[
Prog Mol Biol Transl Sci,
2009]
The nematode worm, Caenorhabditis elegans, contains orthologs of most regulator of G protein signaling (RGS) protein subfamilies and all four G protein -subunit subfamilies found in mammals. Every C. elegans RGS and G gene has been knocked out, and the in vivo functions and G targets of a number of RGS proteins have been characterized in detail. This has revealed a complex relationship between the RGS and G proteins, in which multiple RGS proteins can regulate the same G protein, either by acting redundantly or by exerting control over signaling under different circumstances or in different cells. RGS proteins that are coexpressed can also show specificity for distinct G targets in vivo, and the determinants of such specificity can reside outside of the RGS domain. This review will discuss how analysis in C. elegans may aid us in achieving a full understanding of the physiological functions of RGS proteins.
[
Trends Pharmacol Sci,
2009]
RGS (regulator of G protein signaling) proteins have emerged as crucial regulators, effectors and integrators in G-protein-coupled receptor (GPCR) signaling networks. Many RGS proteins accelerate GTP hydrolysis by Galpha subunits, thereby regulating G protein activity, whereas certain RGS proteins also transduce Galpha signals to downstream targets. Particularly intriguing are members of the RGS7 (R7) family (RGS6, RGS7, RGS9 and RGS11), which heterodimerize with Gbeta5. In Caenorhabditis elegans, R7-Gbeta5 heterodimers regulate synaptic transmission, anesthetic action and behavior. In vertebrates, they regulate vision, postnatal development, working memory and the action of psychostimulants or morphine. Here we highlight R9AP and R7BP, a related pair of recently identified SNARE-like R7-family binding proteins, which regulate intracellular trafficking, expression and function of R7-Gbeta5 heterodimers in retina and brain. Emerging understanding of R7BP and R9AP promises to provide new insights into neuronal GPCR signaling mechanisms relevant to the causes and treatment of neurological disorders.
[
WormBook,
2006]
Heterotrimeric G proteins, composed of alpha , beta , and gamma subunits, are able to transduce signals from membrane receptors to a wide variety of intracellular effectors. In this role, G proteins effectively function as dimers since the signal is communicated either by the G alpha subunit or the stable G betagamma complex. When inactive, G alpha -GDP associates with G betagamma and the cytoplasmic portion of the receptor. Ligand activation of the receptor stimulates an exchange of GTP for GDP resulting in the active signaling molecules G alpha -GTP and free G betagamma , either of which can interact with effectors. Hydrolysis of GTP restores G alpha -GDP, which then reassociates with G betagamma and receptor to terminate signaling. The rate of G protein activation can be enhanced by the guanine-nucleotide exchange factor, RIC-8 , while the rate of GTP hydrolysis can be enhanced by RGS proteins such as EGL-10 and EAT-16 . Evidence for a receptor-independent G-protein-signaling pathway has been demonstrated in C. elegans early embryogenesis. In this pathway, the G alpha subunits GOA-1 and GPA-16 are apparently activated by the non-transmembrane proteins GPR-1 , GPR-2 , and RIC-8 , and negatively regulated by RGS-7 . The C. elegans genome encodes 21 G alpha , 2 G beta and 2 G gamma subunits. The alpha subunits include one ortholog of each mammalian G alpha family: GSA-1 (Gs), GOA-1 (Gi/o), EGL-30 (Gq) and GPA-12 (G12). The remaining C. elegans alpha subunits ( GPA-1 , GPA-2 , GPA-3 , GPA-4 , GPA-5 , GPA-6 , GPA-7 , GPA-8 , GPA-9 , GPA-10 , GPA-11 , GPA-13 , GPA-14 , GPA-15 , GPA-16 , GPA-17 and ODR-3 ) are most similar to the Gi/o family, but do not share sufficient homology to allow classification. The conserved G alpha subunits, with the exception of GPA-12 , are expressed broadly while 14 of the new G alpha genes are expressed in subsets of chemosensory neurons. Consistent with their expression patterns, the conserved C. elegans alpha subunits, GSA-1 , GOA-1 and EGL-30 are involved in diverse and fundamental aspects of development and behavior. GOA-1 acts redundantly with GPA-16 in positioning of the mitotic spindle in early embryos. EGL-30 and GSA-1 are required for viability starting from the first larval stage. In addition to their roles in development and behaviors such as egg laying and locomotion, the EGL-30 , GSA-1 and GOA-1 pathways interact in a network to regulate acetylcholine release by the ventral cord motor neurons. EGL-30 provides the core signals for vesicle release, GOA-1 negatively regulates the EGL-30 pathway, and GSA-1 modulates this pathway, perhaps by providing positional cues. Constitutively activated GPA-12 affects pharyngeal pumping. The G alpha subunits unique to C. elegans are primarily involved in chemosensation. The G beta subunit, GPB-1 , as well as the G gamma subunit, GPC-2 , appear to function along with the alpha subunits in the classic G protein heterotrimer. The remaining G beta subunit, GPB-2 , is thought to regulate the function of certain RGS proteins, while the remaining G gamma subunit, GPC-1 , has a restricted role in chemosensation. The functional difference for most G protein pathways in C. elegans, therefore, resides in the alpha subunit. Many cells in C. elegans express multiple G alpha subunits, and multiple G protein pathways are known to function in specific cell types. For example, Go, Gq and Gs-mediated signaling occurs in the ventral cord motor neurons. Similarly, certain amphid neurons use multiple G protein pathways to both positively and negatively regulate chemosensation. C. elegans thus provides a powerful model for the study of interactions between and regulation of G protein signaling.
[
Bioessays,
2000]
Mutations in the C. elegans maternal-effect gene
clk-1 are highly pleiotropic, affecting the duration of diverse developmental and behavioral processes. They result in an average slowing of embryonic and post-embryonic development, adult rhythmic behaviors, reproduction, and aging.(1) CLK-1 is a highly conserved mitochondrial protein,(2,3) but even severe
clk-1 mutations affect mitochondrial respiration only slightly.(3) Here, we review the evidence supporting the regulatory role of
clk-1 in physiological timing. We also discuss possible models for the action of CLK-1, in particular, one proposing that CLK-1 is involved in the coordination of mitochondrial and nuclear function. BioEssays 22:48-56, 2000.
[
Biochem Cell Biol,
2007]
Che-1/AATF (Che-1) was originally characterized as an interacting protein for RNA polymerase II. In addition to transcriptional regulation, the evidence suggests that Che-1 has a viral factor-like S phase promoting role in counteracting Rb repression to facilitate E2F-dependent transactivation during G1-S transition. Recently, Che-1 was found to play an important role in the DNA damage response and cell-cycle checkpoint control. Genetic studies in mice revealed that Che-1 is essential for preimplantation development and the establishment of embryonic gene expression. Importantly, several findings showed that Che-1 participates in inhibiting apoptotic process. Thus, Che-1 emerges as an important adaptor that connects transcriptional regulation, cell-cycle progression, checkpoint control, and apoptosis.
[
Front Neurosci,
2019]
The nematode <i>Caenorhabditis elegans</i> expresses the <i>
ten-1</i> gene that encodes teneurin. TEN-1 protein is expressed throughout the life of <i>C. elegans</i>. The loss of <i>
ten-1</i> function results in embryonic and larval lethality, highlighting its importance for fundamental processes during development. TEN-1 is expressed in the epidermis and neurons. Defects in neuronal pathfinding and epidermal closure are characteristic of <i>
ten-1</i> loss-of-function mutations. The molecular mechanisms of TEN-1 function in neurite outgrowth, neuronal pathfinding, and dendritic morphology in <i>C. elegans</i> are largely unknown. Its genetic redundancy with the extracellular matrix receptors integrin and dystroglycan and genetic interactions with several basement membrane components suggest a role for TEN-1 in the maintenance of basement membrane integrity, which is essential for neuronal guidance. Identification of the <i>
lat-1</i> gene in <i>C. elegans</i>, which encodes latrophilin, as an interaction partner of <i>
ten-1</i> provides further mechanistic insights into TEN-1 function in neuronal development. However, receptor-ligand interactions between LAT-1 and TEN-1 remain to be experimentally proven. The present review discusses the function of teneurin in <i>C. elegans</i>, with a focus on its involvement in the formation of receptor signaling complexes and neuronal networks.