The CATP-8/P5A-type ATPase functions in multiple pathways during neuronal patterning.

The assembly of neuronal circuits involves the migrations of neurons from their place of birth to their final location in the nervous system, as well as the coordinated growth and patterning of axons and dendrites. In screens for genes required for patterning of the nervous system, we identified the catp-8/P5A-ATPase as an important regulator of neural patterning. P5A-ATPases are part of the P-type ATPases, a family of proteins known to serve a conserved function as transporters of ions, lipids and polyamines in unicellular eukaryotes, plants, and humans. While the function of many P-type ATPases is relatively well understood, the function of P5A-ATPases in metazoans remained elusive. We show here, that the Caenorhabditis elegans ortholog catp-8/P5A-ATPase is required for defined aspects of nervous system development. Specifically, the catp-8/P5A-ATPase serves functions in shaping the elaborately sculpted dendritic trees of somatosensory PVD neurons. Moreover, catp-8/P5A-ATPase is required for axonal guidance and repulsion at the midline, as well as embryonic and postembryonic neuronal migrations. Interestingly, not all axons at the midline require catp-8/P5A-ATPase, although the axons run in the same fascicles and navigate the same space. Similarly, not all neuronal migrations require catp-8/P5A-ATPase. A CATP-8/P5A-ATPase reporter is localized to the ER in most, if not all, tissues and catp-8/P5A-ATPase can function both cell-autonomously and non-autonomously to regulate neuronal development. Genetic analyses establish that catp-8/P5A-ATPase can function in multiple pathways, including the Menorin pathway, previously shown to control dendritic patterning in PVD, and Wnt signaling, which functions to control neuronal migrations. Lastly, we show that catp-8/P5A-ATPase is required for localizing select transmembrane proteins necessary for dendrite morphogenesis. Collectively, our studies suggest that catp-8/P5A-ATPase serves diverse, yet specific, roles in different genetic pathways and may be involved in the regulation or localization of transmembrane and secreted proteins to specific subcellular compartments.

RABR-1, an atypical Rab-related GTPase, cell-nonautonomously restricts somatosensory dendrite branching.

Neurons are highly polarized cells with dendrites and axons. Dendrites, which receive sensory information or input from other neurons, often display elaborately branched morphologies. While mechanisms that promote dendrite branching have been widely studied, less is known about the mechanisms that restrict branching. Using the nematode Caenorhabditis elegans, we identify rabr-1 (for Rab-related gene 1) as a factor that restricts branching of the elaborately branched dendritic trees of PVD and FLP somatosensory neurons. Animals mutant for rabr-1 show excessively branched dendrites throughout development and into adulthood in areas where the dendrites overlay epidermal tissues. Phylogenetic analyses show that RABR-1 displays similarity to small GTPases of the Rab-type, although based on sequence alone, no clear vertebrate ortholog of RABR-1 can be identified. We find that rabr-1 is expressed and can function in epidermal tissues, suggesting that rabr-1 restricts dendritic branching cell-nonautonomously. Genetic experiments further indicate that for the formation of ectopic branches rabr-1 mutants require the genes of the Menorin pathway, which have been previously shown to mediate dendrite morphogenesis of somatosensory neurons. A translational reporter for RABR-1 reveals a subcellular localization to punctate, perinuclear structures, which correlates with endosomal and autophagosomal markers, but anticorrelates with lysosomal markers suggesting an amphisomal character. Point mutations in rabr-1 analogous to key residues of small GTPases suggest that rabr-1 functions in a GTP-bound form independently of GTPase activity. Taken together, rabr-1 encodes for an atypical small GTPase of the Rab-type that cell-nonautonomously restricts dendritic branching of somatosensory neurons, likely independently of GTPase activity.

Axon-Dependent Patterning and Maintenance of Somatosensory Dendritic Arbors.

The mechanisms that pattern and maintain dendritic arbors are key to understanding the principles that govern nervous system assembly. The activity of presynaptic axons has long been known to shape dendrites, but activity-independent functions of axons in this process have remained elusive. Here, we show that in Caenorhabditis elegans, the axons of the ALA neuron control guidance and extension of the 1° dendrites of PVD somatosensory neurons independently of ALA activity. PVD 1° dendrites mimic ALA axon guidance defects in loss-of-function mutants for the extracellular matrix molecule MIG-6/Papilin or the UNC-6/Netrin pathway, suggesting that axon-dendrite adhesion is important for dendrite formation. We found that the SAX-7/L1CAM cell adhesion molecule engages in distinct molecular mechanisms to mediate extensions of PVD 1° dendrites and maintain the ALA-PVD axon-dendritic fascicle, respectively. Thus, axons can serve as critical scaffolds to pattern and maintain dendrites through contact-dependent but activity-independent mechanisms.