Efficient Dispatch of Multi-object Polymorphic Call Sites in Contextual Role-Oriented Programming Languages

Adaptive software becomes more and more important as computing is increasingly context-dependent. Runtime adaptability can be achieved by dynamically selecting and applying context-specific code. Role-oriented programming has been proposed as a paradigm to enable runtime adaptive software by design. Roles change the objects’ behavior at runtime, thus adapting the software to a given context. The cost of adaptivity is however a high runtime overhead stemming from executing compositions of behavior-modifying code. It has been shown that the overhead can be reduced by optimizing dispatch plans at runtime when contexts do not change, but no method exists to reduce the overhead in cases with high context variability. This paper presents a novel approach to implement polymorphic role dispatch, taking advantage of run-time information to effectively guard abstractions and enable reuse even in the presence of variable contexts. The concept of polymorphic inline caches is extended to role invocations. We evaluate the implementation with a benchmark for role-oriented programming languages achieving a geometric mean speedup of 4.0× (3.8× up to 4.5×) with static contexts, and close to no overhead in the case of varying contexts over the current implementation of contextual roles in Object Team

TDP-43 expression in mouse models of amyotrophic lateral sclerosis and spinal muscular atrophy

<p>Abstract</p> <p>Background</p> <p>Redistribution of nuclear TAR DNA binding protein 43 (TDP-43) to the cytoplasm and ubiquitinated inclusions of spinal motor neurons and glial cells is characteristic of amyotrophic lateral sclerosis (ALS) pathology. Recent evidence suggests that TDP-43 pathology is common to sporadic ALS and familial ALS without SOD1 mutation, but not SOD1-related fALS cases. Furthermore, it remains unclear whether TDP-43 abnormalities occur in non-ALS forms of motor neuron disease. Here, we characterise TDP-43 localisation, expression levels and post-translational modifications in mouse models of ALS and spinal muscular atrophy (SMA).</p> <p>Results</p> <p>TDP-43 mislocalisation to ubiquitinated inclusions or cytoplasm was notably lacking in anterior horn cells from transgenic mutant SOD1^G93Amice. In addition, abnormally phosphorylated or truncated TDP-43 species were not detected in fractionated ALS mouse spinal cord or brain. Despite partial colocalisation of TDP-43 with SMN, depletion of SMN- and coilin-positive Cajal bodies in motor neurons of affected SMA mice did not alter nuclear TDP-43 distribution, expression or biochemistry in spinal cords.</p> <p>Conclusion</p> <p>These results emphasise that TDP-43 pathology characteristic of human sporadic ALS is not a core component of the neurodegenerative mechanisms caused by SOD1 mutation or SMN deficiency in mouse models of ALS and SMA, respectively.</p

Pre-symptomatic development of lower motor neuron connectivity in a mouse model of severe spinal muscular atrophy

The childhood motor neuron disease spinal muscular atrophy (SMA) results from reduced expression of the survival motor neuron (SMN) gene. Previous studies using in vitro model systems and lower organisms have suggested that low levels of Smn protein disrupt prenatal developmental processes in lower motor neurons, influencing neuronal outgrowth, axon branching and neuromuscular connectivity. The extent to which these developmental pathways contribute to selective vulnerability and pathology in the mammalian neuromuscular system in vivo remains unclear. Here, we have investigated the pre-symptomatic development of neuromuscular connectivity in differentially vulnerable motor neuron populations in Smn(-/-);SMN2 mice, a model of severe SMA. We show that reduced Smn levels have no detectable effect on morphological correlates of pre-symptomatic development in either vulnerable or stable motor units, indicating that abnormal pre-symptomatic developmental processes are unlikely to be a prerequisite for subsequent pathological changes to occur in vivo. Microarray analyses of spinal cord from two different severe SMA mouse models demonstrated that only minimal changes in gene expression were present in pre-symptomatic mice. In stark contrast, microarray analysis of late-symptomatic spinal cord revealed widespread changes in gene expression, implicating extracellular matrix integrity, growth factor signalling and myelination pathways in SMA pathogenesis. Taken together, these data suggest that reduced Smn levels induce SMA pathology by instigating rapidly progressive neurodegenerative pathways in lower motor neurons around the time of disease onset rather than by modulating pre-symptomatic neurodevelopmental pathways

Alternative Splicing Events Are a Late Feature of Pathology in a Mouse Model of Spinal Muscular Atrophy

Spinal muscular atrophy is a severe motor neuron disease caused by inactivating mutations in the SMN1 gene leading to reduced levels of full-length functional SMN protein. SMN is a critical mediator of spliceosomal protein assembly, and complete loss or drastic reduction in protein leads to loss of cell viability. However, the reason for selective motor neuron degeneration when SMN is reduced to levels which are tolerated by all other cell types is not currently understood. Widespread splicing abnormalities have recently been reported at end-stage in a mouse model of SMA, leading to the proposition that disruption of efficient splicing is the primary mechanism of motor neuron death. However, it remains unclear whether splicing abnormalities are present during early stages of the disease, which would be a requirement for a direct role in disease pathogenesis. We performed exon-array analysis of RNA from SMN deficient mouse spinal cord at 3 time points, pre-symptomatic (P1), early symptomatic (P7), and late-symptomatic (P13). Compared to littermate control mice, SMA mice showed a time-dependent increase in the number of exons showing differential expression, with minimal differences between genotypes at P1 and P7, but substantial variation in late-symptomatic (P13) mice. Gene ontology analysis revealed differences in pathways associated with neuronal development as well as cellular injury. Validation of selected targets by RT–PCR confirmed the array findings and was in keeping with a shift between physiologically occurring mRNA isoforms. We conclude that the majority of splicing changes occur late in SMA and may represent a secondary effect of cell injury, though we cannot rule out significant early changes in a small number of transcripts crucial to motor neuron survival

TBK1 Mutation Spectrum in an Extended European Patient Cohort with Frontotemporal Dementia and Amyotrophic Lateral Sclerosis

We investigated the mutation spectrum of the TANK-Binding Kinase 1 (TBK1) gene and its associated phenotypic spectrum by exonic resequencing of TBK1 in a cohort of 2,538 patients with frontotemporal dementia (FTD), amyotrophic lateral sclerosis (ALS), or FTD plus ALS, ascertained within the European Early-Onset Dementia Consortium. We assessed pathogenicity of predicted protein-truncating mutations by measuring loss of RNA expression. Functional effect of in-frame amino acid deletions and missense mutations was further explored in vivo on protein level and in vitro by an NFκB-induced luciferase reporter assay and measuring phosphorylated TBK1. The protein-truncating mutations led to the loss of transcript through nonsense-mediated mRNA decay. For the in-frame amino acid deletions, we demonstrated loss of TBK1 or phosphorylated TBK1 protein. An important fraction of the missense mutations compromised NFκB activation indicating that at least some functions of TBK1 are lost. Although missense mutations were also present in controls, over three times more mutations affecting TBK1 functioning were found in the mutation fraction observed in patients only, suggesting high-risk alleles (P = 0.03). Total mutation frequency for confirmed TBK1 LoF mutations in the European cohort was 0.7%, with frequencies in the clinical subgroups of 0.4% in FTD, 1.3% in ALS, and 3.6% in FTD-ALS

Functional genetic analysis of motor neuron disease

Amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy (SMA) are the commonest motor neuron diseases of adult- and childhood onset. Alterations of the RNA binding protein TDP-43 are associated with most cases of ALS, while SMA is caused by deletion of the Survival Motor Neuron (SMN1) gene. SMN has been well characterised in its role in the assembly of the cellular machinery that carries out splicing of pre-mRNA, but is thought to have other functions in RNA metabolism unrelated to pre-mRNA splicing. It is conceivable that specific aspects of RNA handling are disrupted in both SMA and ALS. A variety of genetic, molecular and neuropathological approaches were applied to investigate a potential common pathway in these diseases. The spectrum of genetic mutations underlying motor neuron disorders were explored by screening patient DNA. Cell culture and mouse models were used to test the hypothesis that altered pre-mRNA splicing causes motor neuron death. Human neuropathological specimens were examined for changes in proteins involved in RNA metabolism. The results indicate that altered pre-mRNA splicing is a late occurrence in disease and more likely to be a consequence rather than the cause of motor neuron degeneration. However, the notion that RNA metabolism is highly relevant to motor neuron diseases was strengthened by the discovery of mutations in another RNA binding protein, FUS, in cases of ALS without TDP-43 pathology. Overall the findings highlight the need to consider disruption of mRNA transport and regulation of mRNA translation in future motor neuron disease research

Functional genetic analysis of motor neuron disease

Amyotrophic lateral sclerosis (ALS) and spinal muscular atrophy (SMA) are the commonest motor neuron diseases of adult- and childhood onset. Alterations of the RNA binding protein TDP-43 are associated with most cases of ALS, while SMA is caused by deletion of the Survival Motor Neuron (SMN1) gene. SMN has been well characterised in its role in the assembly of the cellular machinery that carries out splicing of pre-mRNA, but is thought to have other functions in RNA metabolism unrelated to pre-mRNA splicing. It is conceivable that specific aspects of RNA handling are disrupted in both SMA and ALS. A variety of genetic, molecular and neuropathological approaches were applied to investigate a potential common pathway in these diseases. The spectrum of genetic mutations underlying motor neuron disorders were explored by screening patient DNA. Cell culture and mouse models were used to test the hypothesis that altered pre-mRNA splicing causes motor neuron death. Human neuropathological specimens were examined for changes in proteins involved in RNA metabolism. The results indicate that altered pre-mRNA splicing is a late occurrence in disease and more likely to be a consequence rather than the cause of motor neuron degeneration. However, the notion that RNA metabolism is highly relevant to motor neuron diseases was strengthened by the discovery of mutations in another RNA binding protein, FUS, in cases of ALS without TDP-43 pathology. Overall the findings highlight the need to consider disruption of mRNA transport and regulation of mRNA translation in future motor neuron disease research.EThOS - Electronic Theses Online ServiceGBUnited Kingdo