Pathological aggregation of a-synuclein (aS) is implicated in the pathogenesis of Parkinson's disease (PD) and other a-synucleinopathies. The current view is that neuron-to-neuron spreading of aS pathology contributes to the progression of a-synucleinopathy. We used an A53T mutant human aS transgenic mouse model () to examine whether the site of pathogenic aS inoculation affects the pattern of neuropathology and whether soluble and insoluble fractions derived from crude pathogenic tissue lysates exhibit differential capacities to initiate aS pathology. To test whether the inoculation site impacts the ultimate spatial/temporal patterns of aS pathology, aS preformed fibrils (PFF), or brain homogenates from mice with a-synucleinopathy, were injected into the cortex/striatum, brain stem, or skeletal muscle. In all cases, inoculation of pathogenic aS induced end-stage motor dysfunction within ~100 days post-inoculation (dpi). Significantly, irrespective of the inoculation sites, ultimate distribution of the aS pathology was like that seen in normally aged mice at end-stage, indicating that the intrinsic neuronal vulnerability is a significant determinant in the induction of aS pathology, even when initiated by inoculation of pathogenic aS. Temporal analysis of brain stem injected mice show that initial aS pathology was seen by 30 days post-inoculation and inflammatory changes occur at later stages. To determine if the aS species with differential solubility are differentially pathogenic, brain lysates from end-stage were fractionated into highly soluble (S150) and insoluble (P150) fractions, as well as the endoplasmic reticulum (ER)-enriched fraction (P100). Significantly, all fractions were able to seed aS pathology , when injected unilaterally into with the ER fractions being most pathogenic. Our results suggest that multiple aS species from brain can initiate the development of progressive aS pathology.