The G-protein gamma subunit gpc-1 of the nematode C.elegans is involved in taste adaptation

Caenorhabditis elegans has two heterotrimeric G-protein gamma subunits, gpc-1 and gpc-2. Although GPC-1 is specifically expressed in sensory neurons, it is not essential for the detection of odorants or salts. To test whether GPC-1 is involved in sensory plasticity, we developed a water soluble compound adaptation assay. The behaviour of wild-type animals in this assay confirms that prolonged exposure to salts can abolish chemo-attraction to these compounds. This process is time and concentration dependent, partly salt specific and reversible. In contrast, gpc-1 mutant animals show clear deficits in their ability to adapt to NaAc, NaCl and NH4Cl, but normal wild-type adaptation to odorants. Two other loci previously implicated in odorant adaptation, adp-1 and osm-9, are also involved in adaptation to salts. Our finding that G proteins, OSM-9 and ADP-1 are involved in taste adaptation offer the first molecular insight into this process.     

Modulation of EGF receptor-mediated vulva development by the heterotrimeric G-protein Galphaq and excitable cells in C. elegans

The extent to which excitable cells and behavior modulate animal development has not been examined in detail. Here, we demonstrate the existence of a novel pathway for promoting vulval fates in C. elegans that involves activation of the heterotrimeric Galphaq protein, EGL-30. EGL-30 acts with muscle-expressed EGL-19 L-type voltage-gated calcium channels to promote vulva development, and acts downstream or parallel to LET-60 (RAS). This pathway is not essential for vulval induction on standard Petri plates, but can be stimulated by expression of activated EGL-30 in neurons, or by an EGL-30-dependent change in behavior that occurs in a liquid environment. Our results indicate that excitable cells and animal behavior can provide modulatory inputs into the effects of growth factor signaling on cell fates, and suggest that communication between these cell populations is important for normal development to occur under certain environmental conditions.     

Structure of the parathyroid hormone receptor C terminus bound to the G-protein dimer Gbeta1gamma2

A critical role of the Gbetagamma dimer in heterotrimeric G-protein signaling is to facilitate the engagement and activation of the Galpha subunit by cell-surface G-protein-coupled receptors. However, high-resolution structural information of the connectivity between receptor and the Gbetagamma dimer has not previously been available. Here, we describe the structural determinants of Gbeta1gamma2 in complex with a C-terminal region of the parathyroid hormone receptor-1 (PTH1R) as obtained by X-ray crystallography. The structure reveals that several critical residues within PTH1R contact only Gbeta residues located within the outer edge of WD1- and WD7-repeat segments of the Gbeta toroid structure. These regions encompass a predicted membrane-facing region of Gbeta thought to be oriented in a fashion that is accessible to the membrane-spanning receptor. Mutation of key receptor contact residues on Gbeta1 leads to a selective loss of function in receptor/heterotrimer coupling while preserving Gbeta1gamma2 activation of the effector phospholipase-C beta.     

Cellular interactions in early C. elegans embryos

In normal development both the anterior and posterior blastomeres in a 2-cell C. elegans embryo produce some descendants that become muscles. We show that cellular interactions appear to be necessary in order for the anterior blastomere to produce these muscles. The anterior blastomere does not produce any muscle descendants after either the posterior blastomere or one of the daughters of the posterior blastomere is removed from the egg. Moreover, we demonstrate that a daughter of the anterior blastomere that normally does not produce muscles appears capable of generating muscles when interchanged with its sister, a cell that normally does produce muscles. Embryos develop normally after these blastomeres are interchanged, suggesting that cellular interactions play a major role in determining the fates of some cells in early embryogenesis.     

Cytoplasmic flow and the establishment of polarity in C. elegans 1-cell embryos

Early Caenorhabditis elegans embryos provide an excellent model for the study of developmental processes. Development can be studied by direct observation under the light microscope and can be perturbed using laser manipulations, drug inhibitor treatments, and genetic mutants. The first division of the C. elegans embryo is asymmetric, generating two daughter cells unequal in size and developmental fate. These distinct fates are generated by the partitioning of cytoplasmic determinants during the first mitotic cell cycle. Partitioning of these determinants is thought to be driven by cytoplasmic flow. Recent studies in C. elegans in the past year have identified a number of components necessary for this flow, giving us a clearer picture of the molecular mechanisms underlying developmental asymmetry.     

RIC-8 is required for GPR-1/2-dependent Galpha function during asymmetric division of C. elegans embryos

Heterotrimeric G proteins are crucial for asymmetric cell division, but the mechanisms of signal activation remain poorly understood. Here, we establish that the evolutionarily conserved protein RIC-8 is required for proper asymmetric division of one-cell stage C. elegans embryos. Spindle severing experiments demonstrate that RIC-8 is required for generation of substantial pulling forces on astral microtubules. RIC-8 physically interacts with GOA-1 and GPA-16, two Galpha subunits that act in a partially redundant manner in one-cell stage embryos. RIC-8 preferentially binds to GDP bound GOA-1 and is a guanine nucleotide exchange factor (GEF) for GOA-1. Our analysis suggests that RIC-8 acts before the GoLoco protein GPR-1/2 in the sequence of events leading to Galpha activation. Furthermore, coimmunoprecipitation and in vivo epistasis demonstrate that inactivation of the Gbeta subunit GPB-1 alleviates the need for RIC-8 in one-cell stage embryos. Our findings suggest a mechanism in which RIC-8 favors generation of Galpha free from Gbetagamma and enables GPR-1/2 to mediate asymmetric cell division.     

The glp-1 locus and cellular interactions in early C. elegans embryos

Interactions between the early blastomeres in a C. elegans embryo are required for the specification of certain cell fates. Blastomeres that produce neurons and skin cells when cultured in isolation are induced to also produce pharyngeal cells in intact embryos. We have identified maternal effect lethal mutations that, on the basis of phenotype and temperature-sensitive period, appear to disrupt this inductive interaction. These mutations are all alleles of glp-1, a gene also involved in the control of germ cell proliferation during postembryonic development of C. elegans.     

Beyond the plasma membrane: New functions for heterotrimeric G-protein signaling in asymmetric and symmetric cell division

Plasma membrane heterotrimeric G proteins transduce extracellular signal from seven transmembrane receptors to downstream effectors. In addition, G proteins and their regulators localize at multiple intracellular sites and play crucial roles in cell division. In model organisms such as Caenorhabditis elegans and Drosophila receptor-independent heterotrimeric G protein function is vital for the orientation of mitotic spindle, generation of microtubule pulling force, aster-induced cytokinesis, and centration of the nucleus-centrosome complex. This new paradigm is now being extended to mammalian cells. Mammalian G protein signaling components localize in centrosomes and at the midbody, and altered function or expression of these proteins can cause cell division defects. Here, we highlight the role and possible mechanisms of G protein signaling in mammalian cell division in conjunction with recent findings in model organisms. Together the evidence argues for a more direct role of non-canonical heterotrimeric G protein signaling in microtubule- and actin cytoskeleton-mediated cellular processes.     

Cortical microtubule contacts position the spindle in C. elegans embryos

Interactions between microtubules and the cell cortex play a critical role in positioning organelles in a variety of biological contexts. Here we used Caenorhabditis elegans as a model system to study how cortex-microtubule interactions position the mitotic spindle in response to polarity cues. Imaging EBP-2::GFP and YFP::alpha-tubulin revealed that microtubules shrink soon after cortical contact, from which we propose that cortical adaptors mediate microtubule depolymerization energy into pulling forces. We also observe association of dynamic microtubules to form astral fibers that persist, despite the catastrophe events of individual microtubules. Computer simulations show that these effects, which are crucially determined by microtubule dynamics, can explain anaphase spindle oscillations and posterior displacement in 3D.     

eat-11 encodes GPB-2, a Gbeta(5) ortholog that interacts with G(o)alpha and G(q)alpha to regulate C. elegans behavior

In C. elegans, a G(o)/G(q) signaling network regulates locomotion and egg laying [1-8]. Genetic analysis shows that activated Ca(2+)/calmodulin-dependent protein kinase II (CaMKII) is suppressed by perturbations of this network, which include loss of the GOA-1 G(o)alpha, DGK-1 diacylglycerol kinase, EAT-16 G protein gamma subunit-like (GGL)-containing RGS protein, or an unidentified protein encoded by the gene eat-11 [9]. We cloned eat-11 and report that it encodes the Gbeta(5) ortholog GPB-2. Gbeta(5) binds specifically to GGL-containing RGS proteins, and the Gbeta(5)/RGS complex can promote the GTP-hydrolyzing activity of Galpha subunits [10, 11]. However, little is known about how this interaction affects G protein signaling in vivo. In addition to EAT-16, the GGL-containing RGS protein EGL-10 participates in G(o)/G(q) signaling; EGL-10 appears to act as an RGS for the GOA-1 G(o)alpha, while EAT-16 appears to act as an RGS for the EGL-30 G(q)alpha [4, 5]. We have combined behavioral, electrophysiological, and pharmacological approaches to show that GPB-2 is a central member of the G(o)/G(q) network and that GPB-2 may interact with both the EGL-10 and EAT-16 RGS proteins to mediate the opposing activities of G(o)alpha and G(q)alpha. These interactions provide a mechanism for the modulation of behavior by antagonistic G protein networks.     

PLK-1 asymmetry contributes to asynchronous cell division of C. elegans embryos

Acquisition of lineage-specific cell cycle duration is an important feature of metazoan development. In Caenorhabditis elegans, differences in cell cycle duration are already apparent in two-cell stage embryos, when the larger anterior blastomere AB divides before the smaller posterior blastomere P1. This time difference is under the control of anterior-posterior (A-P) polarity cues set by the PAR proteins. The mechanisms by which these cues regulate the cell cycle machinery differentially in AB and P1 are incompletely understood. Previous work established that retardation of P1 cell division is due in part to preferential activation of an ATL-1/CHK-1 dependent checkpoint in P1, but how the remaining time difference is controlled is not known. Here, we establish that differential timing relies also on a mechanism that promotes mitosis onset preferentially in AB. The polo-like kinase PLK-1, a positive regulator of mitotic entry, is distributed in an asymmetric manner in two-cell stage embryos, with more protein present in AB than in P1. We find that PLK-1 asymmetry is regulated by A-P polarity cues through preferential protein retention in the embryo anterior. Importantly, mild inactivation of plk-1 by RNAi delays entry into mitosis in P1, but not in AB, in a manner that is independent of ATL-1/CHK-1. Together, our findings support a model in which differential timing of mitotic entry in C. elegans embryos relies on two complementary mechanisms: ATL-1/CHK-1-dependent preferential retardation in P1 and PLK-1-dependent preferential promotion in AB, which together couple polarity cues and cell cycle progression during early development.     

Centrosomes promote timely mitotic entry in C. elegans embryos

Several mitotic regulators, including Cyclin B1/Cdk1, are present at centrosomes prior to mitosis onset, but it is unclear whether centrosomes promote mitotic entry in vivo. Here we developed a sensitive assay in C. elegans embryos for the temporal analysis of mitotic entry, in which the male and female pronuclei undergo asynchronous entry into mitosis when separated from one another. Using this assay, we found that centrosome integrity is necessary for timing mitotic entry. Centrosomes do not function in this instance through their ability to nucleate microtubules. Instead, centrosomes serve to focus the Aurora A kinase AIR-1, which is essential for timely mitotic entry. Furthermore, analysis of embryos in which centrosomes and pronuclei are detached from one another demonstrates that centrosomes are sufficient to promote mitosis onset. Together, our findings support a model in which centrosomes serve as integrative centers for mitotic regulators and thus trigger mitotic entry in a timely fashion.     

Endothelin-1 activates endothelial cell nitric-oxide synthase via heterotrimeric G-protein betagamma subunit signaling to protein jinase B/Akt

Endothelin-1 has dual vasoactive effects, mediating vasoconstriction via ETA receptor activation of vascular smooth muscle cells and vasorelaxation via ETB receptor activation of endothelial cells. Although it is commonly accepted that endothelin-1 binding to endothelial cell ETB receptors stimulates nitric oxide (NO) synthesis and subsequent smooth muscle relaxation, the signaling pathways downstream of ETB receptor activation are unknown. Here, using a model in which we have utilized isolated primary endothelial cells, we demonstrate that ET-1 binding to sinusoidal endothelial cell ETB receptors led to increased protein kinase B/Akt phosphorylation, endothelial cell nitric-oxide synthase (eNOS) phosphorylation, and NO synthesis. Furthermore, eNOS activation was not dependent on tyrosine phosphorylation, and pretreatment of endothelial cells with pertussis toxin as well as overexpression of a dominant negative G-protein-coupled receptor kinase construct that sequesters betagamma subunits inhibited Akt phosphorylation and NO synthesis. Taken together, the data elucidate a G-protein-coupled receptor signaling pathway for ETB receptor-mediated NO production and call attention to the absolute requirement for heterotrimeric G-protein betagamma subunits in this cascade.     

Dopamine mediates context-dependent modulation of sensory plasticity in C. elegans

Dopamine has been implicated in the modulation of diverse forms of behavioral plasticity, including appetitive learning and addiction. An important challenge is to understand how dopamine's effects at the cellular level alter the properties of neural circuits to modify behavior. In the nematode C. elegans, dopamine modulates habituation of an escape reflex triggered by body touch. In the absence of food, animals habituate more rapidly than in the presence of food; this contextual information about food availability is provided by dopaminergic mechanosensory neurons that sense the presence of bacteria. We find that dopamine alters habituation kinetics by selectively modulating the touch responses of the anterior-body mechanoreceptors; this modulation involves a D1-like dopamine receptor, a Gq/PLC-beta signaling pathway, and calcium release within the touch neurons. Interestingly, the body touch mechanoreceptors can themselves excite the dopamine neurons, forming a positive feedback loop capable of integrating context and experience to modulate mechanosensory attention.