Popovici C et al. (2002) Neurosci Lett "Caenorhabditis elegans receptors related to mammalian vascular endothelial growth factor receptors are expressed in neural cells."

Isnardon D, Birnbaum D, Popovici C, Roubin R

[Neurosci Lett, 2002]

Through a genomic survey of the Caenorhabditis elegans genome for genes encoding tyrosine kinase receptors (RTK) we identified a family of four RTKs which are structurally related to vascular enclothelial growth factor receptors (VEGFRs). We named this family the ver gene family (for Vascular Endothelial growth factor receptor Related). It was intriguing to find this type of RTK in an animal devoid of a vascular system. The common sites of expression of the ver genes are specialized cells of neural origin: ver-1 (T17A3.1) is expressed in the support (glial) cells of amphid and phasmid neurons, ver-2 (T17A3.8) in ADL, a pair of chemosensorial neurons, and ver-3 (F59F3.1) in the ALA neuron. In mammals, the VEGFRs are associated with angiogenesis and neurogenesis. We provide here the first observation that these molecules may be primarily and solely involved in neurogenesis in a living organism.

Luth ES et al. (2021) PLoS Genet "VER/VEGF receptors regulate AMPA receptor surface levels and glutamatergic behavior."

Markoja K, Juo P, Rennich BJ, Riccio C, Hofer J, Luth ES, Hodul M

[PLoS Genet, 2021]

Several intracellular trafficking pathways contribute to the regulation of AMPA receptor (AMPAR) levels at synapses and the control of synaptic strength. While much has been learned about these intracellular trafficking pathways, a major challenge is to understand how extracellular factors, such as growth factors, neuropeptides and hormones, impinge on specific AMPAR trafficking pathways to alter synaptic function and behavior. Here, we identify the secreted ligand PVF-1 and its cognate VEGF receptor homologs, VER-1 and VER-4, as regulators of glutamate signaling in C. elegans. Loss of function mutations in ver-1, ver-4, or pvf-1, result in decreased cell surface levels of the AMPAR GLR-1 and defects in glutamatergic behavior. Rescue experiments indicate that PVF-1 is expressed and released from muscle, whereas the VERs function in GLR-1-expressing neurons to regulate surface levels of GLR-1 and glutamatergic behavior. Additionally, ver-4 is unable to rescue glutamatergic behavior in the absence of pvf-1, suggesting that VER function requires endogenous PVF-1. Inducible expression of a pvf-1 rescuing transgene suggests that PVF-1 can function in the mature nervous system to regulate GLR-1 signaling. Genetic double mutant analysis suggests that the VERs act together with the VPS-35/retromer recycling complex to promote cell surface levels of GLR-1. Our data support a genetic model whereby PVF-1/VER signaling acts with retromer to promote recycling and cell surface levels of GLR-1 to control behavior.

Procko C et al. (2011) Development "Glia delimit shape changes of sensory neuron receptive endings in C. elegans."

Shaham S, Lu Y, Procko C

[Development, 2011]

Neuronal receptive endings, such as dendritic spines and sensory protrusions, are structurally remodeled by experience. How receptive endings acquire their remodeled shapes is not well understood. In response to environmental stressors, the nematode Caenorhabditis elegans enters a diapause state, termed dauer, which is accompanied by remodeling of sensory neuron receptive endings. Here, we demonstrate that sensory receptive endings of the AWC neurons in dauers remodel in the confines of a compartment defined by the amphid sheath (AMsh) glial cell that envelops these endings. AMsh glia remodel concomitantly with and independently of AWC receptive endings to delimit AWC receptive ending growth. Remodeling of AMsh glia requires the OTD/OTX transcription factor TTX-1, the fusogen AFF-1 and probably the vascular endothelial growth factor (VEGFR)-related protein VER-1, all acting within the glial cell. ver-1 expression requires direct binding of TTX-1 to ver-1 regulatory sequences, and is induced in dauers and at high temperatures. Our results demonstrate that stimulus-induced changes in glial compartment size provide spatial constraints on neuronal receptive ending growth.

Procko C et al. (2012) Genetics "Sensory organ remodeling in Caenorhabditis elegans requires the zinc-finger protein ZTF-16."

Shaham S, Procko C, Lu Y

[Genetics, 2012]

Neurons and glia display remarkable morphological plasticity, and remodeling of glia may facilitate neuronal shape changes. The molecular basis and control of glial shape changes is not well understood. In response to environmental stress, the nematode Caenorhabditis elegans enters an alternative developmental state, called dauer, in which glia and neurons of the amphid sensory organ remodel. Here, we describe a genetic screen aimed at identifying genes required for amphid glia remodeling. We previously demonstrated that remodeling requires the Otx-type transcription factor TTX-1 and its direct target, the receptor tyrosine kinase gene ver-1. We now find that the hunchback/Ikaros-like C2H2 zinc-finger factor ztf-16 is also required. We show that ztf-16 mutants exhibit pronounced remodeling defects, which are explained, at least in part, by defects in the expression of ver-1. Expression and cell-specific rescue studies suggest that ztf-16, like ttx-1, functions within glia; however, promoter deletion studies show that ztf-16 acts through a site on the ver-1 promoter that is independent of ttx-1. Our studies identify an important component of glia remodeling and suggest that transcriptional changes may underlie glial morphological plasticity in the sensory organs of C. elegans.

Lee IH et al. (2021) Cell Rep "Stress-Induced Neural Plasticity Mediated by Glial GPCR REMO-1 Promotes C.elegans Adaptive Behavior."

Shaham S, Lee IH, Lu Y, Procko C

[Cell Rep, 2021]

Animal nervous systems remodel following stress. Although global stress-dependent changes are well documented, contributions of individual neuron remodeling events to animal behavior modification are challenging to study. In response to environmental insults, C.elegans become stress-resistant dauers. Dauer entry induces amphid sensory organ remodeling in which bilateral AMsh glial cells expand and fuse, allowing embedded AWC chemosensory neurons to extend sensory receptive endings. We show that amphid remodeling correlates with accelerated dauer exit upon exposure to favorable conditions and identify a G protein-coupled receptor, REMO-1, driving AMsh glia fusion, AWC neuron remodeling, and dauer exit. REMO-1 is expressed in and localizes to AMsh glia tips, is dispensable for other remodeling events, and promotes stress-induced expression of the remodeling receptor tyrosine kinase VER-1. Our results demonstrate how single-neuron structural changes affect animal behavior, identify key glial roles in stress-induced nervous system plasticity, and demonstrate that remodeling primes animals to respond to favorable conditions.