Cell-Autonomous Gβ Signaling Defines Neuron-Specific Steady State Serotonin Synthesis in Caenorhabditis elegans

Heterotrimeric G proteins regulate a vast array of cellular functions via specific intracellular effectors. Accumulating pharmacological and biochemical studies implicate Gβ subunits as signaling molecules interacting directly with a wide range of effectors to modulate downstream cellular responses, in addition to their role in regulating Gα subunit activities. However, the native biological roles of Gβ-mediated signaling pathways in vivo have been characterized only in a few cases. Here, we identified a Gβ GPB-1 signaling pathway operating in specific serotonergic neurons to the define steady state serotonin (5-HT) synthesis, through a genetic screen for 5-HT synthesis mutants in Caenorhabditis elegans. We found that signaling through cell autonomous GPB-1 to the OCR-2 TRPV channel defines the baseline expression of 5-HT synthesis enzyme tryptophan hydroxylase tph-1 in ADF chemosensory neurons. This Gβ signaling pathway is not essential for establishing the serotonergic cell fates and is mechanistically separated from stress-induced tph-1 upregulation. We identified that ADF-produced 5-HT controls specific innate rhythmic behaviors. These results revealed a Gβ-mediated signaling operating in differentiated cells to specify intrinsic functional properties, and indicate that baseline TPH expression is not a default generic serotonergic fate, but is programmed in a cell-specific manner in the mature nervous system. Cell-specific regulation of TPH expression could be a general principle for tailored steady state 5-HT synthesis in functionally distinct neurons and their regulation of innate behavior.     

Regulators of AWC-Mediated Olfactory Plasticity in Caenorhabditis elegans

While most sensory neurons will adapt to prolonged stimulation by down-regulating their responsiveness to the signal, it is not clear which events initiate long-lasting sensory adaptation. Likewise, we are just beginning to understand how the physiology of the adapted cell is altered. Caenorhabditis elegans is inherently attracted to specific odors that are sensed by the paired AWC olfactory sensory neurons. The attraction diminishes if the animal experiences these odors for a prolonged period of time in the absence of food. The AWC neuron responds acutely to odor-exposure by closing calcium channels. While odortaxis requires a Gα subunit protein, cGMP-gated channels, and guanylyl cyclases, adaptation to prolonged odor exposure requires nuclear entry of the cGMP-dependent protein kinase, EGL-4. We asked which candidate members of the olfactory signal transduction pathway promote nuclear entry of EGL-4 and which molecules might induce long-term adaptation downstream of EGL-4 nuclear entry. We found that initiation of long-term adaptation, as assessed by nuclear entry of EGL-4, is dependent on G-protein mediated signaling but is independent of fluxes in calcium levels. We show that long-term adaptation requires polyunsaturated fatty acids (PUFAs) that may act on the transient receptor potential (TRP) channel type V OSM-9 downstream of EGL-4 nuclear entry. We also present evidence that high diacylglycerol (DAG) levels block long-term adaptation without affecting EGL-4 nuclear entry. Our analysis provides a model for the process of long-term adaptation that occurs within the AWC neuron of C. elegans: G-protein signaling initiates long-lasting olfactory adaptation by promoting the nuclear entry of EGL-4, and once EGL-4 has entered the nucleus, processes such as PUFA activation of the TRP channel OSM-9 may dampen the output of the AWC neuron.     

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.     

A Chemical Biology Approach Demonstrates G Protein βγ Subunits Are Sufficient to Mediate Directional Neutrophil Chemotaxis

Our laboratory has identified a number of small molecules that bind to G protein βγ subunits (Gβγ) by competing for peptide binding to the Gβγ “hot spot.” M119/Gallein were identified as inhibitors of Gβγ subunit signaling. Here we examine the activity of another molecule identified in this screen, 12155, which we show that in contrast to M119/Gallein had no effect on Gβγ-mediated phospholipase C or phosphoinositide 3-kinase (PI3K) γ activation in vitro. Also in direct contrast to M119/Gallein, 12155 caused receptor-independent Ca²⁺ release, and activated other downstream targets of Gβγ including extracellular signal regulated kinase (ERK), protein kinase B (Akt) in HL60 cells differentiated to neutrophils. We show that 12155 releases Gβγ in vitro from Gα_i1β₁γ₂ heterotrimers by causing its dissociation from GαGDP without inducing nucleotide exchange in the Gα subunit. We used this novel probe to examine the hypothesis that Gβγ release is sufficient to direct chemotaxis of neutrophils in the absence of receptor or G protein α subunit activation. 12155 directed chemotaxis of HL60 cells and primary neutrophils in a transwell migration assay with responses similar to those seen for the natural chemotactic peptide n-formyl-Met-Leu-Phe. These data indicate that release of free Gβγ is sufficient to drive directional chemotaxis in a G protein-coupled receptor signaling-independent manner.     

Genetic and Physical Interactions between Gα Subunits and Components of the Gβγ Dimer of Heterotrimeric G Proteins in Neurospora crassa

Heterotrimeric G proteins are critical regulators of growth and asexual and sexual development in the filamentous fungus Neurospora crassa. Three Gα subunits (GNA-1, GNA-2, and GNA-3), one Gβ subunit (GNB-1), and one Gγ subunit (GNG-1) have been functionally characterized, but genetic epistasis relationships between Gβ and Gα subunit genes have not been determined. Physical association between GNB-1 and FLAG-tagged GNG-1 has been previously demonstrated by coimmunoprecipitation, but knowledge of the Gα binding partners for the Gβγ dimer is currently lacking. In this study, the three N. crassa Gα subunits are analyzed for genetic epistasis with gnb-1 and for physical interaction with the Gβγ dimer. We created double mutants lacking one Gα gene and gnb-1 and introduced constitutively active, GTPase-deficient alleles for each Gα gene into the Δgnb-1 background. Genetic analysis revealed that gna-3 is epistatic to gnb-1 with regard to negative control of submerged conidiation. gnb-1 is epistatic to gna-2 and gna-3 for aerial hyphal height, while gnb-1 appears to act upstream of gna-1 and gna-2 during aerial conidiation. None of the activated Gα alleles restored female fertility to Δgnb-1 mutants, and the gna-3^Q208L allele inhibited formation of female reproductive structures, consistent with a need for Gα proteins to cycle through the inactive GDP-bound form for these processes. Coimmunoprecipitation experiments using extracts from the gng-1-FLAG strain demonstrated that the three Gα proteins interact with the Gβγ dimer. The finding that the Gβγ dimer interacts with all three Gα proteins is supported by epistasis between gnb-1 and gna-1, gna-2, and gna-3 for at least one function.     

Selection of Gβ Subunits with Point Mutations That Fail to Activate Specific Signaling Pathways In Vivo: Dissecting Cellular Responses Mediated by a Heterotrimeric G Protein in Dictyostelium discoideum

In Dictyostelium discoideum, a unique Gβ subunit is required for a G protein–coupled receptor system that mediates a variety of cellular responses. Binding of cAMP to cAR1, the receptor linked to the G protein G2, triggers a cascade of responses, including activation of adenylyl cyclase, gene induction, actin polymerization, and chemotaxis. Null mutations of the cAR1, Gα2, and Gβ genes completely impair all these responses. To dissect specificity in Gβγ signaling to downstream effectors in living cells, we screened a randomly mutagenized library of Gβ genes and isolated Gβ alleles that lacked the capacity to activate some effectors but retained the ability to regulate others. These mutant Gβ subunits were able to link cAR1 to G2, to support gene expression, and to mediate cAMP-induced actin polymerization, and some were able to mediate to chemotaxis toward cAMP. None was able to activate adenylyl cyclase, and some did not support chemotaxis. Thus, we separated in vivo functions of Gβγ by making point mutations on Gβ. Using the structure of the heterotrimeric G protein displayed in the computer program CHAIN, we examined the positions and the molecular interactions of the amino acids substituted in each of the mutant Gβs and analyzed the possible effects of each replacement. We identified several residues that are crucial for activation of the adenylyl cyclase. These residues formed an area that overlaps but is not identical to regions where bovine Gtβγ interacts with its regulators, Gα and phosducin.     

SEK-1 MAPKK mediates Ca2+ signaling to determine neuronal asymmetric development in Caenorhabditis?elegans

The mitogen-activated protein kinase (MAPK) pathway is a highly conserved signaling cascade that converts extracellular signals into various outputs. In Caenorhabditis elegans, asymmetric expression of the candidate odorant receptor STR-2 in either the left or the right of two bilaterally symmetrical olfactory AWC neurons is regulated by axon contact and Ca²⁺ signaling. We show that the MAPK kinase (MAPKK) SEK-1 is required for asymmetric expression in AWC neurons. Genetic and biochemical analyses reveal that SEK-1 functions in a pathway downstream of UNC-43 and NSY-1, Ca²⁺/calmodulin-dependent protein kinase II (CaMKII) and MAPK kinase kinase (MAPKKK), respectively. Thus, the NSY-1–SEK-1–MAPK cascade is activated by Ca²⁺ signaling through CaMKII and establishes asymmetric cell fate decision during neuronal development.     

Evolution,Expression Differentiation and Interaction Specificity of Heterotrimeric G-Protein Subunit Gene Family in the Mesohexaploid Brassica rapa

Heterotrimeric G-proteins, comprising of Gα, Gβ, and Gγ subunits, are important signal transducers which regulate many aspects of fundamental growth and developmental processes in all eukaryotes. Initial studies in model plants Arabidopsis and rice suggest that the repertoire of plant G-protein is much simpler than that observed in metazoans. In order to assess the consequence of whole genome triplication events within Brassicaceae family, we investigated the multiplicity of G-protein subunit genes in mesohexaploid Brassica rapa, a globally important vegetable and oilseed crop. We identified one Gα (BraA.Gα1), three Gβ (BraA.Gβ1, BraA.Gβ2, and BraA.Gβ3), and five Gγ (BraA.Gγ1, BraA.Gγ2, BraA.Gγ3, BraA.Gγ4, and BraA.Gγ5) genes from B. rapa, with a possibility of 15 Gαβγ heterotrimer combinations. Our analysis suggested that the process of genome triplication coupled with gene-loss (gene-fractionation) phenomenon have shaped the quantitative and sequence diversity of G-protein subunit genes in the extant B. rapa genome. Detailed expression analysis using qRT-PCR assays revealed that the G-protein genes have retained ubiquitous but distinct expression profiles across plant development. The expression of multiple G-protein genes was differentially regulated during seed-maturation and germination stages, and in response to various phytohormone treatments and stress conditions. Yeast-based interaction analysis showed that G-protein subunits interacted in most of the possible combinations, with some degree of subunit-specific interaction specificity, to control the functional selectivity of G-protein heterotrimer in different cell and tissue-types or in response to different environmental conditions. Taken together, this research identifies a highly diverse G-protein signaling network known to date from B. rapa, and provides a clue about the possible complexity of G-protein signaling networks present across globally important Brassica species.     

A Molecular Readout of Long-term Olfactory Adaptation in C. elegans

During sustained stimulation most sensory neurons will adapt their response by decreasing their sensitivity to the signal. The adaptation response helps shape attention and also protects cells from over-stimulation. Adaptation within the olfactory circuit of C. elegans was first described by Colbert and Bargmann^1,2. Here, the authors defined parameters of the olfactory adaptation paradigm, which they used to design a genetic screen to isolate mutants defective in their ability to adapt to volatile odors sensed by the Amphid Wing cells type C (AWC) sensory neurons. When wildtype C. elegans animals are exposed to an attractive AWC-sensed odor³ for 30 min they will adapt their responsiveness to the odor and will then ignore the adapting odor in a chemotaxis behavioral assay for ~1 hr. When wildtype C. elegans animals are exposed to an attractive AWC-sensed odor for ~1 hr they will then ignore the adapting odor in a chemotaxis behavioral assay for ~3 hr. These two phases of olfactory adaptation in C. elegans were described as short-term olfactory adaptation (induced after 30 min odor exposure), and long-term olfactory adaptation (induced after 60 min odor exposure). Later work from L''Etoile et al.,⁴ uncovered a Protein Kinase G (PKG) called EGL-4 that is required for both the short-term and long-term olfactory adaptation in AWC neurons. The EGL-4 protein contains a nuclear localization sequence that is necessary for long-term olfactory adaptation responses but dispensable for short-term olfactory adaptation responses in the AWC⁴. By tagging EGL-4 with a green fluorescent protein, it was possible to visualize the localization of EGL-4 in the AWC during prolonged odor exposure. Using this fully functional GFP-tagged EGL-4 (GFP::EGL-4) molecule we have been able to develop a molecular readout of long-term olfactory adaptation in the AWC⁵. Using this molecular readout of olfactory adaptation we have been able to perform both forward and reverse genetic screens to identify mutant animals that exhibit defective subcellular localization patterns of GFP::EGL-4 in the AWC^6,7. Here we describe: 1) the construction of GFP::EGL-4 expressing animals; 2) the protocol for cultivation of animals for long-term odor-induced nuclear translocation assays; and 3) the scoring of the long-term odor-induced nuclear translocation event and recovery (re-sensitization) from the nuclear GFP::EGL-4 state.     

Arabidopsis Heterotrimeric G-Proteins Play a Critical Role in Host and Nonhost Resistance against Pseudomonas syringae Pathogens

Heterotrimeric G-proteins have been proposed to be involved in many aspects of plant disease resistance but their precise role in mediating nonhost disease resistance is not well understood. We evaluated the roles of specific subunits of heterotrimeric G-proteins using knock-out mutants of Arabidopsis Gα, Gβ and Gγ subunits in response to host and nonhost Pseudomonas pathogens. Plants lacking functional Gα, Gβ and Gγ1Gγ2 proteins displayed enhanced bacterial growth and disease susceptibility in response to host and nonhost pathogens. Mutations of single Gγ subunits Gγ1, Gγ2 and Gγ3 did not alter bacterial disease resistance. Some specificity of subunit usage was observed when comparing host pathogen versus nonhost pathogen. Overexpression of both Gα and Gβ led to reduced bacterial multiplication of nonhost pathogen P. syringae pv. tabaci whereas overexpression of Gβ, but not of Gα, resulted in reduced bacterial growth of host pathogen P. syringae pv. maculicola, compared to wild-type Col-0. Moreover, the regulation of stomatal aperture by bacterial pathogens was altered in Gα and Gβ mutants but not in any of the single or double Gγ mutants. Taken together, these data substantiate the critical role of heterotrimeric G-proteins in plant innate immunity and stomatal modulation in response to P. syringae.     

HIV-1 Nef Impairs Heterotrimeric G-protein Signaling by Targeting Gαi2 for Degradation through Ubiquitination

The HIV Nef protein is an important pathogenic factor that modulates cell surface receptor trafficking and impairs cell motility, presumably by interfering at multiple steps with chemotactic receptor signaling. Here, we report that a dominant effect of Nef is to trigger AIP4 E3 ligase-mediated Gα_i2 ubiquitination, which leads to Gα_i2 endolysosomal sequestration and destruction. The loss of the Gα_i2 subunit was demonstrable in many cell types in the context of gene transfection, HIV infection, or Nef protein transduction. Nef directly interacts with Gα_i2 and ternary complexes containing AIP4, Nef, and Gα_i2 form. A substantial reversal of Gα_i2 loss and a partial recovery of impaired chemotaxis occurred following siRNA knockdown of AIP4 or NEDD4 or by inhibiting dynamin. The N-terminal myristoyl group, ⁶²EEEE⁶⁵ motif, and ⁷²PXXP⁷⁵ motif of Nef are critical for this effect to occur. Nef expression does not affect a Gq_i5 chimera where the five C-terminal residues of Gq are replaced with those of Gα_i2. Lysine at position 296 of Gα_i2 was identified as the critical determinant of Nef-induced degradation. By specifically degrading Gα_i2, Nef directly subverts leukocyte migration and homing. Impaired trafficking and homing of HIV Nef-expressing lymphocytes probably contributes to early immune dysfunction following HIV infection.     

Functional Coupling of a Nematode Chemoreceptor to the Yeast Pheromone Response Pathway

Sequencing of the Caenorhabditis elegans genome revealed sequences encoding more than 1,000 G-protein coupled receptors, hundreds of which may respond to volatile organic ligands. To understand how the worm''s simple olfactory system can sense its chemical environment there is a need to characterise a representative selection of these receptors but only very few receptors have been linked to a specific volatile ligand. We therefore set out to design a yeast expression system for assigning ligands to nematode chemoreceptors. We showed that while a model receptor ODR-10 binds to C. elegans Gα subunits ODR-3 and GPA-3 it cannot bind to yeast Gα. However, chimaeras between the nematode and yeast Gα subunits bound to both ODR-10 and the yeast Gβγ subunits. FIG2 was shown to be a superior MAP-dependent promoter for reporter expression. We replaced the endogenous Gα subunit (GPA1) of the Saccharomyces cerevisiae (ste2Δ sst2Δ far1Δ) triple mutant (“Cyb”) with a Gpa1/ODR-3 chimaera and introduced ODR-10 as a model nematode GPCR. This strain showed concentration-dependent activation of the yeast MAP kinase pathway in the presence of diacetyl, the first time that the native form of a nematode chemoreceptor has been functionally expressed in yeast. This is an important step towards en masse de-orphaning of C. elegans chemoreceptors.     

A Quantitative Model of the GIRK1/2 Channel Reveals That Its Basal and Evoked Activities Are Controlled by Unequal Stoichiometry of Gα and Gβγ

G protein-gated K⁺ channels (GIRK; Kir3), activated by Gβγ subunits derived from G_i/o proteins, regulate heartbeat and neuronal excitability and plasticity. Both neurotransmitter-evoked (I_evoked) and neurotransmitter-independent basal (I_basal) GIRK activities are physiologically important, but mechanisms of I_basal and its relation to I_evoked are unclear. We have previously shown for heterologously expressed neuronal GIRK1/2, and now show for native GIRK in hippocampal neurons, that I_basal and I_evoked are interrelated: the extent of activation by neurotransmitter (activation index, R_a) is inversely related to I_basal. To unveil the underlying mechanisms, we have developed a quantitative model of GIRK1/2 function. We characterized single-channel and macroscopic GIRK1/2 currents, and surface densities of GIRK1/2 and Gβγ expressed in Xenopus oocytes. Based on experimental results, we constructed a mathematical model of GIRK1/2 activity under steady-state conditions before and after activation by neurotransmitter. Our model accurately recapitulates I_basal and I_evoked in Xenopus oocytes, HEK293 cells and hippocampal neurons; correctly predicts the dose-dependent activation of GIRK1/2 by coexpressed Gβγ and fully accounts for the inverse I_basal-R_a correlation. Modeling indicates that, under all conditions and at different channel expression levels, between 3 and 4 Gβγ dimers are available for each GIRK1/2 channel. In contrast, available Gα_i/o decreases from ~2 to less than one Gα per channel as GIRK1/2''s density increases. The persistent Gβγ/channel (but not Gα/channel) ratio support a strong association of GIRK1/2 with Gβγ, consistent with recruitment to the cell surface of Gβγ, but not Gα, by GIRK1/2. Our analysis suggests a maximal stoichiometry of 4 Gβγ but only 2 Gα_i/o per one GIRK1/2 channel. The unique, unequal association of GIRK1/2 with G protein subunits, and the cooperative nature of GIRK gating by Gβγ, underlie the complex pattern of basal and agonist-evoked activities and allow GIRK1/2 to act as a sensitive bidirectional detector of both Gβγ and Gα.     

A Highlights from MBoC Selection: Drosophila Ric-8 interacts with the Gα12/13 subunit,Concertina, during activation of the Folded gastrulation pathway

Heterotrimeric G proteins, composed of α, β, and γ subunits, are activated by exchange of GDP for GTP on the Gα subunit. Canonically, Gα is stimulated by the guanine-nucleotide exchange factor (GEF) activity of ligand-bound G protein–coupled receptors. However, Gα subunits may also be activated in a noncanonical manner by members of the Ric-8 family, cytoplasmic proteins that also act as GEFs for Gα subunits. We used a signaling pathway active during Drosophila gastrulation as a model system to study Ric-8/Gα interactions. A component of this pathway, the Drosophila Gα_12/13 subunit, Concertina (Cta), is necessary to trigger actomyosin contractility during gastrulation events. Ric-8 mutants exhibit similar gastrulation defects to Cta mutants. Here we use a novel tissue culture system to study a signaling pathway that controls cytoskeletal rearrangements necessary for cellular morphogenesis. We show that Ric-8 regulates this pathway through physical interaction with Cta and preferentially interacts with inactive Cta and directs its localization within the cell. We also use this system to conduct a structure–function analysis of Ric-8 and identify key residues required for both Cta interaction and cellular contractility.     

Canonical and Noncanonical G-Protein Signaling Helps Coordinate Actin Dynamics To Promote Macrophage Phagocytosis of Zymosan

Both chemotaxis and phagocytosis depend upon actin-driven cell protrusions and cell membrane remodeling. While chemoattractant receptors rely upon canonical G-protein signaling to activate downstream effectors, whether such signaling pathways affect phagocytosis is contentious. Here, we report that Gα_i nucleotide exchange and signaling helps macrophages coordinate the recognition, capture, and engulfment of zymosan bioparticles. We show that zymosan exposure recruits F-actin, Gα_i proteins, and Elmo1 to phagocytic cups and early phagosomes. Zymosan triggered an increase in intracellular Ca²⁺ that was partially sensitive to Gα_i nucleotide exchange inhibition and expression of GTP-bound Gα_i recruited Elmo1 to the plasma membrane. Reducing GDP-Gα_i nucleotide exchange, decreasing Gα_i expression, pharmacologically interrupting Gβγ signaling, or reducing Elmo1 expression all impaired phagocytosis, while favoring the duration that Gα_i remained GTP bound promoted it. Our studies demonstrate that targeting heterotrimeric G-protein signaling offers opportunities to enhance or retard macrophage engulfment of phagocytic targets such as zymosan.     

Mutants in Drosophila TRPC Channels Reduce Olfactory Sensitivity to Carbon Dioxide

Background

Members of the canonical Transient Receptor Potential (TRPC) class of cationic channels function downstream of Gαq and PLCβ in Drosophila photoreceptors for transducing visual stimuli. Gαq has recently been implicated in olfactory sensing of carbon dioxide (CO₂) and other odorants. Here we investigated the role of PLCβ and TRPC channels for sensing CO₂ in Drosophila.

Methodology/Principal Findings

Through behavioral assays it was demonstrated that Drosophila mutants for plc21c, trp and trpl have a reduced sensitivity for CO₂. Immuno-histochemical staining for TRP, TRPL and TRPγ indicates that all three channels are expressed in Drosophila antennae including the sensory neurons that express CO₂ receptors. Electrophysiological recordings obtained from the antennae of protein null alleles of TRP (trp³⁴³) and TRPL (trpl³⁰²), showed that the sensory response to multiple concentrations of CO₂ was reduced. However, trpl³⁰²; trp³⁴³ double mutants still have a residual response to CO₂. Down-regulation of TRPC channels specifically in CO₂ sensing olfactory neurons reduced the response to CO₂ and this reduction was obtained even upon down-regulation of the TRPCs in adult olfactory sensory neurons. Thus the reduced response to CO₂ obtained from the antennae of TRPC RNAi strains is not due to a developmental defect.

Conclusion

These observations show that reduction in TRPC channel function significantly reduces the sensitivity of the olfactory response to CO₂ concentrations of 5% or less in adult Drosophila. It is possible that the CO₂ receptors Gr63a and Gr21a activate the TRPC channels through Gαq and PLC21C.     

Different Roles of G Protein Subunits β1 and β2 in Neutrophil Function Revealed by Gene Expression Silencing in Primary Mouse Neutrophils

Neutrophils play important roles in host innate immunity and various inflammation-related diseases. In addition, neutrophils represent an excellent system for studying directional cell migration. However, neutrophils are terminally differentiated cells that are short lived and refractory to transfection; thus, they are not amenable for existing gene silencing techniques. Here we describe the development of a method to silence gene expression efficiently in primary mouse neutrophils. A mouse stem cell virus-based retroviral vector was modified to express short hairpin RNAs and fluorescent marker protein at high levels in hematopoietic cells and used to infect mouse bone marrow cells prior to reconstitution of the hematopoietic system in lethally irradiated mice. This method was used successfully to silence the expression of Gβ₁ and/or Gβ₂ in mouse neutrophils. Knockdown of Gβ₂ appeared to affect primarily the directionality of neutrophil chemotaxis rather than motility, whereas knockdown of Gβ₁ had no significant effect. However, knockdown of both Gβ₁ and Gβ₂ led to significant reduction in motility and responsiveness. In addition, knockdown of Gβ₁ but not Gβ₂ inhibited the ability of neutrophils to kill ingested bacteria, and only double knockdown resulted in significant reduction in bacterial phagocytosis. Therefore, we have developed a short hairpin RNA-based method to effectively silence gene expression in mouse neutrophils for the first time, which allowed us to uncover divergent roles of Gβ₁ and Gβ₂ in the regulation of neutrophil functions.     

The Gβγ-Src signaling pathway regulates TNF-induced necroptosis via control of necrosome translocation

Formation of multi-component signaling complex necrosomes is essential for tumor necrosis factor α (TNF)-induced programmed necrosis (also called necroptosis). However, the mechanisms of necroptosis are still largely unknown. We isolated a TNF-resistant L929 mutant cell line generated by retrovirus insertion and identified that disruption of the guanine nucleotide-binding protein γ 10 (Gγ10) gene is responsible for this phenotype. We further show that Gγ10 is involved in TNF-induced necroptosis and Gβ2 is the partner of Gγ10. Src is the downstream effector of Gβ2γ10 in TNF-induced necroptosis because TNF-induced Src activation was impaired upon Gγ10 knockdown. Gγ10 does not affect TNF-induced activation of NF-κB and MAPKs and the formation of necrosomes, but is required for trafficking of necrosomes to their potential functioning site, an unidentified subcellular organelle that can be fractionated into heterotypic membrane fractions. The TNF-induced Gβγ-Src signaling pathway is independent of RIP1/RIP3 kinase activity and necrosome formation, but is required for the necrosome to function.     

Sporophyte Formation and Life Cycle Completion in Moss Requires Heterotrimeric G-Proteins

In this study, we report the functional characterization of heterotrimeric G-proteins from a nonvascular plant, the moss Physcomitrella patens. In plants, G-proteins have been characterized from only a few angiosperms to date, where their involvement has been shown during regulation of multiple signaling and developmental pathways affecting overall plant fitness. In addition to its unparalleled evolutionary position in the plant lineages, the P. patens genome also codes for a unique assortment of G-protein components, which includes two copies of Gβ and Gγ genes, but no canonical Gα. Instead, a single gene encoding an extra-large Gα (XLG) protein exists in the P. patens genome. Here, we demonstrate that in P. patens the canonical Gα is biochemically and functionally replaced by an XLG protein, which works in the same genetic pathway as one of the Gβ proteins to control its development. Furthermore, the specific G-protein subunits in P. patens are essential for its life cycle completion. Deletion of the genomic locus of PpXLG or PpGβ2 results in smaller, slower growing gametophores. Normal reproductive structures develop on these gametophores, but they are unable to form any sporophyte, the only diploid stage in the moss life cycle. Finally, the mutant phenotypes of ΔPpXLG and ΔPpGβ2 can be complemented by the homologous genes from Arabidopsis, AtXLG2 and AtAGB1, respectively, suggesting an overall conservation of their function throughout the plant evolution.In all known eukaryotes, cellular signaling involves heterotrimeric GTP-binding proteins (G-proteins), which consist of Gα, Gβ, and Gγ subunits (Cabrera-Vera et al., 2003). According to the established paradigm, when Gα is GDP-bound, it forms a trimeric complex with the Gβγ dimer and remains associated with a G-protein coupled receptor. Signal perception by the receptor facilitates GDP to GTP exchange on Gα. GTP-Gα dissociates from the Gβγ dimer, and both these entities can transduce the signal by interacting with different effectors. The duration of the active state is determined by the intrinsic GTPase activity of Gα, which hydrolyzes bound GTP into GDP and inorganic phosphate (Pi), followed by the reassociation of the inactive, trimeric complex (Siderovski and Willard, 2005).In plants, G-protein signaling has been studied in only a few angiosperms to date at the functional level, although the proteins exist in the entire plant lineage (Hackenberg and Pandey, 2014; Urano and Jones, 2014; Hackenberg et al., 2016). Interestingly, while the overall biochemistry of the individual G-protein components and the interactions between them are conserved between plant and metazoan systems, deviations from the established norm are also obvious. For example, the repertoire of canonical G-proteins is significantly limited in plants; the human genome codes for 23 Gα, 5 Gβ, and 12 Gγ proteins, whereas most plant genomes, including those of basal plants, typically encode 1 canonical Gα, 1 Gβ, and three to five Gγ proteins (Urano and Jones, 2014). The only exceptions are some polyploid species, such as soybean, which have retained most of the duplicated G-protein genes (Bisht et al., 2011; Choudhury et al., 2011). Moreover, even in plants that possess only a single canonical Gα and Gβ protein, for example Arabidopsis (Arabidopsis thaliana) and rice, the phenotypes of plants lacking either one or both proteins are relatively subtle. The mutant plants exhibit multiple developmental and signaling defects but are able to complete the life cycle without any major consequences. These observations have questioned the significance of G-protein mediated signaling pathways in plants.Interestingly, plants also possess certain unique variants of the classical G-protein components such as the type III Cys-rich Gγ proteins and extra-large GTP-binding (XLG) proteins, which add to the diversity and expanse of the G-protein signaling networks (Roy Choudhury et al., 2011; Chakravorty et al., 2015; Maruta et al., 2015). The XLG proteins are almost twice the size of typical Gα proteins, with the C-terminal region that codes for Gα-like domain and an extended N-terminal region without any distinctive features. Plant XLGs are encoded by entirely independent genes and therefore are different from the mammalian extra-long versions of Gα proteins such as XLαs and XXLαs, which are expressed due to the use of alternate exons (Abramowitz et al., 2004). Three to five copies of XLG proteins are present in the genome of most angiosperms. At the functional level, the XLG proteins have been characterized only from Arabidopsis, to date, where recent studies suggest that the proteins compete with canonical Gα for binding with the Gβγ dimers and may form functional trimeric complexes (Chakravorty et al., 2015; Maruta et al., 2015). The XLG and Gβγ mutants of Arabidopsis seem to function in the same pathways during the regulation of a subset of plant responses, for example primary root length and its regulation by abscisic acid (ABA); the root waving and skewing responses; sensitivity to Glc, salt, and tunicamycin; and sensitivity to certain bacterial and fungal pathogens (Ding et al., 2008; Pandey et al., 2008; Chakravorty et al., 2015; Maruta et al., 2015). However, many of the phenotypes of Arabidopsis Gα and Gβγ mutants are also distinct from that of the xlg triple mutants. For example, compared to the wild-type plants, the canonical G-protein mutants exhibit altered response to gibberellic acid, brassinosteroids, and auxin and show changes in leaf shape, branching, flowering time, and stomatal densities (Ullah et al., 2003; Chen et al., 2004; Pandey et al., 2006; Zhang et al., 2008; Nilson and Assmann, 2010). The xlg triple mutants behave similarly to wild-type plants in all these aspects of development and signaling. Moreover, whether the XLG proteins are authentic GTP-binding and -hydrolyzing proteins and the extent to which they directly participate in G-protein-mediated signaling pathways remains confounding (Chakravorty et al., 2015; Maruta et al., 2015). Even in plants with a limited number of G-protein subunits such as Arabidopsis, one Gα and three XLGs potentially compete for a single Gβ protein, and the analysis of null mutants is not straightforward, that is, it is not possible to delineate whether the phenotypes seen in the Gα null mutants are truly due to the lack of Gα and/or because of an altered stoichiometry or availability of Gβ for the XLG proteins.As a bryophyte, Physcomitrella patens occupies a unique position in the evolutionary history of plants. It lacks vasculature but exhibits alteration between generations, which is dominated by a gametophytic (haploid) phase and a short sporophytic (diploid) phase (Cove et al., 2009). Many of the pathways related to hormone signaling, stress responses, and development are conserved between angiosperms and P. patens (Cove et al., 2009; Sun, 2011; Komatsu et al., 2013; Yasumura et al., 2015). It is also an intriguing example in the context of the G-protein signaling, because its fully sequenced genome does not encode a canonical Gα gene, although genes coding for the Gβ and Gγ proteins exist. A single gene for a potential XLG homolog also exists in the P. patens genome. This unique assortment of proteins predicts several alternative scenarios for G-protein signaling in P. patens. For example, the P. patens Gβγ proteins might be nonfunctional due to the loss of canonical Gα and are left in the genome as evolutionary artifacts. Alternatively, the Gβγ proteins of P. patens might maintain functionality regardless of the existence of a canonical Gα protein in pathways not regulated via classic G-protein signaling modes. Finally, a more likely scenario could be that the potential XLG protein can substitute for the Gα function in P. patens.To explore these possibilities and understand better the conserved and unique mechanisms of G-protein signaling pathways in plants and their significance, we examined the role of G-protein subunits in P. patens. We provide unambiguous evidence for the genetic coupling of XLG and Gβ proteins in controlling P. patens development. In contrast to all other plant species analyzed to date, where G-proteins are not essential for growth and survival, the XLG or one of the Gβ proteins is required for the sporophyte formation and life cycle completion in P. patens. Furthermore, one of the Arabidopsis XLG proteins, XLG2, and the canonical Gβ protein AGB1 can functionally complement the P. patens mutant phenotypes. These data provide new insights in the evolutionary breadth and the spectrum of signaling pathways regulated by G-proteins in plants.