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Fabry disease (FD) is an X-linked lysosomal storage disorder with intracellular accumulation of globotriaosylceramide (Gb3) due to α-galactosidase A deficiency. We studied α-galactosidase A knockout mice (GLA KO) as a model for sensory disturbance and pain in FD.
Pain associated behavior of young (3 months) and old (≥18 months) GLA KO mice and wildtype (WT) littermates in an inflammatory and a neuropathic pain model was investigated. Furthermore, affective and cognitive behavior was assessed in the naïve state and in an inflammatory pain model. Gene and protein expression of pain associated ion channels and Gb3 accumulation in dorsal root ganglion (DRG) neurons was determined. We also performed patch clamp analysis on cultivated DRG neurons and human embryonic kidney 293 (HEK) cells expressing voltage-gated-sodium channel 1.7 (Nav1.7) as an in vitro model of FD. Intracellular Gb3 deposits were modulated using shRNA silencing of α-galactosidase A.
After intraplantar injection of complete Freund`s adjuvant (CFA) and chronic constriction injury (CCI) of the right sciatic nerve, old GLA KO mice did not develop heat and mechanical hypersensitivity in contrast to young GLA KO and old WT mice. Additionally, we found no relevant differences between genotypes and age-groups in affective and cognitive behavior in the naïve state and after CFA injection. Gene and protein expression analysis provided no explanation for the observed sensory impairment. However, cultured DRG neurons of old GLA KO mice revealed a marked decrease of sodium and Ih-currents compared to young GLA KO and old WT mice. DRG neurons of old GLA KO mice displayed substantial intracellular accumulation of Gb3 compared to young GLA KO and old WT mice. Similar to cultured neurons, sodium currents were also decreased in HEK cells treated with shRNA and consecutively increased intracellular Gb3 deposits compared to the control condition, but could be rescued by treatment with agalsidase-alpha.
Our study unveils that, similar to patients with FD, GLA KO mice display age-dependent sensory deficits. However, contrary to patients, GLA KO mice are also protected from hypersensitivity induced by inflammation and nerve lesion due to Gb3-dependent and reversible reduction of neuronal sodium- and Ih-currents. Our data provide evidence for direct Gb3-dependent ion channel impairment in sensory DRG neurons as a potential contributor to sensory dysfunction and pain in FD.
In the central nervous system, excitatory and inhibitory signal transduction processes are mediated by presynaptic release of neurotransmitters, which bind to postsynaptic receptors. Glycine receptors (GlyRs) and GABAA receptors (GABAARs) are ligand-gated ion channels that enable synaptic inhibition. One part of the present thesis elucidated the role of the GlyRα1 β8 β9 loop in receptor expression, localization, and function by means of amino acid substitutions at residue Q177. This residue is underlying a startle disease phenotype in the spontaneous mouse model shaky and affected homozygous animals are dying 4-6 weeks after birth. The residue is located in the β8 β9 loop and thus part of the signal transduction unit essential for proper ion channel function. Moreover, residue Q177 is involved in a hydrogen network important for ligand binding. We observed no difference in ion channel trafficking to the cellular membrane for GlyRα1Q177 variants. However, electrophysiological measurements demonstrated reduced glycine, taurine, and β alanine potency in comparison to the wildtype protein. Modeling revealed that some GlyRα1Q177 variants disrupt the hydrogen network around residue Q177. The largest alterations were observed for the Q177R variant, which displayed similar effects as the Q177K mutation present in shaky mice. Exchange with structurally related amino acids to the original glutamine preserved the hydrogen bond network. Our results underlined the importance of the GlyR β8 β9 loop for proper ion channel gating.
GlyRs as well as GABAARs can be modulated by numerous allosteric substances. Recently, we focused on monoterpenes from plant extracts and showed positive allosteric modulation of GABAARs. Here, we focused on the effect of 11 sesquiterpenes and sesquiterpenoids (SQTs) on GABAARs. SQTs are compounds naturally occurring in plants. We tested SQTs of the volatile fractions of hop and chamomile, including their secondary metabolites generated during digestion. Using the patch-clamp technique on transfected cells and neurons, we were able to observe significant GABAAR modulation by some of the compounds analyzed. Furthermore, a possible binding mechanism of SQTs to the neurosteroid binding site of the GABAAR was revealed by modeling and docking studies. We successfully demonstrated GABAAR modulation by SQTs and their secondary metabolites.
The second part of the thesis investigated three-dimensional (3D) in vitro cell culture models which are becoming more and more important in different part of natural sciences. The third dimension allows developing of complex models closer to the natural environment of cells, but also requires materials with mechanical and biological properties comparable to the native tissue of the encapsulated cells. This is especially challenging for 3D in vitro cultures of primary neurons and astrocytes as the brain is one of the softest tissues found in the body. Ultra-soft matrices that mimic the neuronal in vivo environment are difficult to handle. We have overcome these challenges using fiber scaffolds created by melt electrowriting to reinforce ultra-soft matrigel. Hence, the scaffolds enabled proper handling of the whole composites and thus structural and functional characterizations requiring movement of the composites to different experimental setups. Using these scaffold-matrigel composites, we successfully established methods necessary for the characterization of neuronal network formation. Before starting with neurons, a mouse fibroblast cell line was seeded in scaffold-matrigel composites and transfected with the GlyR. 3D cultured cells displayed high viability, could be immunocytochemically stained, and electrophysiologically analyzed.
In a follow-up study, primary mouse cortical neurons in fiber-reinforced matrigel were grown for up to 21 days in vitro. Neurons displayed high viability, and quantification of neurite lengths and synapse density revealed a fully formed neuronal network already after 7 days in 3D culture. Calcium imaging and patch clamp experiments demonstrated spontaneous network activity, functional voltage-gated sodium channels as well as action potential firing. By combining ultra-soft hydrogels with fiber scaffolds, we successfully created a cell culture model suitable for future work in the context of cell-cell interactions between primary cells of the brain and tumor cells, which will help to elucidate the molecular pathology of aggressive brain tumors and possibly other disease mechanisms.
Immune-mediated polyneuropathies like chronic inflammatory demyelinating polyradiculoneuropathy or Guillain-Barré syndrome are rare diseases of the peripheral nervous system. A subgroup of patients harbors autoantibodies against nodal or paranodal antigens, associated with a distinct phenotype and treatment response. In a part of patients with pathologic paranodal or nodal immunoreactivity the autoantigens remain difficult or impossible to determine owing to limitations of the used detection approach - usually ELISAs (enzyme-linked-immunosorbent-assays) - and incomplete knowledge of the possible autoantigens. Due to their high-throughput, low sample consumption and high sensitivity as well as the possibility to display many putative nodal and paranodal autoantigens simultaneously, peptide microarray-based approaches are prime candidates for the discovery of novel autoantigens, point-of-care diagnostics and, in addition, monitoring of pathologic autoimmune response. Current applications of peptide microarrays are however limited by high false-positive rates and the associated need for detailed follow-up studies and validation. Here, robust peptide microarray-based detection of antibodies and the efficient validation of binding signals by on-chip neutralization is demonstrated. First, autoantigens were displayed as overlapping peptide libraries in microarray format. Copies of the biochips were used for the fine mapping of antibody epitopes. Next, binding signals were validated by antibody neutralization in solution. Since neutralizing peptides are obtained in the process of microarray fabrications, neither throughput nor costs are significantly altered. Similar in-situ validation approaches could contribute to future autoantibody characterization and detection methods as well as to therapeutic research. Areas of application could be expanded to any autoimmune-mediated neurological disease as a long-term vision.
The mammalian central clock, located in the suprachiasmatic nucleus (SCN) of the anterior hypothalamus, controls circadian rhythms in behaviour such as the sleep-wake cycle. It is made up of approximately 20,000 heterogeneous neurons that can be classified by their expression of neuropeptides. There are three major populations: AVP neurons (arginine vasopressin), VIP neurons (vasoactive intestinal peptide), and GRP neurons (gastrin releasing peptide). How these neuronal clusters form functional units to govern various aspects of rhythmic behavior is poorly understood. At a molecular level, biological clocks are represented by transcriptional-posttranslational feedback loops that induce circadian oscillations in the electrical activity of the SCN and hence correlate with behavioral circadian rhythms. In mammals, the sleep wake cycle can be accurately predicted by measuring electrical muscle and brain activity. To investigate the link between the electrical activity of heterogeneous neurons of the SCN and the sleep wake cycle, we optogenetically manipulated AVP neurons in vivo with SSFO (stabilized step function opsin) and simultaneously recorded an electroencephalogram (EEG) and electromyogram (EMG) in freely moving mice. SSFO-mediated stimulation of AVP positive neurons in the anterior hypothalamus increased the total amount of wakefulness during the hour of stimulation. Interestingly, this effect led to a rebound in sleep in the hour after stimulation. Markov chain sleep-stage transition analysis showed that the depolarization of AVP neurons through SSFO promotes the transition from all states to wakefulness. After the end of stimulation, a compensatory increase in transitions to NREM sleep was observed. Ex vivo, SSFO activation in AVP neurons causes depolarization and modifies the activity of AVP neurons. Therefore, the results of this thesis project suggest an essential role of AVP neurons as mediators between circadian rhythmicity and sleep-wake behaviour.
The Stiff-person syndrome (SPS) is a rare autoimmune disease that is characterized by symptoms including stiffness in axial and limb muscles as well as painful spasms. Different variants of SPS are known ranging from moderate forms like the stiff-limb syndrome to the most severe form progressive encephalomyelitis with rigidity and myoclonus (PERM). SPS is elicited by autoantibodies that target different pre- or postsynaptic proteins. The focus of the present work is on autoantibodies against the glycine receptor (GlyR). At start of the present thesis, as main characteristic of the GlyR autoantibody pathology, receptor cross-linking followed by enhanced receptor internalization and degradation via the lysosomal pathway was described. If binding of autoantibodies modulates GlyR function and therefore contributes to the GlyR autoantibody pathology has not yet been investigated. Moreover, not all patients respond well to plasmapheresis or other treatments used in the clinic. Relapses with even higher autoantibody titers regularly occur.
In the present work, further insights into the disease pathology of GlyRα autoantibodies were achieved. We identified a common GlyRα1 autoantibody epitope located in the far N-terminus including amino acids A1-G34 which at least represent a part of the autoantibody epitope. This part of the receptor is easily accessible for autoantibodies due to its location at the outermost surface of the GlyRα1 extracellular domain. It was further investigated if the glycosylation status of the GlyR interferes with autoantibody binding. Using a GlyRα1 de-glycosylation mutant exhibited that patient autoantibodies are able to detect the de-glycosylated GlyRα1 variant as well. The direct modulation of the GlyR analyzed by electrophysiological recordings demonstrated functional alterations of the GlyR upon autoantibody binding. Whole cell patch clamp recordings revealed that autoantibodies decreased the glycine potency, shown by increased EC50 values. Furthermore, an influence on the desensitization behavior of the receptor was shown. The GlyR autoantibodies, however, had no impact on the binding affinity of glycine. These issues can be explained by the localization of the GlyR autoantibody epitope. The determined epitope has been exhibited to influence GlyR desensitization upon binding of allosteric modulators and differs from the orthosteric binding site for glycine, which is localized much deeper in the structure at the interface between two adjacent subunits. To neutralize GlyR autoantibodies, two different methods have been carried out. Transfected HEK293 cells expressing GlyRα1 and ELISA plates coated with the GlyRα1 extracellular domain were used to efficiently neutralize the autoantibodies. Finally, the successful passive transfer of GlyRα1 autoantibodies into zebrafish larvae and mice was shown. The autoantibodies detected their target in spinal cord and brain regions rich in GlyRs of zebrafish and mice. A passive transfer of human GlyRα autoantibodies to zebrafish larvae generated an impaired escape behavior in the animals compatible with the abnormal startle response in SPS or PERM patients.
Autoantibodies against proteins of the node of Ranvier have been identified in a subset of patients with chronic inflammatory demyelinating polyradiculoneuropathy (CIDP). Main antigens targeted by autoantibodies are the paranodal proteins contactin 1 (CNTN1), neurofascin (NF) 155 or contactin associated protein (Caspr) as well as the nodal NF186. Several studies investigated the role of anti-paranodal autoantibodies in the pathophysiology of CIDP leading to the current knowledge that immunoglobulin G (IgG)4 deposition leads to detachment of myelin from the axon at the paranodes. However, many questions remain unsolved. Thus, autoantibodies against NF155 have been well studied and their pathogenicity has been proven in an animal model in vivo. However, in some patients, autoantibodies against all isoforms of NF are detectable. These anti-pan-NF autoantibodies occur more rarely and lead to a very severe clinical phenotype. As the pathogenesis of patient-derived autoantibodies against pan-NF has never been investigated in vivo before, we used an animal model to study the effect of acute exposure to anti-pan-NF IgG3 by intraneural injections to the rat sciatic nerve. In addition, we used anti-NF155 IgG4 from a seropositive patient. Behavioral testings as well as nerve conduction studies did not re- veal any deficits after injected neither for anti-NF155 nor for anti-pan-NF autoantibodies. This leads to the suspicion that the disease is more likely induced by a chronic process.
A common symptom in patients with anti-CNTN1 associated neuropathy is sensory ataxia and therefore, an involvement of dorsal root ganglia (DRGs) is hypothesized. We show that sera from anti-CNTN1 positive patients specifically bind to DRG neurons in vitro and reduce surface expression of CNTN1. This is most probably due to internalization mediated by coexisting IgG3 although IgG4 is the predominant subclass of autoantibodies. As it is known that CNTN1 interacts with the β1 subunit of specific sodium channels we analyzed channel expression and sodium currents of DRG neurons after incubation with anti-CNTN1 positive patients’ sera. We identified reduced sodium currents after long-term treatment with patients’ material although surface channel expression remained stable. We therefore concluded that CNTN1 might influence channel properties indirectly through auxiliary β1 subunits. Moreover, we suggest an involvement of DRG neurons in the pathogenesis of anti-CNTN1 associated CIDP as medium-large size neurons are more affected than small neurons. However, the exact mechanism of how anti-CNTN1 autoantibodies influence sodium channels should be subject of further studies.
Furthermore, preliminary results indicate that the epitope for anti-CNTN1 autoantibodies from seropositive patients might be associated with distinct clinical features. We could show that autoantibodies might be either directed against a conformational epitope as binding is prevented after deletion of the first immunoglobulin (Ig) domain of CNTN1 or against the fibronectin type III (FnIII) domains. Strikingly, both patients with FnIII do- main specificity had very high titers of anti-CNTN1 autoantibodies and a chronic disease progression, whereas patients binding to a conformational epitope or to the Ig domains are related to a relapsing-remitting or even monophasic disease course. However, these results need to be further confirmed before a clear statement can be made.
In conclusion, the present study contributes to elucidate the pathogenesis of peripheral neuropathies associated with anti-paranodal autoantibodies. However, further studies are required including a higher number of patients as well as considering effects on structures like DRGs besides the node of Ranvier to fully understand the disease mechanisms.
Chronic pain conditions are a major reason for the utilization of the health care system. Inflammatory pain states can persist facilitated by peripheral sensitization of nociceptors. The voltage-gated sodium channel 1.9 (NaV1.9) is an important regulator of neuronal excitability and is involved in inflammation-induced pain hypersensitivity. Recently, oxidized 1-palmitoyl-2-arachidonoyl-sn-glycerol-3-phosphatidylcholine (OxPAPC) was identified as a mediator of acute inflammatory pain and persistent hyperalgesia, suggesting an involvement in proalgesic cascades and peripheral sensitization. Peripheral sensitization implies an increase in neuronal excitability. This thesis aims to characterize spontaneous calcium activity in neuronal compartments as a proxy to investigate neuronal excitability, making use of the computational tool Neural Activity Cubic (NA3). NA3 allows automated calcium activity event detection of signal-close-to-noise calcium activity and evaluation of neuronal activity states. Additionally, the influence of OxPAPC and NaV1.9 on the excitability of murine dorsal root ganglion (DRG) neurons and the effect of OxPAPC on the response of DRG neurons towards other inflammatory mediators (prostaglandin E2, histamine, and bradykinin) is investigated. Using calcium imaging, the presence of spontaneous calcium activity in murine DRG neurons was established. NA3 was used to quantify this spontaneous calcium activity, which revealed decreased activity counts in axons and somata of NaV1.9 knockout (KO) neurons compared to wildtype (WT). Incubation of WT DRG neurons with OxPAPC before calcium imaging did not show altered activity counts compared to controls. OxPAPC incubation also did not modify the response of DRG neurons treated with inflammatory mediators. However, the variance ratio computed by NA3 conclusively allowed to determine neuronal activity states. In conclusion, my findings indicate an important function of NaV1.9 in determining the neuronal excitability of DRG neurons in resting states. OxPAPC exposition does not influence neuronal excitability nor sensitizes neurons for other inflammatory mediators. This evidence reduces the primary mechanism of OxPAPC-induced hyperalgesia to acute effects. Importantly, it was possible to establish an approach for unbiased excitability quantification of DRG neurons by calcium activity event detection and calcium trace variance analysis by NA3. It was possible to show that signal-close-to-noise calcium activity reflects neuronal excitability states.
Parkinson’s disease (PD) is the second most common neurodegenerative disease with still no cure available. The prominent feature of PD is the loss of dopaminergic neurons at the Substantia nigra (SN). Genetic and environmental insults affecting the SNCA gene encoding the alpha-Synuclein (alpha-Syn) protein result into an aberrant form of the protein with higher propensity towards oligomerization becoming part of insoluble inclusions called Lewy Bodies (LB). LB impart cytotoxicity leading to neurodegeneration, activate resident microglia and escape to the periphery where they get captured by dendritic cells and presented to naïve T cells. Proliferating effector T lymphocytes invade the brain releasing proinflammatory cytokines and performing a cytotoxic effect on neurons.
In this study, we examine the hypothesis that the expansion of regulatory T cells (Treg) could exert an anti-inflammatory effect that averts neurodegeneration in the AAV1/2-A53T-alpha-Syn mouse model for PD.
Mice brains were transfected by a unilateral stereotaxic injection at the SN region with a chimeric Adeno-Associated Viral vector of serotypes 1 and 2 (AAV1/2) carrying the A53T-mutated human SNCA gene encoding the readily aggregating aberrant alpha-Syn (AAV1/2-A53T-alpha-Syn). One week after injection, mice were treated with the CD28 superagonistic antibody (CD28SA), known to significantly expand the Treg population. Mice were then analyzed by behavioral analysis using the Rotarod performance test and the Cylinder test. The impact of CD28SA on the immune system was examined by flow cytometry. The integrity of the nigrostriatal system was assessed by stereological quantification of Tyrosine hydroxylase (TH)-stained dopaminergic neurons in SN and optical density measurements of TH-stained striatum. The mechanism of action of CD28SA was analyzed by treating PD mice alternatively with a Treg adoptive transfer, while CD28SA effect on levels of neurotrophic factors was quantified by ELISA.
We observed an expansion of Treg by FACS analyses three days after CD28SA treatment, demonstrating target engagement. CD28SA treatment of AAV1/2-A53T-alpha-Syn mice provided neuroprotection evident through elevated numbers of dopaminergic neurons in the SN and higher optical density of TH-staining in the striatum, in CD28SA-treated mice compared to PBS-treated control mice, and that was reflected in an enhanced performance in behavioral studies. Additionally, brain infiltration of proinflammatory activated T lymphocytes (CD4+CD69+ and CD8+CD69+ cells), that were obvious in PBS-treated AAV1/2-A53T-alpha-Syn control mice, was augmented in PD mice receiving CD28SA. The alternative treatment with Treg adoptive transfer did replicate the beneficial effects of CD28SA indicating that Treg expansion is the main effector mechanism by which it exerts its neuroprotective effect. CD28SA treatment of PD mice led to an increase of GDNF and BDNF in some brain structures that was not observed in untreated mice.
We conclude that in the AAV1/2-A53T-alpha-Syn PD mouse model, CD28SA suppresses proinflammation, reverses behavioral deficits and is neuroprotective on SN dopaminergic cells.