2D vs 3D morphological analysis of dorsal root ganglia in health and painful neuropathy

Dorsal root ganglia (DRGs) are clusters of sensory neurons that transmit the sensory information from the periphery to the central nervous system, and satellite glial cells (SGCs), their supporting trophic cells. Sensory neurons are pseudounipolar neurons with a heterogeneous neurochemistry reflecting their functional features. DRGs, not protected by the blood brain barrier, are vulnerable to stress and damage of different origin (i.e., toxic, mechanical, metabolic, genetic) that can involve sensory neurons, SGCs or, considering their intimate intercommunication, both cell populations. DRG damage, primary or secondary to nerve damage, produces a sensory peripheral neuropathy, characterized by neurophysiological abnormalities, numbness, paraesthesia and dysesthesia, tingling and burning sensations and neuropathic pain. DRG stress can be morphologically detected by light and electron microscope analysis with alterations in cell size (swelling/atrophy) and in different sub-cellular compartments (i.e., mitochondria, endoplasmic reticulum, and nucleus) of neurons and/or SGCs. In addition, neurochemical changes can be used to portray abnormalities of neurons and SGC. Conventional immunostaining, i.e., immunohistochemical detection of specific molecules in tissue slices can be employed to detect, localize and quantify particular markers of damage in neurons (i.e., nuclear expression ATF3) or SGCs (i.e., increased expression of GFAP), markers of apoptosis (i.e., caspases), markers of mitochondrial suffering and oxidative stress (i.e., 8-OHdG), markers of tissue inflammation (i.e., CD68 for macrophage infiltration), etc. However classical (2D) methods of immunostaining disrupt the overall organization of the DRG, thus resulting in the loss of some crucial information. Whole-mount (3D) methods have been recently developed to investigate DRG morphology and neurochemistry without tissue slicing, giving the opportunity to study the intimate relationship between SGCs and sensory neurons in health and disease. Here, we aim to compare classical (2D) vs whole-mount (3D) approaches to highlight “pros” and “cons” of the two methodologies when analysing neuropathy-induced alterations in DRGs

Expression, distribution and glutamate uptake activity of excitatory aminoacid transporters in vitro cultures of embryonic rat dorsal root ganglia cells

Glutamate is the major mediator of excitatory signalling in the mammalian central nervous system, but it has recently been shown to play also a role in the transduction of sensory input at the periphery and in peripheral neuropathies. New advances in research have demonstrated that rat peripheral sensory terminals and dorsal root ganglia (DRG) express molecules involved in glutamate signalling, including high-affinity membrane-bound glutamate transporters (Excitatory Aminoacid Transporters, EAATs) and that alterations in their expression and/or functionality can be implicated in several models of peripheral neuropathy, neuropathic pain and hyperalgesia. Since EAATS might represent an interesting target for pharmacological intervention, the knowledge of their distribution and functionality deserves to be improved. Here we describe, through immunofluorescence assays, immunoblotting and beta-counter analysis of (H3) L-glutamate uptake, the expression, distribution and activity of the EAATs in in vitro cultures of embryonic DRG sensory neurons, sensory neurons+satellite cells and satellite cells. In this study we demonstrated that EAATs are expressed in all cultures, but that their distribution recognizes a peculiar pattern for each of them, since EAATs immunolabelling was differentially expressed in the cytoplasm of neuronal or satellite cells. This result was further confirmed by immunoblotting. Moreover, both cell types showed a strong sodium-ATP-dependent (active) glutamate uptake activity. However, the net (i.e. active transport minus passive diffusion) glutamate transport was more marked in neuronal cultures when cells were grown and maintained without satellite cells. These results, that demonstrate that functionally active EAATs can be studied in DRG cell cultures, provide further evidence for a role of glutamatergic transport in the peripheral nervous system and will be useful for testing whether any change occurs in in vitro models of peripheral nervous system damage. This work was supported in part by an unrestricted research grant from the “Fondazione Banca del Monte di Lombardia”

Chemotherapy-induced peripheral neuropathy in immunodeficient mice: new useful ready-to-use animal models

Cisplatin, paclitaxel, and bortezomib represent the most employed chemotherapy regimens for the treatment of genitourinary cancers, breast and lung cancers and multiple myeloma. Nevertheless, their clinical use is often associated to the development of peripheral neuropathies characterized mostly by sensory alterations and pain (Argyriou et al., 2012). Several rat models of chemotherapy-induced peripheral neuropathy (CIPN) had been established in the past to describe the mechanisms of its development and pathogenesis. However, only few cancer cell lines induce the development of cancer in the rat, while immunodeficient mice best allowed human cancers xenografts to study at the same time, the antineoplastic and neurotoxic effects of chemotherapy. Here we characterized neuropathic pain, neurophysiological and neuropathological alterations induced by chronic chemotherapy in immunodeficient nude mice. Mice were treated with effective doses of cisplatin (4 mg/Kg, i.p), paclitaxel (80 mg/Kg, i.v) and bortezomib (0.8 mg/Kg, i.v) for a 4-6 weeks period. At the end of the 6th week all chemotherapy regimens determined a significant impairment of neurophysiologic parameters, mechanical allodynia and thermal hypo-or hyperalgesia. Light microscopy analysis of dorsal root ganglia (DRG) showed that bortezomib induced morphological alterations in the sensory neurons and satellite cells as dark inclusions and clear vacuolation throughout the cytoplasm. Moreover, sporadic episodes of neuronal degeneration were evident. DRG of cisplatin-treated animals showed severe neuronal atrophy. Moreover bortezomib induced moderate to severe axonal degeneration of the myelinated fibers in the sciatic nerves. More severe changes were induced by paclitaxel where also areas of fibers loss were frequently observed and rare pathological abnormalities were present in unmyelinated fibers. Similar changes were evident in paclitaxel-treated mice (degeneration at different stage of severity in myelinated fibers, enlargement of Schwann cells, fibers loss and dark inclusions in the unmyelinated fibers). These schedules demonstrated to be effective in mimicking clinical features of painful neuropathies and allows to combine the study of peripheral neurotoxicity of chemotherapy drugs to their anti-tumour activity against cancers of human origin

A new animal model of chemotherapy induced peripheral neurotoxicity: the immune-deficient mouse

Cisplatin, paclitaxel and bortezomib are anticancer drugs widely employed in the treatment of different solid tumours even though peripheral neurotoxicity represents a major limitation in their clinical use. During the last decades many rat and mouse models of chronic chemotherapyinduced peripheral neurotoxicity (CIPN) have been characterized from the clinical, pathological, neurophysiological and behavioural point of view. These models were based on immune-competent animals, however in preclinical oncology immune-deficient mice are mainly used. In this respect, the development of immune-deficient mice models could represent a basis for the concurrent investigation of both anticancer drug efficacy and neurotoxicity in animals implanted with human-derived cancer. Moreover, in the same model, neuroprotective effects and non-interference with anticancer activity could be better studied. In this study we established the feasibility of new immune-deficient murine models of peripheral neurotoxicity induced by three anticancer drugs. Forty-eight athymic nude mice were randomized in 4 groups of 12 animals, three were treated respectively with cisplatin, paclitaxel and bortezomib, and one was left untreated. All animals were followed up for 6 weeks. They were examined at baseline, week 4 and 6 for neurophysiological functions and behavioural tests, whilst morphological and morphometric analysis were performed on dorsal root ganglia (DRG) and peripheral nerves collected after 4 and 6 weeks of treatment. The results of the study demonstrate that athymic nude mice show CIPN features similar to those observed in conventional models even if some differences must be remarked as the prolonged time of treatment required to develop a chronic neuropathy. The characterization of this new mice model of CIPN will allow studies of antineoplastic and neurotoxic effects in the same animal

Morphofunctional characterization of peripheral nerve damage and recovery in sphyngomielinase deficient mice

Mutation of the acid sphingomyelinase (ASM) gene and its reduced enzymatic activity is the main cause of the Type A Niemann-Pick disease. Recent advances demonstrated that ASM is necessary and sufficient to control the formation and release of microvesiscles containing the proinflammatory cytokine interleukin-1β (IL-1β) by glial cells [1]. Since IL-1β modulates the events caused by nerve damage and repair and seems to act as a neuro-modulator between activated glia and neurons [2], the control of its production and secretion might represent a new strategy in nerve regeneration and in the control of neuropathic pain. In this study we used a well-characterized ASM knockout mouse (ASMKO, [3]) to evaluate, through a multimodal approach, the onset and the course of the morphological and functional nerve damage and of neuropathic pain after sciatic nerve crush. Adult (1 and 5 month-old) male ASMKO and age-matched wild-type (WT) mice underwent sciatic nerve crush lesion. Nerve conduction velocity (NCV), walking track analysis followed by ultra-structural and morphometric analysis of sciatic nerves were performed to evaluate the features of nerve damage. Thermal (Plantar test) and mechanical sensitivity (Dynamic Plantar Aesthesiometer apparatus) were used to measure the severity of neuropathic pain. Moreover, the rotarod test completed the analysis as an indicator of motor impairment. One or two months after the nerve crush motor functional recovery was similar in WT and KO mice and the NCV measures performed in the sciatic nerve demonstrated a moderate and progressive improvement of nerve function. The results of the morphological examination confirmed the expected course of nerve recovery, but also demonstrated defective nerve regeneration, particularly evident in older, but already present in younger ASMKO mice. Behavioral tests suggested that the mutated phenotype in ASMKO might have an effect on the onset and development of mechanical and thermal hyperalgesia after nerve crush in both 1 - month and 5 - months - old groups. In conclusion, these data suggest a possible role for ASM-related microvesicles in nerve regeneration and suggest that targeting the IL-1β production and release may represent a new therapeutic strategy for the treatment of nerve damage and neuropathic pain

Givinostat-Liposomes: Anti-Tumor Effect on 2D and 3D Glioblastoma Models and Pharmacokinetics

Glioblastoma is the most common and aggressive brain tumor, associated with poor prognosis and survival, representing a challenging medical issue for neurooncologists. Dysregulation of histone-modifying enzymes (HDACs) is commonly identified in many tumors and has been linked to cancer proliferation, changes in metabolism, and drug resistance. These findings led to the development of HDAC inhibitors, which are limited by their narrow therapeutic index. In this work, we provide the proof of concept for a delivery system that can improve the in vivo half-life and increase the brain delivery of Givinostat, a pan-HDAC inhibitor. Here, 150-nm-sized liposomes composed of cholesterol and sphingomyelin with or without surface decoration with mApoE peptide, inhibited human glioblastoma cell growth in 2D and 3D models by inducing a time-and dose-dependent reduction in cell viability, reduction in the receptors involved in cholesterol metabolism (from −25% to −75% of protein levels), and reduction in HDAC activity (−25% within 30 min). In addition, liposome-Givinostat formulations showed a 2.5-fold increase in the drug half-life in the bloodstream and a 6-fold increase in the amount of drug entering the brain in healthy mice, without any signs of overt toxicity. These features make liposomes loaded with Givinostat valuable as potential candidates for glioblastoma therapy

Oxaliplatin-induced peripheral neurotoxicity: morphological characterization in different mouse strains

Oxaliplatin is one of the most effective anticancer drug, particularly employed in the treatment of colorectal cancer, but one of the major limitation in its use is peripheral neurotoxicity. Oxaliplatin induced peripheral neurotoxicity (OIPN) has a high incidence and is frequently long lasting or permanent. Neuropathy is characterized by distal sensory impairment initially in the legs, then extending to the arms. A prominent manifestation of sensitive damage is ataxia. Besides chronic neurotoxicity, many patients experience an acute, rapidly developing cold-induced sensory neuropathy, usually resolving within one week. OIPN clinical manifestations reflect the involvement of dorsal root ganglia (DRG) as primary target of the drug toxicity. Although this assumption is largely accepted and some pathogenetic hypothesis have been proposed, mechanisms at the basis of OIPN need to be clearly defined. OIPN may vary in frequency and severity among different cancer patients despite equal treatment schedules. A genetic susceptibility for more severe oxaliplatin-induced peripheral neurotoxicity (OIPN) has been suggested but never confirmed. Therefore we designed a study to assess the phenotypic differences induced by oxaliplatin treatment in six different mice strains (Balb c, AJ, C57Bl6, FVB, DBA, CD1) aiming at identifying the more and less severely affected. Animals were treated with OHP 3.5 mg/Kg/iv twice weekly x 4 weeks and evaluated before and after treatment. In all strains we performed a multimodal characterization of its neurotoxicity through morphological and morphometrical assessment in caudal nerve and DRG at light and electron microscopy, intra-epidermal nerve fibers density quantification, evaluation of mechanical and cold allodynia/hypoaesteshesia, caudal and digital nerve conduction velocity, activity of wide dynamic range (WDR) neurons of the spinal dorsal horn. Our preliminary data suggest that all the strains show signs of OIPN but not the same modifications in the parameters examined. We will show these results with particular attention to morphological data. This study suggests that genetic variability might have a role in the type and severity of OHP-induced peripheral damage

Multimodal assessment of painful peripheral neuropathy induced by chronic oxaliplatin-based chemotherapy in mice

<p>Abstract</p> <p>Background</p> <p>A major clinical issue affecting 10-40% of cancer patients treated with oxaliplatin is severe peripheral neuropathy with symptoms including cold sensitivity and neuropathic pain. Rat models have been used to describe the pathological features of oxaliplatin-induced peripheral neuropathy; however, they are inadequate for parallel studies of oxaliplatin's antineoplastic activity and neurotoxicity because most cancer models are developed in mice. Thus, we characterized the effects of chronic, bi-weekly administration of oxaliplatin in BALB/c mice. We first studied oxaliplatin's effects on the peripheral nervous system by measuring caudal and digital nerve conduction velocities (NCV) followed by ultrastructural and morphometric analyses of dorsal root ganglia (DRG) and sciatic nerves. To further characterize the model, we examined nocifensive behavior and central nervous system excitability by <it>in vivo </it>electrophysiological recording of spinal dorsal horn (SDH) wide dynamic range neurons in oxaliplatin-treated mice</p> <p>Results</p> <p>We found significantly decreased NCV and action potential amplitude after oxaliplatin treatment along with neuronal atrophy and multinucleolated DRG neurons that have eccentric nucleoli. Oxaliplatin also induced significant mechanical allodynia and cold hyperalgesia, starting from the first week of treatment, and a significant increase in the activity of wide dynamic range neurons in the SDH.</p> <p>Conclusions</p> <p>Our findings demonstrate that chronic treatment with oxaliplatin produces neurotoxic changes in BALB/c mice, confirming that this model is a suitable tool to conduct further mechanistic studies of oxaliplatin-related antineoplastic activity, peripheral neurotoxicity and pain. Further, this model can be used for the preclinical discovery of new neuroprotective and analgesic compounds.</p

Anti-tumor Efficacy Assessment of the Sigma Receptor Pan Modulator RC-106. A Promising Therapeutic Tool for Pancreatic Cancer

Introduction: Pancreatic cancer (PC) is one of the most lethal tumor worldwide, with no prognosis improvement over the past 20-years. The silent progressive nature of this neoplasia hampers the early diagnosis, and the surgical resection of the tumor, thus chemotherapy remains the only available therapeutic option. Sigma receptors (SRs) are a class of receptors proposed as new cancer therapeutic targets due to their over-expression in tumor cells and their involvement in cancer biology. The main localization of these receptors strongly suggests their potential role in ER unfolded protein response (ER-UPR), a condition frequently occurring in several pathological settings, including cancer. Our group has recently identified RC-106, a novel pan-SR modulator with good in vitro antiproliferative activities toward a panel of different cancer cell lines. In the present study, we investigated the in vitro properties and pharmacological profile of RC-106 in PC cell lines with the aim to identify a potential lead candidate for the treatment of this tumor.Methods: Pancreatic cancer cell lines Panc-1, Capan-1, and Capan-2 have been used in all experiments. S1R and TMEM97/S2R expression in PC cell lines was quantified by Real-Time qRT-PCR and Western Blot experiments. MTS assay was used to assess the antiproliferative effect of RC-106. The apoptotic properties of RC-106 was evaluated by TUNEL and caspase activation assays. GRP78/BiP, ATF4, and CHOP was quantified to evaluate ER-UPR. Proteasome activity was investigated by a specific fluorescent-based assay. Scratch wound healing assay was used to asses RC-106 effect on cell migration. In addition, we delineated the in vivo pharmacokinetic profile and pancreas distribution of RC-106 in male CD-1 mice.Results: Panc-1, Capan-1, and Capan-2 express both SRs. RC-106 exerts an antiproliferative and pro-apoptotic effect in all examined cell lines. Cells exposure to RC-106 induces the increase of the expression of ER-UPR related proteins, and the inhibition of proteasome activity. Moreover, RC-106 is able to decrease PC cell lines motility. The in vivo results show that RC-106 is more concentrated in pancreas than plasma.Conclusion: Overall, our data evidenced that the pan-SR modulator RC-106 is an optimal candidate for in vivo studies in animal models of PC