Bardet-Biedl syndrome (BBS) is a pleiotropic, heterogeneous human disease whose etiology lies primarily in dysfunctional basal bodies and/or cilia. Both BBS patients and several BBS mouse models exhibit impaired olfactory function. To explore the nature of olfactory defects in BBS, a genetic ablation of the mouse Bbs8 gene that incorporates a fluorescent reporter protein was created. The endogenous BBS8 protein and reporter are particularly abundant in olfactory sensory neurons (OSNs), and specific BBS8 antibodies reveal staining in the dendritic knob in a shell-like structure that surrounds the basal bodies. Bbs8-null mice have reduced olfactory responses to a number of odorants, and immunohistochemical analyses reveal a near-complete loss of cilia from OSNs and mislocalization of proteins normally enriched in cilia. To visualize altered protein localization in OSNs, we generated a SLP3 eGFP knock-in mouse and imaged the apical epithelium, including dendritic knobs and proximal cilia, in ex vivo tissue preparations. Additionally, protein reagents that reflect the characteristic neuronal activity of each OSN revealed altered activity in Bbs8-null cells. In addition to previously known defects at the ciliary border, we also observed aberrant targeting of OSN axons to the olfactory bulb; axons expressing the same receptor display reduced fasciculation and project to multiple targets in the olfactory bulb. We suggest that loss of BBS8 leads to a dramatic and variable reduction in cilia, the essential signaling platform for olfaction, which alters the uniformity of responses in populations of OSNs expressing the same receptor, thereby contributing to the observed axon-targeting defects.ciliopathy | olfactory activity | protein trafficking B ardet-Biedl syndrome (BBS), a heterogeneous human disease, encompasses pleiotropic phenotypes including obesity, polydactyly, retinal degeneration, and renal anomalies. The disease, associated with mutations in at least 16 genes, shows complex inheritance. The BBS8 gene was identified via shared homology with BBS4 and was recognized to bear similarity to bacterial pilF; pilF is thought to be involved in the assembly of pili, which are thin, hairlike extensions on prokaryotic cells (1). This prompted the hypothesis that BBS is primarily a disease of the basal body, a microtubule-based modified centriole that nucleates the ciliary axoneme. Subsequent work supports this common etiology of BBS (2). Characterized BBS genes are highly conserved exclusively among ciliated eukaryotes, and most BBS proteins localize to the basal body, centrosome, and/or cilium in ciliated cell-culture models and in ciliated tissues. BBS proteins are not thought to be essential structural proteins as the basal body and cilium remain largely intact in most mutant BBS models (3-5). Disruption of individual BBS genes leads to defects in intraflagellar transport (IFT), a process essential for protein trafficking within the cilium (6-8).Recent studies have found that seven BBS proteins-BBS1, -2, -4, -5, -7, -8,...
