The compensatory processes that accompany a lesion of the nigrostriatal dopaminergic (DA-ergic) system serve to maintain its function and illustrate adult brain neuroplasticity. The typical motor symptoms of Parkinson’s diseases (PD), characterized by progressive degeneration of DA-ergic neurons of substantia nigra (SN), appear only after substantial neuronal loss. Therefore presymptomatic diagnosis is a crucial issue for future neuroprotective therapies. Another good manifestation of neuroplasticity is adult neurogenesis, known to persist in two areas: the subventricular zone (SVZ) – the olfactory bulb (OB) continuum, and the dentate gyrus (DG) of the hippocampus, and to be altered in PD. In recent years, the surgical treatment by high frequency stimulation (HFS) of the subthalamic nucleus (STN) has proven to be an efficient therapeutic option for PD patients. In this context, my PhD work was focused on neuroplasticity under the functional deficiency of the nigrostriatal DA-ergic system (parkinsonism) and its treatment with the following main objectives: 1 - Develop a model of presymptomatic parkinsonism; 2 - study compensatory mechanisms in nigrostriatal system; 3 - Characterize the effects of subchronic STN HFS on adult neurogenesis. In the first part, we have developed models of presymptomatic parkinsonism based on MPTP administration in mice, as defined by sub-threshold DA depletion and degeneration of DA-ergic axons in the striatum followed by a loss of DA-ergic cell bodies in the SN (advanced presymptomatic stage). In the early symptomatic stage, these parameters reach a threshold that is associated with the appearance of motor deficiency. We have shown that the transition from the advanced presymptomatic stage to the early symptomatic stage is characterized by: (a) a decrease of DA content in surviving DA-ergic axons in the striatum; (b) an increase of DA content and TH-expression in surviving neuronal cell bodies in the SN; (c) an increase of DA turnover in the striatum and much less increase in the SN. The last part of my work is based on extensive DA lesion in rats, using intranigral 6-hydroxydopamine injection mimicking late PD stages, to determine a possible effect of STN-HFS on adult neurogenesis. We have completed series of animals with DA lesion either sham implanted or subsequently treated for 8 days by STN-HFS to be compared with unlesioned rats, and studied selective phases of neurogenesis: proliferation and survival. This study demonstrates selective regulation of cell proliferation and survival following DA depletion and provides the first evidence that prolonged STN-HFS might have a neuroprotective action as shown by the selective increase in survival of newly formed cells following this treatment.