Conditional gene knockout animals are valuable tools for studying the mechanisms underlying cell and developmental biology. We developed a conditional knockout strategy by spatiotemporally manipulating the expression of an RNA-guided DNA endonuclease, CRISPR-Cas9, in Caenorhabditis elegans somatic cell lineages. We showed that this somatic CRISPR-Cas9 technology provides a quick and efficient approach to generate conditional knockouts in various cell types at different developmental stages. Furthermore, we demonstrated that this method outperforms our recently developed somatic TALEN technique and enables the one-step generation of multiple conditional knockouts. By combining these techniques with live-cell imaging, we showed that an essential embryonic gene, Coronin, which is associated with human neurobehavioral dysfunction, regulates actin organization and cell morphology during C. elegans postembryonic neuroblast migration and neuritogenesis. We propose that the somatic CRISPR-Cas9 platform is uniquely suited for conditional gene editing-based biomedical research.
Kinesin-2 motors power anterograde intraflagellar transport (IFT), a highly ordered process that assembles and maintains cilia. However, it remains elusive how kinesin-2 motors are regulated in vivo. Here, we performed forward genetic screens to isolate suppressors that rescue the ciliary defects of OSM-3-kinesin (homolog of mammalian homodimeric kinesin-2 KIF17) mutants in Caenorhabditis elegans. We identified the C. elegans dyf-5 and dyf-18, which encode the homologs of mammalian male germ cell-associated kinase and cell cycle-related kinase, respectively. Using time-lapse fluorescence microscopy, we show that DYF-5 and DYF-18 are IFT cargo molecules and are enriched at the distal segments of sensory cilia. Mutations of dyf-5 and dyf-18 generate elongated cilia and ectopic localization of the heterotrimeric kinesin-2 (kinesin-II) at the ciliary distal segments. Genetic analyses reveal that dyf-5 and dyf-18 are important for stabilizing the interaction between IFT particles and OSM-3-kinesin. Our data suggest that DYF-5 and DYF-18 act in the same pathway to promote handover between kinesin-II and OSM-3 in sensory cilia.
CRISPR–Cas9-induced mutations in intraflagellar transport (IFT) motors reveal that IFT-specific dynein and cytoplasmic dynein have unique compositions but share components and regulatory mechanisms.
SUMMARYNeuroblasts generate neurons with different functions by asymmetric cell division, cell cycle exit and differentiation. The underlying transcriptional regulatory pathways remain elusive. Here, we performed genetic screens in C. elegans and identified three evolutionarily conserved transcription factors (TFs) essential for Q neuroblast lineage progression. Through live cell imaging and genetic analysis, we showed that the storkhead TF HAM-1 regulates spindle positioning and myosin polarization during asymmetric cell division and that the PAR-1-like kinase PIG-1 is a transcriptional regulatory target of HAM-1. The TEAD TF EGL-44, in a physical association with the zinc-finger TF EGL-46, instructs cell cycle exit after the terminal division. Finally, the Sox domain TF EGL-13 is necessary and sufficient to establish the correct neuronal fate. Genetic analysis further demonstrated that HAM-1, EGL-44/EGL-46 and EGL-13 form three transcriptional regulatory pathways. We have thus identified TFs that function at distinct developmental stages to ensure appropriate neuroblast lineage progression and suggest that their vertebrate homologs might similarly regulate neural development.
Directional cell migration is a fundamental process in neural development. In
Caenorhabditis elegans
, Q neuroblasts on the left (QL) and right (QR) sides of the animal generate cells that migrate in opposite directions along the anteroposterior body axis. The homeobox (Hox) gene
lin-39
promotes the anterior migration of QR descendants (QR.x), whereas the canonical Wnt signaling pathway activates another Hox gene,
mab-5
, to ensure the QL descendants’ (QL.x) posterior migration. However, the regulatory targets of LIN-39 and MAB-5 remain elusive. Here, we showed that MIG-13, an evolutionarily conserved transmembrane protein, cell-autonomously regulates the asymmetric distribution of the actin cytoskeleton in the leading migratory edge. We identified
mig-13
as a cellular target of LIN-39 and MAB-5. LIN-39 establishes QR.x anterior polarity by binding to the
mig-13
promoter and promoting
mig-13
expression, whereas MAB-5 inhibits QL.x anterior polarity by associating with the
lin-39
promoter and downregulating
lin-39
and
mig-13
expression. Thus, MIG-13 links the Wnt signaling and Hox genes that guide migrations, to the actin cytoskeleton, which executes the motility response in neuronal migration.
Cytoplasmic dynein-2 powers retrograde intraflagellar transport that is essential for cilium formation and maintenance. Inactivation of dynein-2 by mutations in DYNC2H1 causes skeletal dysplasias, and it remains unclear how the dynein-2 heavy chain moves in cilia. Here, using the genome-editing technique to produce fluorescent dynein-2 heavy chain in Caenorhabditis elegans, we show by high-resolution live microscopy that dynein-2 moves in a surprising way along distinct ciliary domains. Dynein-2 shows triphasic movement in the retrograde direction: dynein-2 accelerates in the ciliary distal region and then moves at maximum velocity and finally decelerates adjacent to the base, which may represent a physical obstacle due to transition zone barriers. By knocking the conserved ciliopathy-related mutations into the C. elegans dynein-2 heavy chain, we find that these mutations reduce its transport speed and frequency. Disruption of the dynein-2 tail domain, light intermediate chain, or intraflagellar transport (IFT)-B complex abolishes dynein-2's ciliary localization, revealing their important roles in ciliary entry of dynein-2. Furthermore, our affinity purification and genetic analyses show that IFT-A subunits IFT-139 and IFT-43 function redundantly to promote dynein-2 motility. These results reveal the molecular regulation of dynein-2 movement in sensory cilia.
Neuronal cilia that are formed at the dendritic endings of sensory neurons are essential for sensory perception. However, it remains unclear how the centriole-derived basal body is positioned to form a template for cilium formation. Using fluorescence time-lapse microscopy, we show that the centriole translocates from the cell body to the dendrite tip in the sensory neurons. The centriolar protein SAS-5 interacts with the dynein light-chain LC8 and conditional mutations of cytoplasmic dynein-1 block centriole translocation and ciliogenesis. The components of the central tube are essential for the biogenesis of centrioles, which later drive ciliogenesis in the dendrite; however, the centriole loses these components at the late stage of centriole translocation and subsequently recruits transition zone and intraflagellar transport proteins. Together, our results provide a comprehensive model of ciliogenesis in sensory neurons and reveal the importance of the dynein-dependent centriole translocation in this process.
Highlights d MTs are essential for nuclear migration but are less involved in bulge formation d Bulge formation alters microtubule patterning and guides nuclear migration d ROP GTPases and actin play an essential role in bulge initiation d ROP4 is localized to the apical membrane and the assembling cell plate
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