Browsing by Subject "SOD1"

Amyotrophic lateral sclerosis (ALS) is a rare fatal neurodegenerative disease in which both the upper and lower motor neurons degenerate. Pathological features of the disease include misfolded proteins and accumulations in the central nervous system. The molecular mechanisms of the disease include neuroinflammation, glutamate induced excitotoxicity, and endoplasmic reticulum stress (ER-stress). Numerous genetic defects have been identified in the background of ALS, the most common mutations are in the C9ORF72, SOD1, TDP43 and FUS genes. For each gene mutation, it is important to develop a reliable animal model of ALS for studying pathology and testing new therapies. The most common and most recently found gene mutation, the C9ORF72 repeat expansion mutation, does not yet have an established animal disesase model. The molecular mechanisms of the disease include neuroinflammation, glutamate induced excitotoxicity, and endoplasmic reticulum stress (ER- stress). There is no drug treatment to cure or slow ALS, so the need for new drug therapies that affect the course of the disease is significant. Cerebral dopamine neurotrophic factor (CDNF) protects and restores dopamine neurons and controls ER-stress in preclinical models of Parkinson’s disease. CDNF has also been shown to improve motor coordination as well as protect spinal cord neurons from cell destruction in ALS genetic SOD1- G93A mouse and TDP-43M337 animal models. The purpose of this master's thesis study was to characterize the changes related to neurodegeneration and neuroinflammation in the new C9ORF72-500 disease model and study ER stress of the SOD1-93A disease model and the effect of CDNF on ER stress in SOD1-model and on inflammation in C9-model. In the first sub-study, brain sections from C9ORF72 transgenic and wild-type mice at different time points were subjected to six different immunohistological stainings. The results were compared at each time point (30, 70 and 170) between the wild type and the transgenic group. In another sub-study, spinal cord sections from CDNF snd vehicle treated SOD1- G93A mice were subjected to immunofluorescence staining, after which the intensity of their ER stress marker, GRP78, was analyzed using a confocal microscope. GFAP stained brain sections from CDNF and vehicle treated C9ORF72 mice were analyzed using microscope and imaging analyses. The results of the first sub-study showed neuroinflammation at 24 weeks timepoint in the transgenic group compared to wild-type mice. Pathological features of C9-ALS, various protein accumulations, were observed only in the transgenic group, mainly at 24 weeks. No neuronal loss was observed in this study. The obtained results support the previously published research results and support the reliability of the studied disease model. In the second sub-study ER stress levels were higher in SOD1-mice compared to wild-type mice. Single intracerebroventrical CDNF injection reduced ER stress in SOD1-G93A transgenic mice almost to the same level as ER stress in wild-type mice. CDNF treatment also showed a tendency for reducing inflammation in hippocampus and motor cortex of C9ORF72 mice. The results confirm the pathological role of ER stress in ALS and show that CDNF reduces ER stress when administered as early in the disease as possible, when neuronal damage begins to occur but does not yet lead to neuronal destruction. CDNF appears to be a promising drug candidate for the treatment of ALS and should therefore be further investigated.

Amyotrophic lateral sclerosis (ALS) is a progressive neurodegenerative disorder caused by degeneration of motor neurons in brain and spinal cord. The degeneration of motor neurons leads to muscle atrophy and paralysis. Currently there is no cure for ALS. Available drugs for ALS can lengthen the survival time by a couple of months. Several factors involve the pathophysiology of ALS, such as endoplasmic reticulum stress and neuroinflammation. Mesencephalic astrocyte-derived neurotrophic factor (MANF) is a protein which has shown neuroprotective effects on animal models of Parkinson disease and brain ischemia. C-terminal fragment of MANF can cross the blood-brain barrier, allowing it to be administered subcutaneously instead of injected directly into the brain. The experimental part consists of two parts. The aim of the first part was to study the pharmacokinetic properties of next generation MANF (C-MANF). The aim of the second part was to elucidate the effect of twice a week administered subcutaneous injection of C-MANF in genetic SOD1-G93A mouse model and its neuroprotective effects by assessing protection of lumbar motor neurons. Pharmacokinetic properties of C-MANF were determined in wild type mice after a single subcutaneous injection of C-MANF at different time points by using indirect ELISA assay. The effects of C-MANF in SOD1-G93A mouse model were assessed by subcutaneous injection of either C-MANF or PBS twice a week and by monitoring clinical score and motor behavior of mice from 10 weeks of age to clinical endpoint. Hematoxylin eosin staining was used to study neuroprotective effects of C-MANF. C-MANF administered subcutaneously is absorbed into the blood circulation and the highest serum concentration of C-MANF is after 60 minutes of dosing. Subcutaneously injected C-MANF also crosses the blood-brain barrier and reach the brain in 120 minutes. C-MANF did not preserve motor function or ameliorated ALS symptoms in SOD1-G93A mouse model. In this study C-MANF did not increase the survival of SOD1-G93A mice. C-MANF did not significantly protect motor neurons from degeneration even though there was a slight trend between the groups. No beneficial effects were observed with C-MANF in SOD1-G93A mouse model and therefore the dose and frequency of administration of C-MANF were not optimal. Subcutaneously injected C-MANF provides a safer dosing option for neurodegenerative disorders.