Loss of Ciliary Gene Bbs8 Results in Physiological Defects in the Retinal Pigment Epithelium

Primary cilia are sensory organelles vital for developmental and physiological processes. Their dysfunction causes a range of phenotypes including retinopathies. Although primary cilia have been described in the retinal pigment epithelium (RPE), little is known about their contribution to biological processes within this tissue. Ciliary proteins are increasingly being identified in non-ciliary locations and might carry out additional functions, disruption of which possibly contributes to pathology. The RPE is essential for maintaining photoreceptor cells and visual function. We demonstrate that upon loss of Bbs8, predominantly thought to be a ciliary gene, the RPE shows changes in gene and protein expression initially involved in signaling pathways and developmental processes, and at a later time point RPE homeostasis and function. Differentially regulated molecules affecting the cytoskeleton and cellular adhesion, led to defective cellular polarization and morphology associated with a possible epithelial-to-mesenchymal transition (EMT)-like phenotype. Our data highlights the benefit of combinatorial “omics” approaches with in vivo data for investigating the function of ciliopathy proteins. It also emphasizes the importance of ciliary proteins in the RPE and their contribution to visual disorders, which must be considered when designing treatment strategies for retinal degeneration

Loss of Bardet–Biedl syndrome protein-8 (BBS8) perturbs olfactory function, protein localization, and axon targeting

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 SLP3eGFP 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

Inhibition of neural crest migration underlies craniofacial dysmorphology and Hirschsprung's disease in Bardet–Biedl syndrome

Facial recognition is central to the diagnosis of many syndromes, and craniofacial patterns may reflect common etiologies. In the pleiotropic Bardet–Biedl syndrome (BBS), a primary ciliopathy with intraflagellar transport dysfunction, patients have a characteristic facial “gestalt” that dysmorphologists have found difficult to characterize. Here, we use dense surface modeling (DSM) to reveal that BBS patients and mouse mutants have mid-facial defects involving homologous neural crest-derived structures shared by zebrafish morphants. These defects of the craniofacial (CF) skeleton arise from aberrant cranial neural crest cell (NCC) migration. These effects are not confined to the craniofacial region, but vagal-derived NCCs fail to populate the enteric nervous system, culminating in disordered gut motility. Furthermore, morphants display hallmarks of disrupted Sonic Hedgehog (Shh) signaling from which NCCs take positional cues. We propose a model whereby Bbs proteins modulate NCC migration, contributing to craniofacial morphogenesis and development of the enteric nervous system. These migration defects also explain the association of Hirschsprung's disease (HD) with BBS. Moreover, this is a previously undescribed method of using characterization of facial dysmorphology as a basis for investigating the pathomechanism of CF development in dysmorphic syndromes

Primary cilium migration depends on G-protein signalling control of subapical cytoskeleton.

International audienceIn ciliated mammalian cells, the precise migration of the primary cilium at the apical surface of the cells, also referred to as translational polarity, defines planar cell polarity (PCP) in very early stages. Recent research has revealed a co-dependence between planar polarization of some cell types and cilium positioning at the surface of cells. This important role of the primary cilium in mammalian cells is in contrast with its absence from Drosophila melanogaster PCP establishment. Here, we show that deletion of GTP-binding protein alpha-i subunit 3 (Gαi3) and mammalian Partner of inscuteable (mPins) disrupts the migration of the kinocilium at the surface of cochlear hair cells and affects hair bundle orientation and shape. Inhibition of G-protein function in vitro leads to kinocilium migration defects, PCP phenotype and abnormal hair bundle morphology. We show that Gαi3/mPins are expressed in an apical and distal asymmetrical domain, which is opposite and complementary to an aPKC/Par-3/Par-6b expression domain, and non-overlapping with the core PCP protein Vangl2. Thus G-protein-dependent signalling controls the migration of the cilium cell autonomously, whereas core PCP signalling controls long-range tissue PCP

Loss of FTO Antagonises Wnt Signaling and Leads to Developmental Defects Associated with Ciliopathies

© 2014 Osborn et al. Common intronic variants in the Human fat mass and obesity-associated gene (FTO) are found to be associated with an increased risk of obesity. Overexpression of FTO correlates with increased food intake and obesity, whilst loss-of-function results in lethality and severe developmental defects. Despite intense scientific discussions around the role of FTO in energy metabolism, the function of FTO during development remains undefined. Here, we show that loss of Fto leads to developmental defects such as growth retardation, craniofacial dysmorphism and aberrant neural crest cells migration in Zebrafish. We find that the important developmental pathway, Wnt, is compromised in the absence of FTO, both in vivo (zebrafish) and in vitro (Fto−/− MEFs and HEK293T). Canonical Wnt signalling is down regulated by abrogated β-Catenin translocation to the nucleus whilst non-canonical Wnt/Ca2+ pathway is activated via its key signal mediators CaMKII and PKCδ. Moreover, we demonstrate that loss of Fto results in short, absent or disorganised cilia leading to situs inversus, renal cystogenesis, neural crest cell defects and microcephaly in Zebrafish. Congruently, Fto knockout mice display aberrant tissue specific cilia. These data identify FTO as a protein-regulator of the balanced activation between canonical and non-canonical branches of the Wnt pathway. Furthermore, we present the first evidence that FTO plays a role in development and cilia formation/function