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[
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.
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[
Sci STKE,
2003]
Examples of the activation of heterotrimeric G proteins in vivo by any means other than through activated cell surface receptors have been limited to pathophysiological phenomena. With the discovery of proteins apart from receptors that facilitate guanine nucleotide exchange and affect G protein subunit dissociation directly, however, the notion of receptor-independent modes of activation in normal circumstances has become a subject of great interest. Three recent publications, each focusing on G protein regulators (GPRs) in asymmetric positioning of the mitotic spindle in the early Caenorhabditis elegans embryo, provide substantial support for the likelihood of such a form of activation. The C. elegans proteins GPR-1 and GPR-2 each contain a G protein regulatory motif, which supports interaction with Galpha(i)-like subunits. Inactivation of the genes encoding GPR-1 and GPR-2 prevents the correct positioning of the mitotic spindle in the one- and two-cell embryo. This phenotype is identical to that achieved by inactivation of genes encoding the Galpha subunits GOA-1 and GPA-16. Because signaling in the one- and two-cell embryos is "intrinsic," the data suggest a GPR-dependent, receptor-independent mode of G protein activation. The GPRs interact preferentially with the guanosine diphosphate (GDP)-bound form of alpha subunits, and the GPR motif per se exhibits GDP dissociation inhibitor activity. The actions of the GPRs imply that GDP.Galpha.GPR is a key intermediate or effector in force generation relevant to
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[
WormBook,
2014]
Polarity establishment, asymmetric division, and acquisition of cell fates are critical steps during early development. In this review, we discuss processes that set up the embryonic axes, with an emphasis on polarity establishment and asymmetric division. We begin with the first asymmetric division in the C. elegans embryo, where symmetry is broken by the local inactivation of actomyosin cortical contractility. This contributes to establishing a polarized distribution of PAR proteins and associated components on the cell cortex along the longitudinal embryonic axis, which becomes the anterior-posterior (AP) axis. Thereafter, AP polarity is maintained through reciprocal negative interactions between the anterior and posterior cortical domains. We then review the mechanisms that ensure proper positioning of the centrosomes and the mitotic spindle in the one-cell embryo by exerting pulling forces on astral microtubules. We explain how a ternary complex comprised of G (GOA-1/GPA-16), GPR-1/GPR-2, and LIN-5 is essential for anchoring the motor protein dynein to the cell cortex, where it is thought to exert pulling forces on depolymerizing astral microtubules. We proceed by providing an overview of cell cycle asynchrony in two-cell embryos, as well as the cell signaling and spindle positioning events that underly the subsequent asymmetric divisions, which establish the dorsal-ventral and left-right axes. We then discuss how AP polarity ensures the unequal segregation of cell fate regulators via the cytoplasmic proteins MEX-5/MEX-6 and other polarity mediators, before ending with an overview of how the fates of the early blastomeres are specified by these processes.
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[
Curr Biol,
2003]
The DAF-16 transcription factor controls aging in C. elegans as part of an insulin-like signaling pathway. Identification of a target of DAF-16 has opened a new window into the aging process.
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[
Cell Cycle,
2006]
A conserved
sir2 deacetylase gene can determine longevity of yeast, flies and worms. Recently we have reported a molecular mechanism of action of the C. elegans homologue
sir-2.1. Our study revealed a novel stress-dependent pathway for lifespan determination in which SIR-2.1 binds to 14-3-3 proteins and a forkhead transcription factor DAF-16 to activate transcription of DAF-16 target genes. DAF-16 has long been known as a central protein in the regulation of lifespan that interfaces with multiple pathways. Recent studies by us and other laboratories suggest that DAF-16 requires co-factors for full activity. In this prospective we review recent literature highlighting the role of SIR-2.1, 14-3-3 and other DAF-16 co-factors in DAF-16 activation.
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[
Med Sci (Paris),
2003]
The mechanisms orchestrating spatial cell division control remain poorly understood. In animal cells, the position of the mitotic spindle dictates cleavage furrow placement, and thus plays a key role in governing spatial relationships between resulting daughter cells. The one-cell stage Caenorhabditis elegans embryo is an attractive model system to investigate the mechanisms underlying spindle positioning in metozoans. In this review, the experimental advantages of this model system for an in vivo dissection of cell division processes are first discussed. Next, three lines of experiments that were conducted to dissect the mechanisms governing spindle positioning in one-cell stage C. elegans embryos are summarized. First, localized laser micro-irradiations were utilized to identify the forces acting on spindle poles during anaphase. This work revealed that there is a precise imbalance of pulling forces acting on the two spindle poles, with the forces acting on the posterior spindle pole being in slight excess, thus explaining the asymmetric spindle position achieved by the end of anaphase. Second, an RNAi-based fonctional genomic screen was carried out to identify novel components required for generating these pulling forces. This uncovered that
gpr-1/gpr-2, which encode GoLoco-containing proteins, as well as the previously identified Go subunits
goa-1/gpa-16, are required for generation of pulling forces on the spindle poles. Third, the
zyg-8 locus was identified by mutational analysis to play a distinct role during anaphase spindle positioning.
zyg-8 was found to encode a protein related to human Doublecortin, which is affected in patients with neuronal migration disorders. Moreover, ZYG-8 is a microtubule-associated protein that stabilizes microtubules against depolymerization. Together, these experimental approaches contribute to a better understanding of the mechanisms orchestrating spatial cell division control in metozoan organisms.
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[
Dev Dyn,
2010]
In a remarkably conserved insulin signaling pathway that is well-known for its regulation of longevity in worms, flies, and mammals, the major C. elegans effector of this pathway, DAF-16/FOXO, also modulates many other physiological processes. This raises the question of how DAF-16/FOXO chooses the correct targets to achieve the appropriate response in a particular context. Here, we review current knowledge of tissue-specificity and interacting partners that modulate DAF-16/FOXO functional output.
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[
Exp Gerontol,
2006]
In Caenorhabditis elegans, the insulin/IGF-1 signaling pathway controls many biological processes such as life span, fat storage, dauer diapause, reproduction and stress response . This pathway is comprised of many genes including the insulin/IGF-1 receptor (DAF-2) that signals through a conserved PI 3-kinase/AKT pathway and ultimately down-regulates DAF-16, a forkhead transcription factor (FOXO). DAF-16 also receives input from several other pathways that regulate life span such as the germline and the JNK pathway [Hsin, H., Kenyon, C., 1999. Signals from the reproductive system regulate the lifespan of C. elegans. Nature 399, 362-366; Oh, S.W., Mukhopadhyay, A., Svrzikapa, N., Jiang, F., Davis, R.J., Tissenbaum, H.A., 2005. JNK regulates lifespan in Caenorhabditis elegans by modulating nuclear translocation of forkhead transcription factor/DAF-16. Proc. Natl. Acad. Sci. USA 102, 4494-4499]. Therefore, DAF-16 integrates signals from multiple pathways and regulates its downstream target genes to control diverse processes. Here, we discuss the signals to and from DAF-16, with a focus on life span regulation.
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[
Biogerontology,
2015]
In C. elegans, mutations in the conserved insulin/IGF-1 signaling (IIS) pathway lead to a robust extension in lifespan, improved late life health, and protection from age-related disease. These effects are mediated by the FoxO transcription factor DAF-16 which lies downstream of the IIS kinase cascade. Identifying and functionally testing DAF-16 target genes has been a focal point of ageing research for the last 10years. Here, I review the recent advances in identifying and understanding IIS/DAF-16 targets. These studies continue to reveal the intricate nature of the IIS/DAF-16 gene regulation network and are helping us to understand the mechanisms that control lifespan. Ageing and age related disease is an area of intense public interest, and the biochemical characterization of the genes involved will be critical for identifying drugs to improve the health of our ageing population.
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[
Ann N Y Acad Sci,
2010]
In the nematode Caenorhabditis elegans and the fruit fly Drosophila, loss of the germline stem cells activates lifespan-extending FOXO-family transcription factors in somatic tissues and extends lifespan, suggesting the existence of an evolutionarily conserved pathway that links reproductive state and aging. Consistent with this idea, reproductive tissues have been shown to influence the lifespans of mice and humans as well. In C. elegans, loss of the germ cells activates a pathway that triggers nuclear localization of the FOXO transcription factor DAF-16 in endodermal tissue. DAF-16 then acts in the endoderm to activate downstream lifespan-extending genes. DAF-16 is also required for inhibition of insulin/insulin-like growth factor 1 (IGF-1) signaling to extend lifespan. However, the mechanisms by which inhibition of insulin/IGF-1 signaling and germline loss activate DAF-16/FOXO are distinct. As loss of the germ cells further doubles the already-long lifespan of insulin/IGF-1 pathway mutants, a better understanding of this reproductive longevity pathway could potentially suggest powerful ways to increase healthy lifespan in humans.