Neuronotoxicity of axonally transported toxic lectins, abrin, modeccin and volkensin in rat peripheral nervous system

Neurotoxicity of Prosopis juliflora: from Natural Poisoning to Mechanism of Action of Its Piperidine Alkaloids

Prosopis juliflora was introduced in northeastern Brazil in the 1940s, and since then, it has been available as an alternative for animal nutrition. However, the consumption of P. juliflora as main or sole source of food causes an illness in animals known locally as "cara torta" disease. Cattle and goats experimentally intoxicated presents neurotoxic damage in the central nervous system. Histologic lesions were mainly characterized by vacuolation and loss of neurons in trigeminal motor nuclei. Furthermore, mitochondrial damage in neurons and gliosis was reported in trigeminal nuclei of intoxicated cattle. Studies, using neural cell cultures, have reproduced the main cellular alterations visualized in cara torta disease and contributed to understanding the mechanism of action piperidine alkaloids, the main neurotoxic compound in P. juliflora leaves and pods. Here, we will present aspects of the biological and toxicological properties of P. juliflora and its pharmacologically active compounds.

Hyperuricaemia, Xanthine Oxidoreductase and Ribosome-Inactivating Proteins from Plants: The Contributions of Fiorenzo Stirpe to Frontline Research

The enzymes called ribosome-inactivating proteins (RIPs) that are able to depurinate nucleic acids and arrest vital cellular functions, including protein synthesis, are still a frontline research field, mostly because of their promising medical applications. The contributions of Stirpe to the development of these studies has been one of the most relevant. After a short biographical introduction, an overview is offered of the main results obtained by his investigations during last 55 years on his main research lines: hyperuricaemia, xanthine oxidoreductase and RIPs.

Ribosome-Inactivating Proteins from Plants: A Historical Overview

This review provides a historical overview of the research on plant ribosome-inactivating proteins (RIPs), starting from the first studies at the end of eighteenth century involving the purification of abrin and ricin, as well as the immunological experiments of Paul Erlich. Interest in these plant toxins was revived in 1970 by the observation of their anticancer activity, which has given rise to a large amount of research contributing to the development of various scientific fields. Biochemistry analyses succeeded in identifying the enzymatic activity of RIPs and allowed for a better understanding of the ribosomal machinery. Studies on RIP/cell interactions were able to detail the endocytosis and intracellular routing of ricin, thus increasing our knowledge of how cells handle exogenous proteins. The identification of new RIPs and the finding that most RIPs are single-chain polypeptides, together with their genetic sequencing, has aided in the development of new phylogenetic theories. Overall, the biological properties of these proteins, including their abortifacient, anticancer, antiviral and neurotoxic activities, suggest that RIPs could be utilized in agriculture and in many biomedical fields, including clinical drug development.

Neuroplasticity and Repair in Rodent Neurotoxic Models of Spinal Motoneuron Disease

Retrogradely transported toxins are widely used to set up protocols for selective lesioning of the nervous system. These methods could be collectively named "molecular neurosurgery" because they are able to destroy specific types of neurons by using targeted neurotoxins. Lectins such as ricin, volkensin, or modeccin and neuropeptide- or antibody-conjugated saporin represent the most effective toxins used for neuronal lesioning. Some of these specific neurotoxins could be used to induce selective depletion of spinal motoneurons. In this review, we extensively describe two rodent models of motoneuron degeneration induced by volkensin or cholera toxin-B saporin. In particular, we focus on the possible experimental use of these models to mimic neurodegenerative diseases, to dissect the molecular mechanisms of neuroplastic changes underlying the spontaneous functional recovery after motoneuron death, and finally to test different strategies of neural repair. The potential clinical applications of these approaches are also discussed.

A model of motor neuron loss: selective deficits after ricin injection

This study characterizes a model of motor neuron (MN) loss on the molecular, cellular, and behavioral levels. Injection of the toxic lectin Ricinus communis agglutinin I (RCA I or ricin) caused cellular deficit and loss of function by damaging the sciatic nerve. Since the sciatic nerve supplies movement to most of the lower limb, damaging this motor system models lower limb paralysis and the deficits that occur in diseases like amyotrophic lateral sclerosis (ALS) and infantile progressive spinal muscular atrophy (SMA). We used motor-, sensorimotor-, locomotor-, and reflex-based tests to demonstrate loss of function after ricin injection. Loss of function was also demonstrated by decreased retrograde transport, and supported by measurements of muscle wasting. Histochemical and molecular methods were used to characterize sciatic nerve damage in axons and cell bodies, including apoptotic cell death in MNs. This battery of tests documents the extent of the ricin-induced damage and provides a baseline that can be used to judge the efficacy of MN treatment strategies in preclinical studies.

Structural analysis of toxic volkensin, a type 2 ribosome inactivating protein from Adenia volkensii Harm (kilyambiti plant): molecular modeling and surface analysis by computational methods and limited proteolysis

Volkensin, isolated from Adenia volkensii, is one of the most toxic type 2 ribosome-inactivating protein (RIP), exerting its biological function by inhibiting protein synthesis. Despite the high sequence identity with type 2 RIPs, including ricin, volkensin shows interesting peculiar properties. In this work a computational model building of volkensin was performed. The volkensin electrostatic potential charge distribution, the hydrophobic profile and the surface topology analyses were also carried out to aid the understanding of structure-function relationships of this potent toxin. Volkensin surface topology was probed by applying a limited proteolysis approach with the aim to gain insights into volkensin conformational features.

Current treatment concepts for neuromas-in-continuity

A neuroma-in-continuity is a neuroma that results from failure of the regenerating nerve growth cone to reach peripheral targets. It occurs within an intact nerve in response to internally damaged fascicles, resulting in a distal portion of the nerve that no longer functions properly. Management of neuromas-in-continuity is challenging. Chemical methods, and microsurgical techniques including fascicular ligation, and burying into muscle and bone have been reported to prevent neuroma-in-continuity formation. The purpose of this article is to present novel techniques for neuroma-in-continuity management, and to discuss the related literature.

Acetylcholine release from fetal tissue homotopically grafted to the motoneuron-depleted lumbar spinal cord. An in vivo microdialysis study in the awake rat

Grafts of spinal cord (SC) tissue can survive and develop into the severed SC, but no conclusive data are available concerning the functional activity of transplanted neurons. In the present study, suspensions of prelabeled embryonic ventral SC tissue were grafted to the lumbar SC of rats with motoneuron loss induced by perinatal injection of volkensin. Eight to ten months post-grafting, acetylcholine (ACh) release was measured by microdialysis in awake rats, under either basal or stimulated conditions. In normal animals, baseline ACh output averaged 1.6 pmol/30 microl, it exhibited a 4-fold increase after KCl-induced depolarization or handling, and it was completely inhibited by tetrodotoxin administration. Moreover, ACh levels did not change following acute SC transection performed under anesthesia during ongoing dialysis, suggesting an intrinsic source for spinal ACh. Treatment with volkensin produced a severe (>85%) motoneuronal loss accompanied by a similar reduction in baseline ACh release and almost completely abolished effects of depolarization or handling. In transplanted animals, many motoneuron-like labeled cells were found within and just outside the graft area, but apparently in no case were they able to extend fibers towards the denervated muscle. However, the grafts restored baseline ACh output up to near-normal levels and responded with significantly increased release to depolarization, but not to handling. The present findings indicate that spinal neuroblasts can survive and develop within the motoneuron-depleted SC and release ACh in a near-normal, but apparently non-regulated, manner. This may be of importance for future studies involving intraspinal stem cell grafts.

Cloning and expression of the B chain of volkensin, type 2 ribosome inactivating protein from Adenia volkensii harms: Co-folding with the A chain for heterodimer reconstitution

Type 2 ribosome inactivating proteins (RIPs) include some potent plant toxins, among which ricin from Ricinus communis and abrin from Abrus precatorius seeds, have been known for more than a century. Two other type 2 RIPs belong to this class of proteins, both isolated from plants of the same family (Passifloraceae), modeccin and volkensin, from Adenia digitata and Adenia volkensii roots, respectively. Volkensin is probably the most potent plant toxin known, with an LD50 for rats of 50-60 ng/kg. Here we report the cloning, expression and renaturation of recombinant volkensin B chain. Furthermore, starting from separately expressed A and B chains, a co-association procedure was set-up, leading to in vitro heterodimeric volkensin reconstitution. The recombinant heterodimer was characterized by N-terminal sequence analysis and its hemagglutinating activity assessed. In parallel, we have explored the carbohydrate-binding properties of native volkensin with the aim to correlate toxin-specific properties (i.e., axonal transport along neurons) to lectin's sugar-binding preferences.

Neuronal lesioning with axonally transported toxins

Axonally transported toxins can be used to make selective lesions of the nervous system. Collectively, these techniques are termed 'molecular neurosurgery' because they exploit the surface molecular identity of neurons to selectively destroy specific types of neurons. Suicide transport, is anatomically selective but not type-selective. The most widely used suicide transport agents are the toxic lectins (ricin, volkensin) and the immunotoxin, OX7-saporin. The toxic lectins and saporin are ribosome inactivating proteins that irreversibly inhibit protein synthesis. The toxic lectins have binding subunits but saporin requires a targeting vector to gain entrance into cells. Immunolesioning uses monoclonal anti-neuronal antibodies to deliver saporin selectively into neurons that express a particular target surface antigen. Neuropeptide-saporin conjugates selectively destroy neurons expressing the appropriate peptide receptors. Notable experimental uses of these agents include analysis of the function of the cholinergic basal forebrain (192-saporin) and pain research (anti-DBH-saporin, substance P-saporin). It is likely that more immunolesioning and neuropeptide-toxin conjugates will be developed in the near future.

Extensive and permanent motoneuron loss in the rat lumbar spinal cord following neurotoxic lesion at birth: morphological evidence

The efficacy of the neurotoxic lectin volkensin to induce motoneuron loss in the lumbar spinal cord was investigated at different time-points following unilateral injection into the medial gastrocnemius muscle of newborn (postnatal day 1 (PD 1)) animals, using retrograde fluorescent neuron labelling and histochemical procedures to evaluate the extent of the toxin-induced depletion, in comparison with the effects produced by neonatal crushing of the sciatic nerve. The results show that very low doses (2.0 ng) of volkensin intramuscularly can produce extensive (about 90%) and long-lasting (up to at least 8 months post-lesion) motoneuronal loss in the lumbar spinal cord, whose magnitude is higher than that observed following mechanical injury of the developing peripheral nerve (50-60%). Volkensin-induced motoneuronal depletion may therefore represent a useful model for experimental studies aimed at functional cell replacement in the immature spinal cord.

Neuronal degeneration by suicide transport following injection of volkensin into rat cerebral cortex

We have examined the time course of neurodegeneration in subcortical nuclei and other cortical areas known to project to the rat parietal cortex, following unilateral injection of the suicide transport agent, volkensin, into the cortex of one side. Degenerating neurons, visualized by Gallyas silver staining were most prominent 21 days after injection. At this time darkly staining neurons were present in nuclei and areas known to project to the injected cortical area but not in other sites. Affected subcortical nuclei included the ipsilateral ventral thalamus and intralaminar nuclei, the basal nucleus of Meynert and claustrum of the same side, and the dorsal median raphé nucleus of both sides. Within the cortex degenerating pyramidal neurons were visible in the contralateral parietal cortex and in the frontal cortex of the same side. The distribution of degenerating cells is in agreement with the conclusion that only neurons projecting to the injection site were affected. The time course of the appearance of the degeneration and its distribution are in keeping with axonal transport rather than spread by diffusion of the toxin. Neuronal counts in Nissl-stained sections of the contralateral SMI confirmed significant neuronal loss 28 days after injection. In situ hybridization studies using an oligonucleotide probe directed against GAD mRNA and counts of GAD mRNA-positive neurons in the contralateral cortex confirmed that this population of cortical interneurons, which do not project to the injection site, were unaffected.

Immunohistochemical study of catecholamine enzymes and neuropeptide Y (NPY) in the rostral ventrolateral medulla and bulbospinal projection

The purpose of this study was to determine whether neuropeptide Y (NPY) terminals in the intermediolateral spinal cord originate from the rostral ventrolateral medulla (RVLM). Immunohistochemical staining of tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH), phenylethanolamine-N-methyltransferase (PNMT), and NPY in the rat brainstem and spinal cord were performed in this study in order to examine consequences of lesions of the RVLM and of intracisternal injections of 6-hydroxydopamine (6-OHDA) on catecholamine and NPY immunoreactivity in the intermediolateral column (IML) of rats. In addition, ricin, a retrograde neurotoxin, was applied in the superior cervical ganglion (SCG) to determine its effect on catecholamine and NPY immunoreactivity in the IML. Computer-aided image analysis was used to quantify the immunohistochemical changes in the RVLM and spinal cord. The results demonstrated that many catecholamine- and NPY-containing neurons and/or fibers existed in the RVLM and their terminals were found in the IML. After administration of 6-OHDA intracisternally, the catecholamine and NPY immunoreactivities were decreased both in the brainstem and IML of the spinal cord. Following unilateral microinjection of 6-OHDA into the RVLM, the number of NPY- and catecholamine-containing neurons decreased and there was a reduction in neuron terminals on the ipsilateral side. After injection of ricin into the SCG, the catecholamine and NPY neurons of the medulla were not affected, whereas their terminals in the IML decreased ipsilaterally. These results indicate that most of the catecholamine- and NPY-immunoreactive terminals found in the IML originated in the RVLM. These terminals appear to project towards the superior cervical ganglia.

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.

Ribosome–Inactivating Proteins from Plants: Present Status and Future Prospects

Plant ribosome-inactivating proteins (RIPs) are N-glycosidases which cleave the N-glycosidic bond of adenine in a specific ribosomal RNA sequence. Most commonly RIPs are single-chain proteins (type 1 RIPs), but some (type 2 RIPs) possess a galactose-specific lectin domain that binds to cell surfaces. The latter RIPs are potent toxins, the best known of which is ricin. RIPs have antiviral and abortifacient activities, and, in a widespread application, can also be linked to antibodies or ligands to form immunotoxins or conjugates specifically toxic to a given type of cell.

Anatomical and neurochemical evidence for suicide transport of a toxic lectin, volkensin, injected in the rat dorsal hippocampus

Volkensin, a ribosome-inactivating toxic lectin which has been proposed as a 'suicide transport' agent in the CNS, was unilaterally injected in the rat dorsal hippocampus at a dose of 1.2 ng. Three to 5 days after the injection, degenerating neurons were observed at the electron microscope in the medial septum-diagonal band area ipsilateral to the injection. Ten days after the injection, the number of pyramidal neurons in the CA3 region of the contralateral hippocampus, which are the major source of hippocampal commissural fibers, was obviously decreased. At the same survival time, the number of choline acetyltransferase (ChAT) immunoreactive neurons in the ipsilateral medial septum-diagonal band area was moderately but significantly decreased. These neurons are known to be the major source of the septohippocampal cholinergic projection. Concomitantly, microchemical assays of ChAT levels revealed a 25% decrease of enzyme activity in the medial septum-diagonal band area ipsilateral to the injection. This was accompanied by a 33% decrease of ChAT in the ipsilateral ventral hippocampus which was interpreted to be due, at least in part, to the degeneration of cholinergic septal neurons projecting to both the dorsal and the ventral hippocampus. Taken together, these results provide clear evidence that volkensin is taken up by nerve terminals in the injected area of the brain and retrogradely transported to the cell bodies originating the projection, which are killed by the toxin. The usefulness of the strategy of 'suicide transport' in the CNS is, therefore, confirmed.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Morphometric evidence from C-synapses for phased Nissl body response in alpha-motoneurones retrogradely intoxicated with diphtheria toxin

Diphtheria toxin (DTX) kills cells by inactivating ribosomal translocation and when used to retrogradely intoxicate cat intercostal motoneurones produces marked morphological alterations in Nissl bodies, including those specifically sited postsynaptic to C-type axon terminals. Here, qualitative examinations of 'intoxicated' postsynaptic Nissl bodies reveal a progressive structural alteration marked by rER dilatation, rER lamellae fragmentation but retention of both the highly ordered multilamellate organization and ribosomal attachment until final stages of Nissl body dissolution. Morphometric results identified 3 broad phases to the postintoxication response which differed in the degree of rER cisternal dilation, and the numerical and spatial relationships between rER-lamellae, rER-bound ribosomes and rER-associated polyribosomes. These phases reflect the known molecular basis of diphtheritic toxicity and contrast with the fast developing Nissl body reaction associated with the neurotoxin ricin which also invokes ribosomal dysfunction and has been used to mimic certain features of motor neurone disease. The cytopathology of DTX and ricin are compared in the Discussion.

Modeccin and volkensin but not abrin are effective suicide transport agents in rat CNS

Suicide transport is a term applied to the technique of producing anatomically selective neural lesions using axonally transported cytotoxins. Because the cytotoxic lectins, abrin, modeccin and volkensin are effective suicide transport agents in the peripheral nervous system, the present study sought to determine if they were effective suicide transport agents in the rat CNS. Toxins were stereotactically pressure microinjected unilaterally into the caudate nucleus of rats. After 2-13 days survival, brain sections were processed for catecholamine histofluorescence or Nissl stained with Cresyl violet. All 3 agents produced extensive necrosis at the caudate injection site. In addition, modeccin and volkensin but not abrin produced destruction of neurons in the ipsilateral substantia nigra and intralaminar thalamus. Histofluorescence confirmed loss of dopaminergic neurons from the ipsilateral substantia nigra after modeccin or volkensin but not abrin injections. These results indicate that modeccin and volkensin are effective suicide transport agents within the rat CNS, presumably due to retrograde axonal transport of the toxins. These agents may prove extremely useful in producing anatomically selective lesions of neurons afferent to a toxin injection site.