Increased levels of phosphoinositides cause neurodegeneration in a Drosophila model of amyotrophic lateral sclerosis

Forrest, Stuart Gordon

January 2013

The human VAMP-associated protein B (hVAPB) has been shown to cause a range of motor neurodegenerative diseases, including amyotrophic lateral sclerosis 8 (ALS8) and spinal muscular atrophy (SMA). However, the molecular mechanisms underlying VAPB-induced neurodegeneration remain elusive. We sought to address this question by identifying VAPB interacting proteins, which may be affected by the disease causative mutations. Using a combination of biochemical and genetic approaches in Drosophila, we confirmed the evolutionarily conserved phosphoinositide phosphatase Sac1 (Suppressor of Actin 1), as a DVAP binding partner and showed that the two proteins colocalise in the endoplasmic reticulum. We also show that DVAP function is required to maintain normal levels of phosphoinositides (PIs) and that downregulation of either Sac1 or DVAP at the larval neuromuscular junction (NMJ) affects a number of synaptic processes, including axonal transport, synaptic growth, microtubule integrity and localisation of several postsynaptic components. We found that double knock down of DVAP and Sac1 induces no further increase in the severity of the mutant phenotypes when compared to either single mutant alone. This, together with the similarity in mutant phenotypes, indicates that the two genes function in a common pathway. In flies carrying the ALS8 mutation (DVAP-P58S), we observed reduced viability, locomotion defects and early death in surviving adults, closely matching the phenotypes of both DVAP and Sac1 downregulation. Additionally, transgenic expression of DVAP-P58S in the motor system elicits synaptic defects similar to those of either Sac1 or DVAP loss-of-function, including an increase in the levels of PtdIns-4-Phosphate (PI4P), the substrate of Sac1. Consistent with these observations, we found that Sac1 is sequestered into DVAP-P58S mediated aggregates and that downregulation of PI4P in neurons rescues the neurodegenerative and the synaptic phenotypes associated with DVAP-P58S transgenic expression. Together our data unveil a previously unknown function for Sac1 in neurodegeneration and synaptic function, as well as provide evidence for a dominant negative mechanism for phosphoinositide-mediated ALS8 pathogenesis. We also highlight a causative role for increased PI4P levels in VAPB-P56S induced neurodegeneration.

616.8

White matter integrity, executive dysfunction, and processing speed in amyotrophic lateral sclerosis

Pettit, Lewis David

January 2014

Cognitive impairment in amyotrophic lateral sclerosis (ALS) is characterized by deficits on tests of executive functions however the contribution of processing speed is unknown. By contrast, multiple sclerosis (MS) is a disorder in which slowed processing speed is regarded as the core deficit, however, methodology is often confounded by tasks which depend on motor speed. MRI studies have revealed multi-system cerebral involvement in ALS, with evidence of reduced white matter volume and integrity in predominantly frontotemporal regions. The current study had two aims. Firstly, to investigate whether cognitive impairments in ALS and MS are due to executive dysfunction or slowed processing speed, independent of motor dysfunction. Secondly, to investigate the relationship between specific cognitive impairments and the integrity of distinct white matter tracts in ALS. Twenty-nine ALS patients, twenty-five MS patients, and matched healthy control groups were administered a dual task paradigm and processing speed tasks in which stimulus presentation times were manipulated. In addition background measures of executive functioning, working memory, verbal memory, and language were administered. White matter integrity was investigated using region-of-interest (ROI) and tract based spatial statistics (TBSS) analyses of diffusion MRI data. ALS patients did not show impairments in tests of processing speed, but deficits were revealed in the dual task, as well as background tests of executive functioning, working memory, and verbal memory. MS patients also exhibited deficits in the dual task as well as background tests of executive functioning, working memory, and verbal memory. However, in contrast to ALS patients, a processing speed deficit was also observed in MS. ROI analyses revealed significant differences in fractional anisotropy (FA) and mean diffusivity (<D>) between ALS patients and healthy controls. Reduced integrity was observed in the corticospinal tracts and prefrontal and temporal white matter tracts including uncinate fasciculus, inferior longitudinal fasciculus, and regions of the cingulum. Significant differences also emerged in the white matter underlying the superior, medial and inferior frontal gyri, and the temporal gyri. Similar group differences were found in the TBSS analyses; ALS patients displayed prominent changes in the corticospinal tract and corpus callosum as well as extensive changes in prefrontal and temporal tracts and association fibres. Correlations between task performance and ROI parameters revealed that dual task performance was associated with FA in the middle frontal gyrus white matter while letter fluency indices correlated with FA in the corpus callosum and corticospinal tracts. Furthermore, verbal memory performance correlated with FA in the inferior longitudinal fasciculus and working memory performance correlated with <D> in uncinate fasciculus and hippocampal portion of the cingulum. Correlations with TBSS revealed significant associations between letter fluency indices and FA in the corticospinal tracts and anterior corpus callosum. The current study demonstrates that cognitive impairment in ALS is not due to slowed processing speed. Moreover dual task deficits are related to distinct prefrontal tract involvement in ALS, whilst fluency deficits may reflect decreasing callosal integrity. Deficits in working memory and verbal memory are related to white matter changes in fibre bundles connecting prefrontal, temporal, and limbic structures.

616.8

Investigation of the interactions of DVAP-33A, the orthologue of human VAPB

Parry, Katherine Elizabeth

January 2011

Amyotrophic Lateral Sclerosis is the most common type of motor neuron disease, characterized by progressive degeneration of the upper and lower motor neurons. Sufferers present with symptoms of muscle weakness and this quickly develops on to paralysis and finally death due to respiratory failure within 5 years of disease onset. Although the majority of cases are sporadic, about 10% are familial and it is hoped that through the investigation of these few cases a greater understanding of the disease process, the reasons for its delayed onset and vulnerability of motor neurons will be achieved. Recently a novel mutation linked to ALS was discovered in an evolutionary conserved protein named Vesicle associated membrane protein (VAMP) associated protein B (VAPB). VAPB is an integral type II membrane protein localised at the Endoplasmic Reticulum and thought to have a role in protein transport. The orthologue in Drosophila has been shown to be involved in the homeostatic regulation of bouton formation at the Neuromuscular Junction through an association with the microtubule network. To elucidate the mechanism through which this protein causes ALS, Pennetta et al have created a Drosophila model of the disease by expressing the mutated orthologue in the fly. To complement this model, I have undertaken a number of biochemical experiments to look for potential interactors of the VAP proteins. The yeast two hybrid system utilises the yeast GAL4 transcriptional activator to indicate a protein interaction within a yeast cell and can be used to test a cDNA library for interactors. Through this technique a number of interesting binding partners have been found that may play crucial roles in the progression of the disease.

616.8

Characterization of Peripherin Isoforms in Amyotrophic Lateral Sclerosis

McLean, Jesse Ryan

17 January 2012

Peripherin is a type III intermediate filament protein that is predominately expressed in the peripheral nervous system and in subsets of efferent projections in the central nervous systems. While the exact role of peripherin remains unclear, it is found upregulated after traumatic neuronal injury and in the devastating neurodegenerative disease amyotrophic lateral sclerosis (ALS). Interestingly, peripherin overexpressing transgenic mice succumb to motor neuron disease with pathological hallmarks reminiscent of those found in ALS. Pathological peripherin abnormalities occur with high frequency in both familial and sporadic forms of ALS, with peripherin found associated with the majority intracellular inclusions present within degenerating motor neuron populations. The findings of peripherin mutations in sporadic ALS have reinforced the importance of peripherin as a prospective etiological or propagative factor of disease pathogenesis. Surprisingly, inherited peripherin gene mutations have not been identified; as such, understanding the post-transcriptional mechanism at which peripherin imparts its effect(s) is considered a key goal and represents a pathological point-of-convergence for an otherwise complex, multifaceted disease. Prior to the commencement of this work, our group identified the presence of an abnormal peripherin alternative splice variant upregulated in ALS. In doing so, we consistently observed the presence of a second peripherin species of ~45 kDa on immunoblots of cell lysates derived from full-length peripherin transfections. Here, we identified this protein as a constitutively expressed isoform, termed Per-45, that arises from alternative translation and that is required for normal filament assembly: changes to the normal isoform expression pattern are associated with malformed filaments and intracellular inclusions. In lieu of the possibility of distinct peripherin intra-isoform associations, we identified isoform-specific expression and ratio changes in traumatic neuronal injury, in mouse models of motor neuron disease, and in ALS. Finally, we explored the interrelationships between peripherin isoform expression, protein aggregation, and neuritic outgrowth by linking these phenotypes with major pathogenic features associated with ALS, including in vitro models of oxidation, glutamate excitotoxicity, and neuroinflammation. Overall, this thesis provides exciting new insight into our knowledge of basic IF biology and the role of peripherin isoforms in injury and in motor neuron disease.

Amyotrophic Lateral Sclerosis (ALS)

Isoforms

alternative translation

aggregation

0317

Characterization of Peripherin Isoforms in Amyotrophic Lateral Sclerosis

McLean, Jesse Ryan

17 January 2012

Peripherin is a type III intermediate filament protein that is predominately expressed in the peripheral nervous system and in subsets of efferent projections in the central nervous systems. While the exact role of peripherin remains unclear, it is found upregulated after traumatic neuronal injury and in the devastating neurodegenerative disease amyotrophic lateral sclerosis (ALS). Interestingly, peripherin overexpressing transgenic mice succumb to motor neuron disease with pathological hallmarks reminiscent of those found in ALS. Pathological peripherin abnormalities occur with high frequency in both familial and sporadic forms of ALS, with peripherin found associated with the majority intracellular inclusions present within degenerating motor neuron populations. The findings of peripherin mutations in sporadic ALS have reinforced the importance of peripherin as a prospective etiological or propagative factor of disease pathogenesis. Surprisingly, inherited peripherin gene mutations have not been identified; as such, understanding the post-transcriptional mechanism at which peripherin imparts its effect(s) is considered a key goal and represents a pathological point-of-convergence for an otherwise complex, multifaceted disease. Prior to the commencement of this work, our group identified the presence of an abnormal peripherin alternative splice variant upregulated in ALS. In doing so, we consistently observed the presence of a second peripherin species of ~45 kDa on immunoblots of cell lysates derived from full-length peripherin transfections. Here, we identified this protein as a constitutively expressed isoform, termed Per-45, that arises from alternative translation and that is required for normal filament assembly: changes to the normal isoform expression pattern are associated with malformed filaments and intracellular inclusions. In lieu of the possibility of distinct peripherin intra-isoform associations, we identified isoform-specific expression and ratio changes in traumatic neuronal injury, in mouse models of motor neuron disease, and in ALS. Finally, we explored the interrelationships between peripherin isoform expression, protein aggregation, and neuritic outgrowth by linking these phenotypes with major pathogenic features associated with ALS, including in vitro models of oxidation, glutamate excitotoxicity, and neuroinflammation. Overall, this thesis provides exciting new insight into our knowledge of basic IF biology and the role of peripherin isoforms in injury and in motor neuron disease.

Amyotrophic Lateral Sclerosis (ALS)

Isoforms

alternative translation

aggregation

0317

Identification of novel genes interacting with DVAP, the causative gene of ALS8 in humans

Sanhueza Cubillos, Mario Andrés

January 2015

Amyotrophic lateral sclerosis (ALS) is a major neurodegenerative disease caused by the death of motor neurons leading to paralysis. Mechanisms underlying the pathogenesis of the disease remain unknown but with the identification of causative genes from ALS patients, some processes have been linked to the disease. One of these genes is VAPB, a highly conserved protein involved in lipid transfer, vesicle metabolism and synaptic morphology. We modeled in Drosophila the disease-linked P56S mutation (DVAP-P58S) and observed with the expression of this allele neurodegeneration in the eye and loss of motor performance. These phenotypes provide an excellent opportunity to use fly’s genetics to find novel genetic interactors of DVAP and understand ALS pathomechanism. Therefore, we carried out a large scale genetic screen by crossing the ALS model with a collection of P-element overexpression lines. After the analysis of 1183 lines, we obtained 71 modifier lines that suppress DVAP-induced neurodegeneration and 14 lines that enhance this phenotype, decreasing furthermore the eye size and viability of the offspring. To confirm that the effect of modifier lines was caused by a specific gene, we validated them with independent alleles of those genes. Using different sources, we were able to confirm the effect of 63 of the 85 modifiers, providing a strong confirmation of their effect. When we studied the effect of the modifier genes co-expressed with DVAP-P58S in the nervous system, we detected that 46 lines presented the same modifying effect in adult viability and 58 in the motor performance of the adult offspring. Considering the stronger readouts, we obtained 42 genes as novel high confidence DVAP genetic interactors. To understand furthermore the way they are affecting DVAP neurodegeneration, we carried out a series of bioinformatic analyses using Drosophila and human databases. Lipid droplets, vesicle metabolism and cell proliferation appear as the most important categories found in the screen, all processes conserved when analysed with human orthologs of the modifiers. Further characterisation of the endocytosis-linked modifier Rab5 and the predicted DVAP-interactors Rab7 and Rab11, showed that the suppression effect is not only confirmed in vivo but is also conserved in human tissue from ALS patients. These data validate our genetic screen and at the same time open novel opportunities to understand ALS mechanisms and find possible therapeutic targets.

616.8

Using induced pluripotent stem cells to model glial-neuronal interactions in TDP-43 proteinopathies

Serio, Andrea

January 2014

Amyotrophic Lateral Sclerosis (ALS) is an incurable late onset neurodegenerative disorder characterised by the specific loss of motor neurones (MNs). It has been recently demonstrated that Transactive response DNA-binding protein (TDP-43) is the dominant disease protein in both ALS and a sub-group of frontotemporal lobar degeneration (FTLDTDP). Moreover, the identification of TARDBP mutations in familial ALS confirms a mechanistic link between the observed mis-accumulation of TDP-43 and neurodegeneration but also provides an opportunity to establish an in vitro platform to model these diseases, based on patient-derived induced pluripotent stem cells (iPSCs). This study presents the optimization of an iPSC-based platform to study the consequences of TDP-43 M337V mutation in human functional populations of MNs and astrocytes in isolation as well as in co-culture. To develop this platform, two protocols to differentiate patient-derived iPSCs into functional MNs and astrocytes were first optimized, and the obtained cellular populations were then used to characterize the behaviour of mutant TDP-43 and its effect on the different cell types. This study show that it is possible to use iPSC-based platforms to recapitulate in vitro key aspects of TDP-43 proteinopathies such as MN cell autonomous toxicity and TDP-43 accumulation, but they can also be used to highlight previously unrecognised disease specific mechanisms and to test novel therapeutic approaches. Moreover, by performing co-culture experiments it was possible to evaluate the effects of M337V astrocytes on the survival of wild-type and M337V TDP-43 motor neurons, showing that mutant TDP-43 astrocytes do not adversely affect survival of co-cultured neurons. This iPSC-based platform represents an in vitro model to study both the effect of somatic mutations on isolated patient-specific cultures, but also to investigate cellular autonomy and neurodegeneration in the context of TDP-43 proteinopathies.

616.8

SOD1 Aggregation : Relevance of thermodynamic stability

Lang, Lisa

January 2017

Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease affecting the upper and lower motor neurons causing muscle atrophy and paralysis followed by death. Aggregates containing superoxide dismutase (SOD1) are found as pathological hallmark in diseased ALS patients. Consequently ALS is regarded as a protein misfolding disorder like Alzheimer’s disease and Parkinson’s disease. So far, little is known about the cause and mechanism behind SOD1 aggregation but the inherent property of all polypeptide chains to form stable aggregated structures indicates that the protein misfolding diseases share a common mechanism. Our results show that SOD1 aggregation starts from the globally unfolded state, since fibrillation is fastest at full occupancy of denatured protein induced either by chemical denaturation or mutation. Even so, the fibrillation rate shows a surprisingly weak dependence on the concentration of globally unfolded SOD1 indicating fibril fragmentation as the dominant mechanism for aggregate formation. This is further supported by the observation that the SOD1 sample has to be mechanically agitated for fibrillation to occur.  Interestingly, we observe a similar SOD1 aggregation behaviour in vivo, where the survival times of ALS transgenic mice correlates with mutant stability, and aggregate growth depends weekly on the concentration of unfolded monomer. Additionally, in-cell NMR measurements reveal that in live cells the thermodynamic equilibrium is shifted towards the unfolded state of SOD1, which is also more fully extended than in vitro. This suggests that the globally unfolded aggregation competent protein is more abundant in the crowded environment in vivo than dilute in vitro conditions. Finally, antibody analysis of aggregates from ALS transgenic mice reveals the existence of aggregate strains involving different parts of the protein depending on mutation, which may offer an explanation for the various disease phenotypes observed in ALS. Altogether these findings provide important clues for understanding SOD1 aggregation with implications for ALS, as well as other protein misfolding diseases.

Aggregation

misfolding

Superoxide dismutase (SOD1)

Amyotrophic lateral sclerosis (ALS)

unfolding

thermodynamic stability

Upplevelsen av att vara närstående till personer med Amyotrofisk lateralskleros (ALS) : En kvalitativ intervjustudie

Nygren, Emelie, Malin, Andersson

January 2019

Bakgrund: Amyotrofisk lateralskleros är en neurologisk sjukdom som orsakar muskelförtvining. I Sverige insjuknar årligen runt 220–250 personer i ALS och totalt lever cirka 750–850 personer med sjukdomen. Etiologin är ännu okänd för sjukdomen som leder till döden.   Syfte: Att belysa upplevelsen av att vara närstående till personer med ALS.   Metod: En kvalitativ intervjustudie baserad på sex intervjuer vilka analyserades utifrån en kvalitativ manifest innehållsanalys.   Resultat: I analysprocessen framkom tre huvudkategorier; Närståendes upplevelser att leva med personer med ALS, Närstående upplevelser av vården och Närståendes önskemål angående vårdmöten. Att leva i den direkta närheten av någon som drabbats av ALS skapar mycket oro, ångest och förtvivlan. Närstående upplever förtvivlan då informationen anses otillräcklig vilket också gäller kunskapen kring sjukdomen bland vårdpersonalen.   Slutsats: Att drabbas av ALS är att få sin dödsdom. Sjukdomen drabbar inte bara patienten utan också närstående. Den slutsats som kan dras utifrån studiens resultat är att det saknas kunskap, information och stöttning av de närstående.

Amyotrophic lateral sclerosis (ALS)

Närstående

Upplevelser

Medical and Health Sciences

Medicin och hälsovetenskap

Nursing

Omvårdnad

Finding new genes causing motor neuron diseases

Gopinath, Sumana

January 2007

Doctor of Philosophy / Abstract Neurodegenerative disorders are a diverse group of disorders that affect specific subsets of neurons. Motor neuron diseases, neurodegenerative disorders of motor neurons, are seen commonly as sporadic cases and less frequently as familial disease forms. The familial forms show genetic and phenotypic heterogeneity. Clinically motor neuron diseases may be seen as rapidly progressive disorders like amyotrophic lateral sclerosis, ALS or slowly progressive disorders like hereditary motor neuropathies, HMN. The only proven causes for motor neuron diseases are gene mutations that lead to motor neuron degeneration in familial disease forms. Only some of these genes have been identified and have contributed greatly to our understanding of the neurobiology of familial and sporadic disease forms. Identification of additional disease causing genes would help enhance our knowledge of the pathophysiological mechanisms underlying all forms of motor neuron disorders, which would lead to early diagnoses, effective prophylaxis and efficient therapies for these disorders. This study aimed to find gene mutations that cause rapid and slowly progressive familial motor neuron disorders in Australian families and to determine their relevance to sporadic forms of motor neuron disease. The familial forms of ALS show reduced disease penetrance, that is, not all gene mutation carriers manifest the disease. This study examines ALS penetrance in a group of Australian families. The most frequently observed mutations in ALS families are cytosolic superoxide dismutase/SOD1 gene mutations. In a collection of ALS families in our centre, families without the common SOD1 gene mutations were genotyped for other ALS genes and loci and studied using genetic linkage and haplotype analyses. Studies in a large Australian ALS family further confirmed genetic heterogeneity in non-SOD familial ALS, all known autosomal dominant ALS genes and chromosomal loci were excluded as cause of disease in this family. Such families can be studied further to identify additional disease genes and loci mapped in other ALS families. These families represent powerful resources for identification of additional ALS genes. Identifying the pathogenic genes in families with reduced disease penetrance may be more relevant to sporadic forms of disease. dHMN is a chronic neurodegenerative disorder predominantly affecting motor neurons. In a large Australian dHMN family, all the known dHMN genes and chromosomal loci were excluded as cause of disease. A genome wide microsatellite screen was performed in this family and genetic linkage was established to a novel 12.98 Mb locus on chromosome 7q34.2-q36. Candidate genes in this large interval will be screened based on their function and expression profile. Identification of a new dHMN locus provides the basis for future identification of a novel gene involved in motor neuron degeneration. Genes in dHMN have been shown to be pathogenic in ALS and Charcot Marie Tooth syndromes. The new locus for dHMN mapped in this project would lead to identification of a novel dHMN gene, which may elucidate the pathogenesis underlying a wide range of neurodegenerative disorders.

linkage

motor neuron disease, MND

Amyotrophic lateral sclerosis, ALS

Hereditary motor neuropathy, HMN

incomplete penetrance