Genetic analysis of Caenorhabditis elegans glp-1 mutants suggests receptor interaction or competition

glp-1 encodes a member of the highly conserved LIN-12/Notch family of receptors that mediates the mitosis/meiosis decision in the C. elegans germline. We have characterized three mutations that represent a new genetic and phenotypic class of glp-1 mutants, glp-1(Pro). The glp-1(Pro) mutants display gain-of-function germline pattern defects, most notably a proximal proliferation (Pro) phenotype. Each of three glp-1(Pro) alleles encodes a single amino acid change in the extracellular part of the receptor: two in the LIN-12/Notch repeats (LNRs) and one between the LNRs and the transmembrane domain. Unlike other previously described gain-of-function mutations that affect this region of LIN-12/Notch family receptors, the genetic behavior of glp-1(Pro) alleles is not consistent with simple hypermorphic activity. Instead, the mutant phenotype is suppressed by wild-type doses of glp-1. Moreover, a trans-heterozygous combination of two highly penetrant glp-1(Pro) mutations is mutually suppressing. These results lend support to a model for a higher-order receptor complex and/or competition among receptor proteins for limiting factors that are required for proper regulation of receptor activity. Double-mutant analysis with suppressors and enhancers of lin-12 and glp-1 further suggests that the functional defect in glp-1(Pro) mutants occurs prior to or at the level of ligand interaction.     

Using C. elegans notch mutants in an undergraduate cancer biology laboratory course to demonstrate oncogenic effects on cell proliferation

Undergraduate laboratory exercises addressing aspects of cancer biology such as increased cell proliferation, gain-of-function signaling mutations and tumour formation often rely on tissue culture or even small mammal models. Many departments have limited or no access to these tools, and even well-equipped departments face logistical problems when incorporating these models into laboratory classes. I have developed a laboratory exercise using the microscopic worm, C. elegans, to demonstrate the effects of Notch receptor mutations on cell proliferation. Notch, which is activated by juxtacrine signaling, is mutated in many human cancers. In this exercise, students compare the germline phenotypes of worms that have a loss-of-function Notch mutation (no cells in the germline) or a gain-of-function Notch mutation (over-proliferation resulting in a germline tumour). Students also genotype the worms and perform sequence analysis to determine the effects of the mutations on the protein sequence. This laboratory exercise demonstrates oncogenic proliferation, correlates genotype to phenotype, exposes students to model organisms and introduces sequence databases and analysis. In addition to cancer biology courses, this exercise could be incorporated in courses with a focus on genetics, cell biology or developmental biology.     

A mutation in teg-4, which encodes a protein homologous to the SAP130 pre-mRNA splicing factor,disrupts the balance between proliferation and differentiation in the C. elegans germ line

Dividing stem cells can give rise to two types of daughter cells; self-renewing cells that have virtually the same properties as the parent cell, and differentiating cells that will eventually form part of a tissue. The Caenorhabditis elegans germ line serves as a model to study how the balance between these two types of daughter cells is maintained. A mutation in teg-4 causes over-proliferation of the stem cells, thereby disrupting the balance between proliferation and differentiation. We have cloned teg-4 and found it to encode a protein homologous to the highly conserved splicing factor subunit 3 of SF3b. Our allele of teg-4 partially reduces TEG-4 function. In an effort to determine how teg-4 functions in controlling stem cell proliferation, we have performed genetic epistasis analysis with known factors controlling stem cell proliferation. We found that teg-4 is synthetic tumorous with genes in both major redundant genetic pathways that function downstream of GLP-1/Notch signaling to control the balance between proliferation and differentiation. Therefore, teg-4 is unlikely to function specifically in either of these two genetic pathways. Further, the synthetic tumorous phenotype seen with one of the genes from these pathways is epistatic to glp-1, indicating that teg-4 functions downstream of glp-1, likely as a positive regulator of meiotic entry. We propose that a reduction in teg-4 activity reduces the splicing efficiency of targets involved in controlling the balance between proliferation and differentiation. This results in a shift in the balance towards proliferation, eventually forming a germline tumor.     

Scratching the niche that controls Caenorhabditis elegans germline stem cells

The Caenorhabditis elegans gonad provides a well-defined model for a stem cell niche and its control of self-renewal and differentiation. The distal tip cell (DTC) forms a mesenchymal niche that controls germline stem cells (GSCs), both to generate the germline tissue during development and to maintain it during adulthood. The DTC uses GLP-1/Notch signaling to regulate GSCs; germ cells respond to Notch signaling with a network of RNA regulators to control the decision between self-renewal and entry into the meiotic cell cycle.     

POS-1 and GLD-1 repress glp-1 translation through a conserved binding-site cluster

RNA-binding proteins (RBPs) coordinate cell fate specification and differentiation in a variety of systems. RNA regulation is critical during oocyte development and early embryogenesis, in which RBPs control expression from maternal mRNAs encoding key cell fate determinants. The Caenorhabditis elegans Notch homologue glp-1 coordinates germline progenitor cell proliferation and anterior fate specification in embryos. A network of sequence-specific RBPs is required to pattern GLP-1 translation. Here, we map the cis-regulatory elements that guide glp-1 regulation by the CCCH-type tandem zinc finger protein POS-1 and the STAR-domain protein GLD-1. Our results demonstrate that both proteins recognize the glp-1 3′ untranslated region (UTR) through adjacent, overlapping binding sites and that POS-1 binding excludes GLD-1 binding. Both factors are required to repress glp-1 translation in the embryo, suggesting that they function in parallel regulatory pathways. It is intriguing that two equivalent POS-1–binding sites are present in the glp-1 3′ UTR, but only one, which overlaps with a translational derepression element, is functional in vivo. We propose that POS-1 regulates glp-1 mRNA translation by blocking access of other RBPs to a key regulatory sequence.     

The establishment of Caenorhabditis elegans germline pattern is controlled by overlapping proximal and distal somatic gonad signals

We investigated the control of proliferation and differentiation in the larval Caenorhabditis elegans hermaphrodite germ line through analysis of glp-1 and lag-2 mutants, cell ablations, and ultrastructural data. After the first several rounds of germ cell division, GLP-1, a receptor of the LIN-12/Notch family, governs germline proliferation. We analyzed the proximal proliferation (Pro) phenotype in glp-1(ar202) and found that initial meiosis was delayed and spatially mispositioned. This is due, at least in part, to a heightened response of the mutant GLP-1 receptor to multiple sources of the somatic ligand LAG-2, including the proximal somatic gonad. We investigated whether proximal LAG-2 affects germline proliferation in the wild type. Our results indicate that (1) LAG-2 is necessary for GLP-1-mediated germline proliferation and prevention of early meiosis, and (2) several distinct anatomical sources of LAG-2 in the larval somatic gonad functionally overlap to promote proliferation and prevent early meiosis. Ultrastructural studies suggest that mitosis is not restricted to areas of direct DTC-germ line contact and that the germ line shares a common cytoplasm in larval stages. We propose that downregulation of the GLP-1 signaling pathway in the proximal germ line at the time of meiotic onset is under tight temporal and spatial control.     

Eukaryotic translation initiation factor 5B activity regulates larval growth rate and germline development in Caenorhabditis elegans

In C. elegans, a population of proliferating germ cells is maintained via GLP-1/Notch signaling; in the absence of GLP-1 signaling, germ cells prematurely enter meiosis and differentiate. We previously identified ego (enhancer of glp-1) genes that promote germline proliferation and interact genetically with the GLP-1 signaling pathway. Here, we report that iffb-1 (initiation factor five B) is an ego gene. iffb-1 encodes the sole C. elegans isoform of eukaryotic translation initiation factor 5B, a protein essential for translation. We have used RNA interference and a deletion mutation to determine the developmental consequences of reduced iffb-1 activity. Our data indicate that maternal iffb-1 gene expression is sufficient for embryogenesis, and zygotic iffb-1 expression is required for development beyond late L1/early L2 stage. Partial reduction in iffb-1 expression delays larval development and can severely disrupt proliferation and differentiation of germ cells. We hypothesize that germline development is particularly sensitive to iffb-1 expression level.     

EGO-1, a putative RNA-directed RNA polymerase, promotes germline proliferation in parallel with GLP-1/notch signaling and regulates the spatial organization of nuclear pore complexes and germline P granules in Caenorhabditis elegans

Caenorhabditis elegans EGO-1, a putative cellular RNA-directed RNA polymerase, promotes several aspects of germline development, including proliferation, meiosis, and gametogenesis, and ensures a robust response to RNA interference. In C. elegans, GLP-1/Notch signaling from the somatic gonad maintains a population of proliferating germ cells, while entry of germ cells into meiosis is triggered by the GLD-1 and GLD-2 pathways. GLP-1 signaling prevents germ cells from entering meiosis by inhibiting GLD-1 and GLD-2 activity. We originally identified the ego-1 gene on the basis of a genetic interaction with glp-1. Here, we investigate the role of ego-1 in germline proliferation. Our data indicate that EGO-1 does not positively regulate GLP-1 protein levels or GLP-1 signaling activity. Moreover, GLP-1 signaling does not positively regulate EGO-1 activity. EGO-1 does not inhibit expression of GLD-1 protein in the distal germline. Instead, EGO-1 acts in parallel with GLP-1 signaling to influence the proliferation vs. meiosis fate choice. Moreover, EGO-1 and GLD-1 act in parallel to ensure germline health. Finally, the size and distribution of nuclear pore complexes and perinuclear P granules are altered in the absence of EGO-1, effects that disrupt germ cell biology per se and probably limit germline growth.     

Targeting Homologous Recombination in Notch-Driven C. elegans Stem Cell and Human Tumors

Mammalian NOTCH1-4 receptors are all associated with human malignancy, although exact roles remain enigmatic. Here we employ glp-1(ar202), a temperature-sensitive gain-of-function C. elegans NOTCH mutant, to delineate NOTCH-driven tumor responses to radiotherapy. At ≤20°C, glp-1(ar202) is wild-type, whereas at 25°C it forms a germline stem cell⁄progenitor cell tumor reminiscent of human cancer. We identify a NOTCH tumor phenotype in which all tumor cells traffic rapidly to G2⁄M post-irradiation, attempt to repair DNA strand breaks exclusively via homology-driven repair, and when this fails die by mitotic death. Homology-driven repair inactivation is dramatically radiosensitizing. We show that these concepts translate directly to human cancer models.     

Translational repression of a C. elegans Notch mRNA by the STAR/KH domain protein GLD-1

In C. elegans, the Notch receptor GLP-1 is localized within the germline and early embryo by translational control of glp-1 mRNA. RNA elements in the glp-1 3'untranslated region (3' UTR) are necessary for repression of glp-1 translation in germ cells, and for localization of translation to anterior cells of the early embryo. The direct regulators of glp-1 mRNA are not known. Here, we show that a 34 nucleotide region of the glp-1 3' UTR contains two regulatory elements, an element that represses translation in germ cells and posterior cells of the early embryo, and an element that inhibits repressor activity to promote translation in the embryo. Furthermore, we show that the STAR/KH domain protein GLD-1 binds directly and specifically to the repressor element. Depletion of GLD-1 activity by RNA interference causes loss of endogenous glp-1 mRNA repression in early meiotic germ cells, and in posterior cells of the early embryo. Therefore, GLD-1 is a direct repressor of glp-1 translation at two developmental stages. These results suggest a new function for GLD-1 in regulating early embryonic asymmetry. Furthermore, these observations indicate that precise control of GLD-1 activity by other regulatory factors is important to localize this Notch receptor, and contributes to the spatial organization of Notch signaling.     

Identification of novel cis-regulatory regions from the Notch receptor genes lin-12 and glp-1 of Caenorhabditis elegans

Notch signaling regulates various cellular processes such as growth, proliferation and differentiation, and plays a key role in tissue patterning during animal development. In humans, defects in Notch signaling have been implicated in cancer, stroke, neurodegeneration, as well as learning and memory deficits. The genome of the nematode Caenorhabditis elegans encodes two members of the Notch transmembrane receptor family, LIN-12 and GLP-1, which have both unique and shared developmental functions. LIN-12 affects diverse cell fate specification events at certain embryonic and larval stages, including the ABplp lineage (a neuronal precursor), intestinal primordium, gonadal anchor cell and secondary vulval precursor cells. In addition to developmental functions, it also operates in the adult nervous system to control locomotion, memory and chemosensory response. Although lin-12 expression was subjected to intense analysis, it was almost not demonstrable in neurons; occasional lin-12 expression was detected only in the two RIG interneurons of young larvae. Here we identify two cis-regulatory regions from lin-12, both of them are specified by the presence of a conserved EXD/HOX composite binding site. One of these regions is located in the first intron and required for driving transgene expression in vulval precursor cell lineages and specific gonadal cells. The other region is located in the second intron and can confer neuronal expression for lin-12 throughout life. The latter regulatory element is highly conserved in the paralogous glp-1 genomic environment, suggesting redundant developmental and physiological roles for the two Notch paralogs in the C. elegans nervous system.     

Intragenic Dominant Suppressors of Glp-1, a Gene Essential for Cell-Signaling in Caenorhabditis Elegans, Support a Role for Cdc10/Sw16/Ankyrin Motifs in Glp-1 Function

The glp-1 gene product mediates cell-cell interactions required for cell fate specification during development in Caenorhabditis elegans. To identify genes that interact with glp-1, we screened for dominant suppressors of two temperature-sensitive glp-1 alleles and recovered 18 mutations that suppress both germline and embryonic glp-1 phenotypes. These dominant suppressors are tightly linked to glp-1 and do not bypass the requirement for a distal tip cell, which is thought to be the source of a signal that is received and transduced by the GLP-1 protein. Using single-strand conformation polymorphism (SSCP) analysis and DNA sequencing, we found that at least 17 suppressors are second-site intragenic revertants. The suppressors, like the original glp-1(ts) mutations, are all located in the cdc10/SWI6/ankyrin domain of GLP-1. cdc10/SWI6/ankyrin motifs have been shown to mediate specific protein-protein interactions in other polypeptides. We propose that the glp-1(ts) mutations disrupt contact between GLP-1 and an as yet unidentified target protein(s) and that the dominant suppressor mutations restore appropriate protein-protein interactions.     

Age-associated and tissue-specific decline in autophagic activity in the nematode C. elegans

Macroautophagy/autophagy is a cellular recycling process that is required for the extended life span observed in many longevity paradigms, including in the nematode C. elegans. However, little is known regarding the spatiotemporal changes in autophagic activity in such long-lived mutants as well as in wild-type animals during normal aging. In a recent study, we report that autophagic activity decreases with age in several major tissues of wild-type C. elegans, including the intestine, body-wall muscle, pharynx, and nerve-ring neurons. Moreover, long-lived daf-2/insulin-signaling mutants and glp-1/Notch receptor mutants display increased autophagic activity, yet with different time- and tissue-specific differences. Notably, the intestine appears to be a critical tissue in which autophagy contributes to longevity in glp-1, but not in daf-2 mutants. Our findings indicate that autophagic degradation is reduced with age, possibly with distinct kinetics in different tissues, and that long-lived mutants increase autophagy in a tissue-specific manner, resulting in increased life span.     

Roles of CUP-5, the <Emphasis Type="Italic">Caenorhabditis elegans</Emphasis> orthologue of human TRPML1, in lysosome and gut granule biogenesis

Background  

CUP-5 is a Transient Receptor Potential protein in C. elegans that is the orthologue of mammalian TRPML1. Loss of TRPML1 results in the lysosomal storage disorder Mucolipidosis type IV. Loss of CUP-5 results in embryonic lethality and the accumulation of enlarged yolk granules in developing intestinal cells. The embryonic lethality of cup-5 mutants is rescued by mutations in mrp-4, which is required for gut granule differentiation. Gut granules are intestine-specific lysosome-related organelles that accumulate birefringent material. This link between CUP-5 and gut granules led us to determine the roles of CUP-5 in lysosome and gut granule biogenesis in developing intestinal cells.     

FBF-1 and FBF-2 regulate the size of the mitotic region in the C. elegans germline

In the C. elegans germline, GLP-1/Notch signaling and two nearly identical RNA binding proteins, FBF-1 and FBF-2, promote proliferation. Here, we show that the fbf-1 and fbf-2 genes are largely redundant for promoting mitosis but that they have opposite roles in fine-tuning the size of the mitotic region. The mitotic region is smaller than normal in fbf-1 mutants but larger than normal in fbf-2 mutants. Consistent with gene-specific roles, fbf-2 expression is limited to the distal germline, while fbf-1 expression is broader. The fbf-2 gene, but apparently not fbf-1, is controlled by GLP-1/Notch signaling, and the abundance of FBF-1 and FBF-2 proteins is limited by reciprocal 3'UTR repression. We propose that the divergent fbf genes and their regulatory subnetwork enable a precise control over size of the mitotic region. Therefore, fbf-1 and fbf-2 provide a paradigm for how recently duplicated genes can diverge to fine-tune patterning during animal development.     

Identification of genes that interact with glp-1, a gene required for inductive cell interactions in Caenorhabditis elegans

The glp-1 gene functions in two inductive cellular interactions and in development of the embryonic hypodermis of C. elegans. We have isolated six mutations as recessive suppressors of temperature-sensitive (ts) mutations of glp-1. By mapping and complementation tests, we found that these suppressors are mutations of known dumpy (dpy) genes; dpy genes are required for development of normal body shape. Based on this result, we asked whether mutations previously isolated in screens for mutants defective in body shape could also suppress glp-1(ts). From these tests, we learned that unselected mutations of eight genes required for normal C. elegans morphogenesis, including the four already identified, suppress glp-1(ts). All of these suppressors rescue all three mutant phenotypes of glp-1(ts) (defects in embryonic induction of pharyngeal tissue, in embryonic hypodermis development, and in induction of germline proliferation). However, they do not rescue putative glp-1 null mutants and therefore do not bypass the requirement for glp-1 in development. In the light of current ideas about the molecular nature of the glp-1 and suppressor gene products, we propose an interaction between the glp-1 protein and components of the extracellular matrix and speculate that this interaction may impose spatial constraints on the decision between mitosis and meiosis in the germline.