Investigating the role of eEF1A2 in motor neuron degeneration

Griffiths, Lowri Ann

January 2011

Abnormal expression of the eukaryotic translation elongation factor 1A (eEF1A) has been implicated in disease states such as motor neuron degeneration and cancer. Two variants of eEF1A are found in mammals, named eEF1A1 and eEF1A2. These two variants are encoded by different genes, produce proteins which are 92% identical but have very different patterns of expression. eEF1A1 is almost ubiquitously expressed while eEF1A2 is expressed only in specialised cell types such as motor neurons and muscle. A spontaneous mutation in eEF1A2 results in the wasted mouse phenotype which shows similar characteristics in the mouse to those seen in human motor neuron degeneration. This mutation has been shown to be a 15.8kb deletion resulting in the complete loss of the promoter region and first non coding exon of eEF1A2 which completely abolishes protein expression. The main aim of this project was to further investigate the role of eEF1A2 in motor neuron degeneration. Firstly, although the wasted phenotype is considered to be caused by a recessive mutation, I established a cohort of aged heterozygote mice to evaluate whether any changes are seen later in life that might model late onset motor neuron degeneration. A combination of behavioural tests and pathology was used to compare wild type and heterozygous mice up to 21 months of age. Whilst results indicate that there is no significant difference between ageing heterozygotes and wildtype controls, there is an indication that female heterozygote mice perform slightly worse that wildtype controls on the rotarod (a behavioural test for motor function). Secondly, I aimed to investigate the primary cause of the wasted pathology by generating transgenic wasted mice expressing neuronal eEF1A2 only. This would complement previous experiments in the lab which studied transgenic wasted mice expressing eEF1A2 in muscle only. Unfortunately the expression of eEF1A2 in the transgenic animals was not neuronal specific. However a transgenic line with expression of eEF1A2 in neurons and skeletal muscle but not cardiac muscle has been generated which clearly warrants further investigation. Thirdly, I wished to assess whether eEF1A2 has any role in human motor neuron degeneration. To achieve this, eEF1A2 expression was investigated in spinal cords from human motor neuron disease (MND) patients. Preliminary data suggests that motor neurons from some MND patients express significantly less eEF1A2 than motor neurons of control samples. Further work is required to confirm these findings. Finally, I investigated the individual roles of eEF1A1 and eEF1A2 in the heat shock response. I used RNAi to ablate each variant separately in cells and subsequently measured the ability of each variant individually to mount a heat shock response. Results indicate a clear role for eEF1A1 but not eEF1A2 in the induction of heat shock. This may explain in part why motor neurons exhibit a poor heat shock response as they express eEF1A2 and not eEF1A1. These experiments shed light on our understanding of the role of eEF1A2 in motor neuron degeneration and uncover many new avenues of future investigation.

616.8

Etude des bases moléculaires de l'atrophie musculaire spinale / Study of the molecular basis of the spinal muscular atrophy SMA

Boulisfane, Nawal

15 November 2011

L'Atrophie Musculaire spinale (SMA) est une maladie neurodégénérative causée par des mutations du gène SMN1 et caractérisée par la dégénérescence sélective des motoneurones alpha de la moelle épinière. les mécanismes moléculaires de la SMA ne sont aps clairs. cependant, deux hypothèses ont été retenues:D'une part, que la déficience en SMN entraine une perturbation de la biogenèse des snRNPs spliceosomales individuelles et par conséquent des défauts d'épissage. pendant ma thèse, nous avons montré que la déficience en SMN provoquait une diminution des particules tri-snRNPs majeures amis surtout mineures et que cela avait des conséquences sur l'épissage d'un sous-groupe de pré-ARNm contenant des introns mineurs.D'autre part, que la déficience en SMN entraine des altérations de transport d'ARN dans les axones, essentiels pour la survie des motoneurones. A part l'ARNm de la beta-actine et l'ARNm de cpg15 récemment identifié, ceux qui pourraient être transportés par SMN n'ont pas été décrits. nous avons donc identifié les ARN interagissant avec les isoformes a-SMN et SMN-fl dans des cellules neuronales, et montré que certains de ces ARN cibles colocalisent avec SMN dans les axones, suggérant qu'elle est impliquée dans leur transport. / Spinal Muscular Atrophy is a neurodegenerative disease caused by mutations in SMN1 gene. SMA is characterized by the loss of alpha-motoneurons of the spinal cord. However, the precise molecular mechanisms underlying the disease are still unkown. two hypotheses have been retained to explain SMA pathigenesis:In one hand, the fact that SMN deficiency leads to a perturbation of individual snRNPs biogenesis and consequently splicing defects. During my PhD, we have shown that SMN deficiency alters the levels of major, but mostly, minor tri-snRNPs. And that leads to splicing defects of a subset of pre-mRNA containing minor introns.In the other hand, that SMN deficiency causes alteration of axonal transport of RNAs crucial to motoneurons survival. Except beta-actin mRNA and the recently identified cpg mRNA, the RNA targets of SMN have not been described. We succeed to identify RNA targets of both a-SMN and SMN-fl isoformes in a neuronal cell line and colocalisation data of some of these targets suggested that SMN could be implicated in the transport of these RNAs.

Sma

Smn

Transport axonal

Dégénerescence des motoneurones

Sma

Smn

Axonal transport

Motor neuron degeneration

Souffle/Spastizin regulates secretory granule maturation by sorting lysosomal cargo from immature secretory granule during zebrafish oogenesis

Palsamy, Kanagaraj

18 November 2014

No description available.

570

Kanagaraj

Zebrafish

Souffle/spastizin/spg15/fyve-cent

HSP-hereditary spastic paraplegia

Oogenesis

Yolk endocytosis and degradation

Vesicle fission and fusion

Lysosome and autophagy

Maternal protein

Vesicle trafficking and transport

Motor neuron degeneration

Germplasm/balbiani body

Biologie (PPN619462639)