Cerebrospinal Fluid from Sporadic Amyotrophic Lateral Sclerosis Patients Induces Mitochondrial and Lysosomal Dysfunction.

In our laboratory, we have developed (1) an in vitro model of sporadic Amyotrophic Lateral Sclerosis (sALS) involving exposure of motor neurons to cerebrospinal fluid (CSF) from sALS patients and (2) an in vivo model involving intrathecal injection of sALS-CSF into rat pups. In the current study, we observed that spinal cord extract from the in vivo sALS model displayed elevated reactive oxygen species (ROS) and mitochondrial dysfunction. Quantitative proteomic analysis of sub-cellular fractions from spinal cord of the in vivo sALS model revealed down-regulation of 35 mitochondrial proteins and 4 lysosomal proteins. Many of the down-regulated mitochondrial proteins contribute to alterations in respiratory chain complexes and organellar morphology. Down-regulated lysosomal proteins Hexosaminidase, Sialidase and Aryl sulfatase also displayed lowered enzyme activity, thus validating the mass spectrometry data. Proteomic analysis and validation by western blot indicated that sALS-CSF induced the over-expression of the pro-apoptotic mitochondrial protein BNIP3L. In the in vitro model, sALS-CSF induced neurotoxicity and elevated ROS, while it lowered the mitochondrial membrane potential in rat spinal cord mitochondria in the in vivo model. Ultra structural alterations were evident in mitochondria of cultured motor neurons exposed to ALS-CSF. These observations indicate the first line evidence that sALS-CSF mediated mitochondrial and lysosomal defects collectively contribute to the pathogenesis underlying sALS.

Evidence of endoplasmic reticular stress in the spinal motor neurons exposed to CSF from sporadic amyotrophic lateral sclerosis patients.

We have earlier reported that intrathecal injection of cerebrospinal fluid (CSF) from sporadic Amyotrophic Lateral Sclerosis patients (ALS-CSF) into neonatal rats and supplementation of rat spinal cord cultures with ALS-CSF induces motor neuron degeneration via aberrant neurofilament phosphorylation and Golgi apparatus fragmentation. Intracellular aggregates immunoreactive to ubiquitin, phosphorylated neurofilaments and choline acetyl transferase (ChAT) were prominently seen in NSC-34 cells exposed to ALS-CSF. Protein aggregation could cause stress on endoplasmic reticulum (ER) and may precede Golgi fragmentation. Here we assessed the effect of ALS-CSF on the expression of GRP-78 and caspase-12 proteins, the markers of ER stress responses, in NSC-34 cells and rat spinal cords by immunochemistry and immunoblotting. Both in vitro and in vivo, increased expression of these proteins accompanied elevated active caspase-12 levels. Apoptotic nuclei and nuclear translocation of caspase-12 were noted in some cells. In vitro, the occurrence of ER stress was supported by electron microscopic observations of numerous free polyribosomes and fragmented ER cisternae. Aggregated mSOD1 protein causes ER stress in familial ALS. ER stress is also reported in the autopsy samples of sporadic ALS. Thus our observation of ER stress may be linked to the protein aggregation, viz. phosphorylated neurofilaments and ChAT, reported earlier.