A Study of the Mechanism of Motor Neuron Death in Amyotrophic Lateral Sclerosis

Politi, Kristin Ann

January 2017

Amyotrophic Lateral Sclerosis (ALS) is a fatal adult-onset paralytic disorder for which there is currently no cure. Underlying the disease mechanism of ALS is the spontaneous pathologic degeneration of motor neurons (MNs). Understanding the molecular mechanisms underlying spontaneous and selective MN demise is critical to the development of rational therapeutic strategies. In the current work, utilizing established in vitro models of ALS, I demonstrate that necroptosis, a form of caspase-independent programmed cell death (PCD), drives MN death. Pharmacologic inhibition and/or genetic silencing of receptor interacting protein kinase-1 (RIPK1), receptor interacting protein kinase-3 (RIPK3), and mixed lineage kinase domain-like-protein (MLKL) rescued MN death in vitro. While this core machinery was conserved, the requirement of nuclear factor kappa-B (NF-κB) and Bcl-2-associated X protein (Bax) deviated from known models of necroptosis. This divergence led me to consider that there may be a MN-specific program of necroptosis. Thus, I then used unbiased approaches, by meta-analyzing a gene expression signature captured from MNs undergoing cell death in vitro, to explore MN cell death drivers that may be engaged upstream or downstream to RIPK1/RIPK3/MLKL. I also explored the relevance of necroptosis to MN disease in vivo, in part by deleting RIPK3 from a genetic mouse model of familial ALS. Overall this approach did not rescue motor neuron loss, and there was no improvement in motor function, disease onset, or survival in these animals. I conclude that while necroptosis machinery drives motor neuron death in in vitro models of ALS, more work needs to be done to (1) assess the motor neuron-specific cell death program, and (2) evaluate the relationship, if any, of necroptosis to motor neuron disease in vivo.

Molecular biology

Biology

Neurosciences

Amyotrophic lateral sclerosis

Motor neurons

Topographical Projections of Limb-Innervating Motor Neurons in Drosophila melanogaster Specified by Morphological Transcription Factors and Downstream Cell Surface Proteins

Venkatasubramanian, Lalanti

January 2019

The nervous system integrates multiple sources of sensory information that ultimately controls motor neurons to generate complex movements. Motor neurons form topographically organised ‘myotopic maps’ between the nerve cord and muscles in the periphery to ensure that correct pre-motor inputs into motor dendrites are relayed through corresponding axons to the appropriate muscle groups. Therefore understanding the development and assembly of motor neuronss is crucial for understanding how animals execute various motor outputs. In adult Drosophila, ~50 motor neurons are topographically organized between each leg and the nerve cord in a highly stereotyped manner (Baek and Mann, 2009). In this thesis, I describe a novel group of transcription factors that act in a combinatorial manner to specify the projections of distinct Drosophila leg motor neurons. Our studies suggest that morphological transcription factors regulate various downstream cell-surface genes that are involved in the assembly of motor circuitry. Using in vivo live imaging I describe the developmental steps involved in Drosophila leg motor neuron axon targeting during metamorphosis and the spatial expression patterns of a novel hetero-binding Ig domain transmembrane protein family – the DIPs and Dprs (Ozkan et al., 2013) in leg neuro-musculature. I further describe a function between interacting partners DIP-alpha and Dpr10, expressed in subsets of leg motor neurons and muscles respectively, in establishing the final stereotyped terminal axon branching of corresponding motor neurons. The combinations of such interactions throughout development between leg motor neurons, not only with muscles in the periphery, but also among themselves, with leg sensory neurons and other components in the central nervous system may ultimately lead to synaptic specificity and stereotyped morphologies of Drosophila leg motor neurons.

Morphology

Neurosciences

Motor neurons

Drosophila melanogaster

Transcription factors

Novel survival factors with a gender specific twist for motor neurons

Wang, Pei-Yu, n/a

January 2006

The survival of motor neurons is controlled by multiple factors, which regulate different aspects of their physiology. The identification of these factors is important because of their relevance for motor neuron disease. This thesis began with a search for novel growth factors that naturally keep these neurons alive. Members of the TGF-β superfamily, including Mullerian inhibiting substance (MIS) and bone morphogenetic protein 6 (BMP6), were identified as putative survival factors following a cDNA microarray analysis of a mouse model of motor neuron disease. MIS is a gonad-derived hormone with a male bias. It induces the degeneration of the female reproductive tract during development and it was thought to have no physiological function outside of the reproductive system. In this thesis, multiple techniques were used to show that adult motor neurons produce MIS and its receptors. The copy number of MIS mRNA in motor neurons was comparable with that of the testis, whereas the mRNA of the MIS type II receptor (MISRII) in motor neurons appeared to be the most abundant receptor of the TGF-β superfamily. These results were confirmed using Western blot and immunohistochemistry. Thus, MIS may exert its function through an autocrine or a paracrine mechanism between neighbouring motor neurons. The function of MIS was examined using a culture system and a mouse null mutation of MISRII. The in vitro assays showed strong neurotrophic effects of MIS on embryonic motor neurons with the maximum extent of survival being similar to that achieved by the classical motor neuron survival factor, GDNF. MIS has a male bias in utero raising the issue of whether motor neurons are sexually dimorphic. Consistent with this, the number of motor neurons in the lumbar lateral motor column of neonatal male MISRII+/+ mice was 13 % greater than in female mice (P = 0.01). The nuclei of male motor neurons were approximately 20 % larger than their female counterparts (P = 0.000). MISRII-/- male mice had 18 % fewer motor neurons than wild-type males (P = 0.01) and the mean size of their motor neurons was 20 % smaller (P = 0.000). The number and size of motor neurons in the MISRII-/- males was not different to those of MISRII+/+ females. These results implicate MIS as being responsible for neuronal survival as well as producing sexual dimorphism of the limb innervating motor neurons. Since MIS does not appear to be expressed in the embryonic neuromuscular system, it is postulated that MIS is a gonad-derived neurotrophic factor for developing motor neurons. The BMP type II receptor (BMPRII) was the second most abundant receptor of the TGF-β superfamily expressed by motor neurons. One of its ligands, BMP6, was found to have a neurotrophic effect on motor neurons in culture but was slightly less potent than MIS. BMP6 mRNA was detected in nerve, skeletal muscle and spinal cord, but not in motor neurons. BMP6 immunoreactivity was mainly associated with the myelinated Schwann cells and satellite glia that surround motor neurons. In skeletal muscles, immunoreactivity was not detected in muscle fibers, nor the postsynaptic region of the neuromuscular junction (NMJ). BMP6 was, however, associated with the interstitial cells of skeletal muscles. Double nerve ligations were used to examine whether Schwann cell-derived BMP6 interacts with motor neurons. Consistent with this, BMP6 was retrogradely transported in motor axons. These observations collectively suggest that BMP6 is a glia-derived regulator of motor neurons. MIS and minority of BMP6 were anterogradely transported towards the NMJ. Their receptors, MISRII and BMPRII, were detected in the postsynaptic portions of the adult NMJ. These observations raised the possibility that MIS and BMP6 may be regulators of the adult NMJ. Since functional redundancy amongst the members of the TGF-β superfamily has been suggested, the function of MIS/BMP6 signaling at the NMJ was therefore examined in mice with muscle-specific deletion of Smad4, a central mediator of TGF-β superfamily pathways. More than 75% of animals lacking Smad4 in muscles died before embryonic day (E) 14 and none survived postnally. This was due to the loss of functional Smad4 in developing cardiac myocytes, which resulted in severe heart defects and early death of embryos. Thus, the function of MIS/BMP6 signaling at the adult NMJ could not be studied. Finally, this thesis briefly examined the phenotypes of mice carrying double null mutations of MISRII and TGF-β2. The animals died at an early stage and showed a more severe phenotype than either of the single null mutants. This suggests that functional redundancy among members of the TGF-β superfamily exists in many organs. In summary, motor neurons require multiple sources of growth factors for their survival. MIS and BMP6 were discovered as novel survival factors for motor neurons in this study. MIS was implicated as a regulator of sexual dimorphism in developing motor neurons, whereas both MIS and BMP6 appear to regulate mature motor neurons, and possibly the NMJ.

motor neurons

physiology

sex differences

growth factors

survival analysis (Biometry)

The genetic regulation of sex-specific motorneurons by the doublesex gene in Drosophila melanogaster and the genetic characterization of an interaction with the sex determination hierarchy

Larsen, DeLaine D.

24 July 1998

The remodeling of the central nervous system (CNS) during metamorphosis in Drosophila melanogaster is a prime model system in which to study the genetic control of the sexual dimorphisms in the abdominal ganglion of the CNS. I have been using a P[tau-lacZ] enhancer trap line, 4.078, to label a segmentally repeated subset of abdominal motorneurons in order to assess the function of the sex determination hierarchy in controlling sex-specific development of the adult nervous system. In both the male and female larva there are 8 sets of these labeled abdominal motorneurons but only six sets in males and five sets in females survive in the adult. When this P[tau-lacZ] reporter construct is placed into a doublesex (dsx) mutant background, all 8 sets of these labeled abdominal motorneurons survive in both male and female adults. These results strongly suggest that dsx plays a role in the sex-specific survival of larval neurons that have functions in the adult. During the construction of mutant strains containing the sex determining genes transformer (tra) and transformer-2 (tra2), a genetic interactor was discovered in the P[tau-lacZ] 4.078 line. Female flies heterozygous for either tra or tra-2 alleles and the P[tau-lacZ] 4.078 developed with masculinized external and internal sex-specific structures. The external sex-specific structures, such as the genitalia, and ventral muscles are dependent on dsx gene function and a dorsal sex-specific muscle is dependent on fruitless (fru) gene function. From standard genetic crosses, I have characterized and demonstrated that the genetic interaction is linked to the P-element insertion site, which maps to the 85-87 region on the right arm of the third chromosome. By genetic analysis, this new genetic interactor appears to interfere with the tra and tra2 regulated female specific functions of both dsx and fru, potentially by reducing the female-specific splicing of the primary transcripts of the genes dsx and fru. To test the possibility that this newly described genetic interactor was allelic to a known gene, B52, that maps to the same region of the chromosome and alters dsx splicing, complementation tests were conducted which showed that the P[tau-lacZ] is not allelic B52. Additional phenotypes were observed in the crosses that first detected the interaction, suggesting that this newly described locus may affect other gene functions as well. Among the phenotypes observed were XX intersexes, male-female gynandromorphs (XX//XO mosaics), and non-disjunction events evident as XO males and XXY females. This new locus may represent a new member of the family of genes that influence regulated splicing events. / Graduation date: 1999

Drosophila melanogaster -- Genetics

Sex determination, Genetic

Motor neurons

Motor neuron development in the Drosophila embryonic central nervous system /

Layden, Michael J,

January 2006

Thesis (Ph. D.)--University of Oregon, 2006. / Typescript. Includes vita and abstract. Includes bibliographical references (leaves 101-115). Also available for download via the World Wide Web; free to University of Oregon users.

Cellular approach for the treatment of amyotrophic lateral sclerosis using adult mesenchymal stem cells

Boucherie, Cédric

12 December 2008

Amyotrophic lateral sclerosis (ALS) is a progressive, lethal, degenerative disorder of the CNS. The hallmark of this disease is the premature and selective death of upper and lower motor neurons (MNs) in the brain and spinal cord, leading to fatal paralysis. Although the archetypal vision of neurotoxicity in neurodegenerative diseases is based on the idea that a specific neuronal population is particularly vulnerable to a cumulative toxic event (protein aggregation, mitochondria dysfunction, compromised axonal transport etc…), experimental evidence illustrate that ALS possibly does not arise strictly from damage within MNs. There is now convincing data supporting a non-cell autonomous mechanism in which neurodegeneration is influenced by the toxicity of non-neuronal cells in the vicinity of neurons such as astrocytes and microglia. Considering the accumulation of data implicating astrocytes in the pathogenesis of ALS (loss of GLT-1, secretion of toxic factor, enhanced inflammation, etc…), approaches aiming at replacing astrocytes at site of lesions constitute promising therapeutic strategies. Rapid progresses in the characterization of adult stem cell biology have generated considerable enthusiasm for the development of therapeutic strategies for CNS insults. Several observations support the hypothesis that stem cells may display a valuable influence on diseased host tissues by exerting a protective “chaperone” effect to neurons after differentiation in glial cells. Hence, we decided to study the neuroprotective potential of adult mesenchymal stem cells (MSCs) in ALS. In contrast to neural stem cells (NSCs) which localization in the central nervous system complicates their isolation, MSCs are easily isolated from the bone marrow. The relevance of using on MSCs in stem cell therapies of neurodegenerative disorders is also justified by their capacity to (trans)differentiate into neural cells. For this purpose, we exposed MSCs to growth factors involved in the astroglial differentiation of NSCs. The differentiation of MSCs was characterized by the acquisition of astrocyte morphology in addition to an increased expression of gene related to NSCs (nestin) and astrocytes (glutamine synthetase). The astroglial differentiation of MSCs is associated with the acquisition of a glial-like specific regulation of the production of GDNF, a potent neurotrophic factor for neurons. Then, we characterized the glutamate uptake in differentiated MSCs, a critical function of astrocytes. Our data demonstrate that the differentiation of MSCs is associated with an increased expression of the high affinity glutamate transporter, GLT-1. Thus, our in vitro results confirm the astrocytic differentiation potential of MSCs and we decided to use then in stem cell therapy of ALS. Indeed, we demonstrated that mechanism of stem cell recruitment is present in the spinal cord during the development of the disease by the secretion of stem cell factor (SCF). We injected MSCs derived from healthy animals into the cerebrospinal fluid of a transgenic rat model of familial ALS (expressing a mutated form of the human superoxide dismutase-1, hSOD1G93A) at disease onset. MSCs were found to infiltrate the nervous parenchyma and migrate substantially into the ventral grey matter by interacting with the SCF. At the site of lesion, MSCs differentiated massively into astrocytes around MNs. The intrathecal delivery of MSCs preserved motor functions and extended the survival of hSOD1G93A rats. Investigation of the lumbar spinal cord 35 days after graft demonstrated that the generation of healthy astrocytes from MSCs decreased motor neuron loss. However, this beneficial effect is not related to a decreased excitotoxicity by the rescue of GLT-1 expression but rather a decreased inflammation around MNs. Together, the data presented in this thesis highlight the protective capacity of adult MSC-derived astrocytes in the treatment of ALS.

Astrocytes

Motor neurons

Mesenchymal stem cells

Amyotrophic lateral sclerosis

Modeling the Intersegmental Coordination of Heart Motor Neurons in the Medicinal Leech

Garcia, Paul Anthony

12 July 2004

We constructed a model of the coordination of segmental heart motor neurons driving blood circulation in leeches. The heart motor neuron models were conductance-based; conductances of voltage-gated and synaptic currents were adjusted to match the firing pattern of heart motor neurons from the living system. Each motor neuron receives a specific pattern of inhibitory input from rhythmic premotor heart interneurons and translates this spatiotemporal pattern into the fictive heartbeat motor pattern. The temporal pattern of synaptic input to the model was derived from extracellularly recorded spikes of the premotor heart interneurons. We focused on determining the components necessary to produce side-to-side asymmetry in the motor pattern: motor neurons on one side fire nearly in synchrony (synchronous coordination), while on the other they fire in a rear-to-front progression (peristaltic coordination). The model reproduces the general trends in phasing and was used to investigate the effective contribution of several synaptic and cellular properties of the motor neurons. The spatial and temporal pattern of premotor synaptic input, the electrical coupling between the segmental motor neurons, intra-burst, short-term synaptic plasticity of the synaptic inputs, and the axonal conduction delays all were integrated with the intrinsic membrane properties to influence intersegmental phasing.

Intersegmental coordination

Leech

Central pattern generator

Neuroscience

Model

Motor neurons

Axonal regeneration of descending brain neurons in larval lamprey

Zhang, Lei,

January 1999

Thesis (Ph. D.)--University of Missouri-Columbia, 1999. / Typescript. Vita. Includes bibliographical references (leaves 138-148). Also available on the Internet.

Ia afferent input alters the recruitment thresholds and firing rates of single human motor units

Grande, Giovanbattista.

January 2001

Thesis (M. Sc.)--York University, 2001. Graduate Programme in Kinesiology and Health Science. / Typescript. Includes bibliographical references. Also available on the Internet. MODE OF ACCESS via web browser by entering the following URL: http://wwwlib.umi.com/cr/yorku/fullcit?pMQ71585.

Molecular correlates of spinal motor neuron functional specification and plasticity

Cherukuri, Pitchaiah

18 October 2012

No description available.

570

Biologie (PPN619462639)