cord on the treated side revealed many hypertrophic astrocytes and reactive microglial cells expressing an increased level of complement receptor type 3 immunoreactivity. In the volkensin-injected peripheral nerve, distinct signs of Wallerian-like degeneration could be observed. Schwann cells identified by immunostaining to S-100 protein appeared to be preserved. Interestingly, at later stages after volkensin injection (four to eight weeks), some retrogradely labelled motoneurons were seen in the peroneal pool; their number occasionally reached 18.4% of the control pool. The dorsal root ganglia showed extensive loss of neurons and numerous abnormal neurons were found throughout the period of the study. These findings suggest that some motoneurons are able to recover from exposure to volkensin and temporary arrest of proteosynthesis. Despite this, volkensin-induced selective motoneuron death in the adult rat can be a useful experimental model for degenerative motoneuron disease.

Neural lesioning with ribosome-inactivating proteins: suicide transport and immunolesioning

Toxic lectins, plant proteins that inactivate ribosomes, irreversibly inhibit protein synthesis with high efficiency. After intraneural (subepineurial) microinjection, these agents are taken up by axons and are retrogradely transported to the perikarya, where they result in cell death. These 'suicide transport' toxins can produce pathway-specific lesions that are useful in several types of experiment, including cellular localization of neurotransmitter receptors. The toxins can be coupled to monoclonal antibodies to produce immunotoxins: reagents that can make highly selective lesions of specific types of neurons. Central or peripheral neurons that express the low-affinity NGF receptor are selectively destroyed by the immunotoxin 192 IgG-saporin. Development of other anti-neuronal immunotoxins should provide a variety of powerful selective lesioning tools.

Immunolesioning: selective destruction of neurons using immunotoxin to rat NGF receptor

192 IgG, a monoclonal antibody to the rat nerve growth factor (NGF) receptor, was disulfide-coupled to saporin, a ribosome-inactivating protein. Systemic injection of 192 IgG-saporin destroyed sympathetic postganglionic neurons and some sensory neurons. Injection of 192 IgG-saporin into the lateral ventricle destroyed cholinergic neurons of the basal forebrain. These results show that antineuronal immunotoxins are a powerful approach that may prove useful in a variety of neurobiological applications.

Behavior of cat abducens motoneurons following the injection of toxic ricin into the lateral rectus muscle

The aim of this investigation was to study the behavior of identified abducens motoneurons in the chronic cat following a single injection of toxic ricin into the lateral rectus muscle. Lateral rectus electromyographic potentials induced by VIth nerve stimulation disappeared, and abducens antidromic field potentials decreased by 90% 3 days following ricin injection. Several abnormalities and a significant decrease in eye position and velocity sensitivities were observed in motoneuron activity up to 8-10 days following ricin injection. Contrary to a previous report for axotomized abducens motoneurons, no functional sign of recovery was observed. Histological analysis showed a survival of 10-15% of the abducens motoneuron population 10 days following ricin injection. From this time on, recorded motoneurons behaved like controls, but showed a specific retraction signal suggesting an exclusive projection onto the retractor bulbi muscle. Although intermingled in the nucleus with motoneurons, no recorded abducens internuclear interneuron was affected by the ricin during one month following the injection.

Quantitative study of neuronal degeneration induced by Ricinus toxin and crush of postganglionic nerves in the ciliary ganglion of quail

The effects of Ricinus toxin on the neurons of the ciliary ganglia were investigated in the quail. The neuronal death and the morphological alterations of the ganglionic cells were assessed following injection of the toxin in the anterior chamber of the eye or after application of the toxin on the postganglionic nerves at a crush site. A 45% loss of choroid neurons without loss of ciliary neurons was observed after postganglionic nerve crush alone. Injection of the toxin in the anterior chamber of the eye led to a selective loss of ciliary neurons (38%). Application of the toxin to the crushed postganglionic nerves led to a loss from both neuronal populations (40% of total neurons). This work indicates that different procedures result in selective lesion of the different neuronal populations in the ciliary ganglion.

Ultrastructural observations of non-selective effects of ricin treatment (RCA-120) in the rat dorsal root ganglion

The effects of ricin (RCA-120) on non-injected dorsal root ganglion (DRG) cells, sharing the same DRG as the injected ones, were studied after ricin injections into the tibial nerve and B-HRP injections into the peroneal nerve. Numerous DRG cells containing B-HRP reaction product and exhibiting signs of advanced degeneration were observed. The findings suggest that ricin may be released from dying injected DRG neurons and taken up by adjacent non-injected DRG cells, which subsequently degenerate.

Degenerative changes of neurons in the superior cervical ganglion following an injection of Ricinus communis agglutinin-60 into the vagus nerve in hamsters

The present study describes neuronal changes in the superior cervical ganglion of hamsters following injection of Ricinus communis agglutinin-60 (RCA-60) into the ipsilateral vagus nerve in the cervical region. There were no noticeable structural changes in the ganglion 1 day after injection. Between 3 and 15 days after injection, a small number of neurons located in the caudal part of the ganglion underwent degenerative changes including disappearance of rough endoplasmic reticulum and cytoplasmic vacuolation. The structural alterations were most acute 7 days after the injection when some neurons showed signs of total vacuolation and lysis. A second phase of neuronal change occurred after longer survival periods extending from 60 to 120 days after injection. The most striking feature of such neurons was darkening of their dendrites associated with abnormally high density cytoplasm that contained mitochondria with disrupted cristae. As distinct from the early phase in which cell necrosis was observed, there was no evidence of cell death of neurons bearing darkened dendrites. Since examples of exfoliation of the affected dendrites and their phagocytosis by satellite cells were extremely rare, it is postulated that these structural alterations are probably reversible but over an extended period. The significance of the two phases of degenerative change is discussed in connection with the acute and possible chronic effects of the toxic lectin. The present study also confirms the presence of postganglionic sympathetic axons in the cervical vagus nerve.

Dose- and time-dependent selective and non-selective effects of ricin (RCA 120) on rat primary sensory neurons

The distribution of degenerating fibers in the spinal cord was studied in Fink-Heimer-stained sections following treatment of the tibial nerve with ricinus communis agglutinin (RCA 120). The ricin was either injected into the nerve or applied in a capsule on the transected nerve. Short survival times and low doses of ricin resulted in degeneration in somatotopically appropriate parts of the medial dorsal horn. Longer survival times and higher doses resulted in degeneration which progressively expanded into inappropriate areas in the central and lateral parts of the dorsal horn and in deeper laminae regardless of the mode of application. Furthermore, the effect of a ricin injection into the tibial nerve on transganglionic transport of choleragenoid horseradish peroxidase (B-HRP) in the peroneal nerve was studied following a simultaneous or delayed B-HRP injection. A simultaneous ricin and a B-HRP injection resulted in primary afferent HRP labeling in the gray matter, regardless of the dose of ricin. Following a delayed B-HRP injection almost no primary afferent labeling was seen in the gray matter, unless a very low dose of ricin was injected. This study shows that treatment of a peripheral nerve with a high dose of ricin and a long survival time may result in a considerable non-selective degeneration of fibers in the spinal cord. A selective degeneration may, however, be obtained by using lower doses or shorter survival times.

Lack of central sprouting of primary afferent fibers after ricin deafferentation

A new deafferentation technique, the application of ricin to peripheral nerves, was used to test for collateral sprouting of undamaged primary afferent fibers within the adult mammalian spinal cord dorsal horn. The right sciatic nerves in rats were injected with ricin 14 to 57 days prior to bilateral labelling of dorsal rootlets with horseradish peroxidase. To equate the number of surviving dorsal root fibers on the two sides, the left sciatic nerves were injected 5 days prior to labelling. In each animal, horseradish peroxidase was applied to a bilateral pair of lumbar or low thoracic dorsal rootlets 18 hours prior to sacrifice to test for sprouting by labelling primary afferent fibers and terminals in the right (experimental) and left (control) dorsal horns. Although there is overlap of degenerated and intact primary afferent fields in this preparation, a postulated precondition for sprouting (Murray and Goldberger: J. Neurosci. 6:3205-3217, '86), we found no evidence for sprouting of undamaged, myelinated afferent fibers in the experimental dorsal horns. The pattern of labelling was symmetrical in all animals, and the density of labelling was not consistently greater on the experimental side. These results support the conclusions of Rodin et al. (J. Comp. Neurol. 215:187-198, '83) and Rodin and Kruger (Somatosens. Res. 2:171-192, '84), who also found no sprouting in the rat's dorsal horn after surgical deafferentation, and do not support the assertion that the difference between the results of those studies and earlier studies in cats was due to a lack of overlap of degenerated and intact dorsal roots in the rat.