The subventricular zone (SVZ) is a brain region that shows intense germinal activity throughout postnatal life. The postnatal SVZ is subdivided in microdomains containing neural stem cells (NSCs) that express defined transcription factors and generate distinct neuronal subtypes in the olfactory bulb (OB). Calretinin-expressing (CalR+) interneurons represent the largest population of OB periglomerular interneurons produced after birth. Yet, in contrast to others, limited information exists regarding their origin, diversity and function in the OB, as well as the transcription factors that guide their generation. Previous studies highlighted that CalR+ PG interneurons are generated by both the medial and dorsal SVZ microdomains, and suggested that the transcription factor Sp8 is involved in their generation.This work aimed at 1) refining current approaches for manipulating gene expression in postnatal SVZ NSCs in a temporally controlled manner, 2) exploring the origin and the function of CalR+ periglomerular neurons, 3) investigating the role of Sp8 in the transcriptional coding of CalR+ periglomerular interneurons specification and maturation.Refinement of the classical electroporation approach allowed the long-term fate mapping and timely-controlled genetic manipulation of NSCs of the SVZ. Using this refined approach allowed identifying two subpopulations of CalR+ interneurons that show different spatial and temporal origins after birth, as well as to explore the functional and morphological correlates of this diversity. A large and previously non-described fraction of CalR+ periglomerular interneurons exhibits properties of immature neurons (i.e. little synaptic inputs and weak excitability), questioning their role in olfactory processing. Finally, genetic manipulations of the transcription factor Sp8 at different stages during CalR+ interneuron differentiation highlighted its role in the long-term survival of mature CalR+ periglomerular interneurons, while excluding a role in their early specification. Altogether these results shed new lights on the origin, diversity and transcriptional coding of CalR+ periglomerular i nterneurons and call for a characterization of their role in olfactory processing