David B. Doroquez scite author profile

Many primary sensory cilia exhibit unique architectures that are critical for transduction of specific sensory stimuli. Although basic ciliogenic mechanisms are well described, how complex ciliary structures are generated remains unclear. Seminal work performed several decades ago provided an initial but incomplete description of diverse sensory cilia morphologies in C. elegans. To begin to explore the mechanisms that generate these remarkably complex structures, we have taken advantage of advances in electron microscopy and tomography, and reconstructed three-dimensional structures of fifty of sixty sensory cilia in the C. elegans adult hermaphrodite at high resolution. We characterize novel axonemal microtubule organization patterns, clarify structural features at the ciliary base, describe new aspects of cilia–glia interactions, and identify structures suggesting novel mechanisms of ciliary protein trafficking. This complete ultrastructural description of diverse cilia in C. elegans provides the foundation for investigations into underlying ciliogenic pathways, as well as contributions of defined ciliary structures to specific neuronal functions.DOI: http://dx.doi.org/10.7554/eLife.01948.001

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Endocytosis Genes Facilitate Protein and Membrane Transport in C. elegans Sensory Cilia

Kaplan

et al. 2012

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SUMMARY Background Multiple intracellular transport pathways drive the formation, maintenance and function of cilia, a compartmentalised organelle associated with motility, chemo-/mechano-/photo-sensation, and developmental signaling. These pathways include cilium-based intraflagellar transport (IFT) and poorly understood membrane trafficking events. Defects in ciliary transport contribute to the aetiology of human ciliary disease such as Bardet-Biedl syndrome (BBS). In this study, we employ the genetically tractable nematode Caenorhabditis elegans to investigate if endocytosis genes function in cilium formation and/or the transport of ciliary membrane or ciliary proteins. Results Here we show that localisation of the clathrin light chain, AP-2 clathrin adaptor, dynamin and RAB-5 endocytic proteins overlaps with a morphologically discrete periciliary membrane compartment associated with sensory cilia. In addition, ciliary transmembrane proteins such as G protein-coupled receptors concentrate at periciliary membranes. Disruption of endocytic gene function causes expansion of ciliary and/or periciliary membranes as well as defects in the ciliary targeting and/or transport dynamics of ciliary transmembrane and IFT proteins. Finally, genetic analyses reveal that the ciliary membrane expansions in dynamin and AP-2 mutants require bbs-8 and rab-8 function, and that sensory signaling and endocytic genes may function in a common pathway to regulate ciliary membrane volume. Conclusions These data implicate C. elegans endocytosis proteins localized at the ciliary base in regulating ciliary and periciliary membrane volume, and suggest that membrane retrieval from these compartments is counter-balanced by BBS-8 and RAB-8-mediated membrane delivery.

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Signal Integration During Development: Mechanisms of EGFR and Notch Pathway Function and Cross-Talk

Doroquez

Rebay

2006

Critical Reviews in Biochemistry and Molecular Biology

123

102

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Metazoan development relies on a highly regulated network of interactions between conserved signal transduction pathways to coordinate all aspects of cell fate specification, differentiation, and growth. In this review, we discuss the intricate interplay between the epidermal growth factor receptor (EGFR; Drosophila EGFR/DER) and the Notch signaling pathways as a paradigm for signal integration during development. First, we describe the current state of understanding of the molecular architecture of the EGFR and Notch signaling pathways that has resulted from synergistic studies in vertebrate, invertebrate, and cultured cell model systems. Then, focusing specifically on the Drosophila eye, we discuss how cooperative, sequential, and antagonistic relationships between these pathways mediate the spatially and temporally regulated processes that generate this sensory organ. The common themes underlying the coordination of the EGFR and Notch pathways appear to be broadly conserved and should, therefore, be directly applicable to elucidating mechanisms of information integration and signaling specificity in vertebrate systems.

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Splits ends is a tissue/promoter specific regulator of Wingless signaling

Lin

Doroquez

Cho

et al. 2003

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Wingless directs many developmental processes inDrosophila by regulating expression of specific target genes through a conserved signaling pathway. Although many nuclear factors have been implicated in mediating Wingless-induced transcription, the mechanism of how Wingless regulates different targets in different tissues remains poorly understood. We report here that the split ends gene is required for Wingless signaling in the eye, wing and leg imaginal discs. Expression of a dominant-negative version of split ends resulted in more dramatic reductions in Wingless signaling than split ends-null alleles, suggesting that it may have a redundant partner. However, removal of split ends or expression of the dominant-negative had no effect on several Wingless signaling readouts in the embryo. The expression pattern of Split ends cannot explain this tissue-specific requirement, as the protein is predominantly nuclear and present throughout embryogenesis and larval tissues. Consistent with its nuclear location, the split ends dominant-negative acts downstream of Armadillo stabilization. Our data indicate that Split ends is an important positive regulator of Wingless signaling in larval tissues. However, it has no detectable role in the embryonic Wingless pathway, suggesting that it is a tissue or promoter-specific factor.

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David B. Doroquez

A high-resolution morphological and ultrastructural map of anterior sensory cilia and glia in Caenorhabditis elegans

Endocytosis Genes Facilitate Protein and Membrane Transport in C. elegans Sensory Cilia

Signal Integration During Development: Mechanisms of EGFR and Notch Pathway Function and Cross-Talk

Splits ends is a tissue/promoter specific regulator of Wingless signaling

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