Sunday, November 24, 2024
11/24/2024
PROJECT SUMMARY / ABSTRACT Hereditary Spastic Paraplegias (HSP) are heritable neurodegenerative diseases in which progressive degeneration of corticospinal axonal tracts results in limb weakness, spasticity and gait deficiencies. These symptoms result from a dying back pattern of degeneration of corticospinal axons, which also display prominent swellings of unclear pathological significance. The commonest form of HSP, termed SPG4-HSP, is caused by mutations in the SPAST gene, which codes for a microtubule-severing protein called spastin. To date, the prevailing mechanistic hypothesis for the etiology of SPG4-HSP is haploinsufficiency, meaning that the corticospinal tracts degenerate because of insufficient functional spastin. However, several major disease features are not readily explained by this etiology, and it is not clear how reduced microtubule severing would promote corticospinal axonal degeneration. Providing novel information that may fill a major gap in our knowledge of SPG4-HSP pathogenesis, recent work of the Principal Investigators revealed toxic properties of mutant spastin proteins, suggesting that a gain-of-function mechanism operates in SPG4-HSP. Curiously, both mechanisms negatively affect fast axonal transport (FAT), a cellular process fueled by molecular motor proteins that allows bidirectional movement of vesicular cargoes along axons. Based on a strong experimental premise, it is hypothesized in this multi-PI grant proposal that abnormalities in microtubule organization associated with reduced spastin levels cause FAT deficits and axonal swellings (loss-of-function). On the other hand, toxic effects of mutant spastin protein cause different FAT deficits that are mediated by casein kinase 2 (CK2), and these deficits promote corticospinal axon degeneration (gain-of-function). The former makes the axon more vulnerable, but it is the latter that suffices for corticospinal axon degeneration. The proposed work seeks to test these hypotheses by directly comparing a mouse model with a single SPAST allele (SPAST +/-) with a transgenic mouse model with both endogenous mouse SPAST alleles intact that additionally expresses human spastin bearing a pathogenic mutation associated with SPG4-HSP (spastin-C448Y mice). In Aim 1, these models will be individually crossed with mice that selectively express eGFP in corticospinal motor neurons (CSMN), so that loss-of and gain-of-function contributions to the disease can be investigated. In Aim 2, FAT deficits will be studied in neurons cultured from these animals, and specific hypotheses for the etiology of the deficits will be tested. In Aim 3, studies are proposed using transgenic spastin-C448Y mice in which autophagy is experimentally enhanced or CK2 levels are experimentally reduced, to test the hypothesis that these manipulations will prevent or reduce corticospinal axon degeneration and associated behavioral deficits. The overall significance of this project is to establish mechanisms underlying SPG4-HSP and forge a path toward effective therapies for patients.
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