Liu FZ et al. (1997) Cell Struct Funct "Assemblases and coupling proteins in thick filament assembly."

Barral JM, Bauer CC, Liu FZ, Cook RG, Epstein HF, Schmid DF, Ortiz I

[Cell Struct Funct, 1997]

Thick filaments are stable assemblies of myosin that are characteristic of specific muscle types from both vertebrates and invertebrates. In general, their structure and assembly require remarkably precise determination of lengths and diameters, structural differentiation and nonequivalence of myosins, a high degree of inelasticity and rigidity, and dynamic regulation of assembly and disassembly in response to both extracellular and intracellular signals. Directed assembly of myosin in which additional proteins function in key roles, therefore, is more likely to be significant than the simple self assembly of myosin into thick filaments. The nematode Caenorhabditis elegans permits a wide spectrum of biochemical, genetic, molecular and structural approaches to be applied to the experimental testing of this hypothesis. Biochemical analysis of C. elegans thick filaments reveals that paramyosin, a homologue of the myosin rod that is the unique product of a single genetic locus, exists as two populations which differ by post-translational modification. The major paramyosin species interacts with the two genetically specified myosin heavy chain isoforms. The minor paramyosin species is organized within the cores of the thick filaments, where it is associated stoichiometrically with three recently identified proteins P20, P28 and P30. These proteins have now been characterized molecularly and contain unique, novel amino acid sequences. Structural analysis of the core shows that seven paramyosin subfilaments are crosslinked by additional internal proteins into a highly rigid tubule. P20, P28 and P30 are proposed to couple the paramyosin subfilaments together into the core tubule during filament assembly. Mutants that affect paramyosin assembly are being characterized for alterations in the core proteins. A fourth protein has been identified recently as the product of the unc-45 gene. Computational analysis of this gene's DNA suggests that the predicted protein may exhibit protein phosphatase and chaperone activities. Genetic analysis shows that three classes of specific unc-45 mutant proteins differentially interact with the two myosins during thick filament assembly. The unc-45 protein is proposed to be a myosin assemblase, a protein catalyst of thick filament assembly.

Liu FZ et al. (1997) Biochemistry "Induction of glyoxylate cycle expression in Caenorhabditis elegans: a fasting response throughout larval development."

Epstein HF, Thatcher JD, Liu FZ

[Biochemistry, 1997]

The mRNA and the bifunctional protein for the two glyoxylate cycle (GC) enzymes, isocitrate lyase and malate synthase, are expressed in a tissue- and stage-specific pattern in Caenorhabditis elegans. Since expression of the two enzymes for the carbon-conserving glyoxylate cycle is regulated by the availability of carbon sources in microorganisms, we have studied the bifunctional GCP gene expression under fasting conditions and in certain mutants of C. elegans in order to understand possible mechanisms regulating its expression during nematode development. The GCP mRNA and protein levels were elevated in early larvae which were never fed, a result consistent with previous enzyme activity measurements (Khan, F.R., & McFadden, B.A. (1982) Exp. Parasitol. 54, 48-54]. However, larvae of later stages also expressed higher levels of GCP mRNA and protein when they were shifted from normal to fasting growing conditions. The GCP expression appeared to be regulated primarily at the transcriptional level throughout development. Although the expression of both the GCP gene and lin-14 peaks at about the same time during development and are induced by fasting, the regulation of the GCP gene is independent of the heterochronic lin-14 control mechanism of postembryonic lineages, as demonstrated by the fact that there was no significant change of the GCP at both mRNA and protein levels in the heterochronic lin-4 (lf) and lin-14 (gf) mutants compared to the wild type.

Liu FZ et al. (2000) J Cell Sci "Differential assembly of alpha- and gamma-filagenins into thick filaments in Caenorhabditis elegans."

Hutagalung A, Epstein HF, Liu FZ, Bauer CC, Ortiz I, Cook RG

[J Cell Sci, 2000]

Muscle thick filaments are highly organized supramolecular assemblies of myosin and associated proteins with lengths, diameters and flexural rigidities characteristic of their source. The cores of body wall muscle thick filaments of the nematode Caenorhabditis elegans are tubular structures of paramyosin sub-filaments coupled by filagenins and have been proposed to serve as templates for the assembly of native thick filaments. We have characterized alpha- and gamma-filagenins, two novel proteins of the cores with calculated molecular masses of 30,043 and 19,601 and isoelectric points of 10.52 and 11.49, respectively. Western blot and immunoelectron microscopy using affinity-purified antibodies confirmed that the two proteins are core components. Immunoelectron microscopy of the cores revealed that they assemble with different periodicities. Immunofluorescence microscopy showed that alpha-filagenin is localized in the medial regions of the A-bands of body wall muscle cells whereas gamma-filagenin is localized in the flanking regions, and that alpha-filagenin is expressed in 1.5-twofold embryos while gamma-filagenin becomes detectable only in late vermiform embryos. The expression of both proteins continues throughout later stages of development. C. elegans body wall muscle thick filaments of these developmental stages have distinct lengths. Our results suggest that the differential assembly of alpha- and gamma-filagenins into thick filaments of distinct lengths may be developmentally regulated.

Liu FZ et al. (1998) J Cell Biol "beta-Filagenin, a newly identified protein coassembling with myosin and paramyosin in Caenorhabditis elegans."

Ortiz I, Cook RG, Schmid MF, Liu FZ, Epstein HF, Bauer CC

[J Cell Biol, 1998]

Muscle thick filaments are stable assemblies of myosin and associated proteins whose dimensions are precisely regulated. The mechanisms underlying the stability and regulation of the assembly are not understood. As an approach to these problems, we have studied the core proteins that, together with paramyosin, form the core structure of the thick filament backbone in the nematode Caenorhabditis elegans. We obtained partial peptide sequences from one of the core proteins, beta-filagenin, and then identified a gene that encodes a novel protein of 201-amino acid residues from databases using these sequences. beta-Filagenin has a calculated isoelectric point at 10.61 and a high percentage of aromatic amino acids. Secondary structure algorithms predict that it consists of four beta-strands but no alpha-helices. Western blotting using an affinity-purified antibody showed that beta-filagenin was associated with the cores. beta-Filagenin was localized by immunofluorescence microscopy to the A bands of body-wall muscles, but not the pharynx. beta-filagenin assembled with the myosin homologue paramyosin into the tubular cores of wild-type nematodes at a periodicity matching the 72-nm repeats of paramyosin, as revealed by immunoelectron microscopy. In CB1214 mutants where paramyosin is absent, beta-filagenin assembled with myosin to form abnormal tubular filaments with a periodicity identical to wild type. These results verify that beta-filagenin is a core protein that coassembles with either myosin or paramyosin in C. elegans to form tubular filaments.

Liu FZ et al. (1995) Dev Biol "Bifunctional glyoxylate cycle protein of Caenorhabditis elegans: a developmentally regulated protein of intestine and muscle."

Liu FZ, Epstein HF, Thatcher JD, Barral JM

[Dev Biol, 1995]

The reaction of an abundant 106-kDa polypeptide with a specific monoclonal antibody has been localized in intestinal and muscle cells of the nematode Caenorhabditis elegans. This protein was first detected in 4-6 cells of the clonal E lineage of 100-cell embryos. This lineage is committed to the intestinal cell fate. The antigen continued to be expressed in the differentiating gut and then appeared in early differentiating body wall muscle cells of 400- to 500-cell embryos. Molecular cloning and sequencing showed that the largest cDNA clone contained 3274 bp and encoded a sequence of 1005 amino acids. The predicted polypeptide of 112,799 MW contains separate domains for the glyoxylate cycle enzymes isocitrate lyase and malate synthase. Their enzymatic activities had been shown previously to be highest in embryos and L1 larvae (Khan, F. R., and McFadden, B. A. (1980). FEBS Lett. 115, 312-314; Khan, F. R., and McFadden, B. A. (1982). Exp. Parasitol. 54, 48-54; Wadsworth, W. G., and Riddle, D. L. (1989). Dev. Biol. 132, 167-173). The domain-specific sequences were shown to be contiguous in genomic DNA and are separated by an intron of 68 bp. A single polypeptide and both enzymatic activities are precipitated by the antibody, and peptide fragments resulting from limited proteolytic digestion contained amino acid sequences which overlap the predicted junctional region. The physical localization of the gene correlates with a small region of the left arm of Linkage Group V to which multiple embryonic lethal mutations have been mapped.

Kaplan HS et al. (2018) Neuron "Sensorimotor Integration for Decision Making: How the Worm Steers."

Zimmer M, Kaplan HS

[Neuron, 2018]

Animals' movements actively shape their perception and subsequent decision making. In this issue of Neuron, Liu etal. (2018) show how C.elegans nematodes steer toward an odorant: a dedicated interneuron class integrates oscillatory olfactory signals, generated by head swings, with corollary discharge motor signals.

Ali L et al. (2020) J Cell Biol "Mitochondrial translation, dynamics, and lysosomes combine to extend lifespan."

Ali L, Haynes CM

[J Cell Biol, 2020]

In this issue, Liu et al. (2019. J. Cell. Biol.https://doi.org/10.1083/jcb.201907067) find that the inhibition of mitochondrial ribosomes in combination with impaired mitochondrial fission or fusion increases C. elegans lifespan by activating the transcription factor HLH-30, which promotes lysosomal biogenesis.

Rahmani, Shapour et al. (2021) MicroPubl Biol

Tuck, Simon, Rahmani, Shapour

[MicroPubl Biol, 2021]

C. elegans males that have come into close proximity of hermaphrodites initiate copulatory behavior comprising at least five different steps termed response, turning, location of vulva, spicule insertion and sperm transfer (Loer and Kenyon 1993, Liu and Sternberg 1995, Chute and Srinivasan 2014). Mutations specifically affecting different steps have been isolated and characterized (Barr and Sternberg 1999, Hajdu-Cronin et al. 2017, Liu et al. 2017). However, our understanding of the molecular mechanisms acting in the neurons controlling copulation is far from complete. During the response step, males that have sensed the presence of a hermaphrodite move backwards in such a way that the males tail fan glides along the surface of the hermaphrodite until the tail reaches the vulva (or head or tail) (Loer and Kenyon 1993, Liu and Sternberg 1995, Sherlekar and Lints 2014). Response behavior is regulated by ciliated neurons in the tail whose dendrites lie in sensory rays within the fan (Liu and Sternberg 1995). If a male reaches the end of the hermaphrodite without having found the vulva, it executes a turn during which the tail bends tightly ventrally so that contact is established between the ventral surface of the fan and the other side of the intended mate (Loer and Kenyon 1993, Liu and Sternberg 1995). The ability to execute turns efficiently is dependent upon serotonergic neurons in the posterior ventral nerve cord (the CP neurons) and on their ability to produce serotonin (Loer and Kenyon 1993, Carnell et al. 2005). Serotonin stimulates the diagonal muscles in the tail to induce curling ventrally by stimulating a serotonin receptor, SER-1 (Loer and Kenyon 1993, Carnell et al. 2005). However, how serotonin affects diagonal muscles and ventral turning is not fully understood.

Kidd AR et al. (2015) PLoS One "The C. elegans Chp/Wrch Ortholog CHW-1 Contributes to LIN-18/Ryk and LIN-17/Frizzled Signaling in Cell Polarity."

Cox AD, Reiner DJ, Muniz-Medina V, Der CJ, Kidd AR

[PLoS One, 2015]

Wnt signaling controls various aspects of developmental and cell biology, as well as contributing to certain cancers. Expression of the human Rho family small GTPase Wrch/RhoU is regulated by Wnt signaling, and Wrch and its paralog Chp/RhoV are both implicated in oncogenic transformation and regulation of cytoskeletal dynamics. We performed developmental genetic analysis of the single Caenorhabditis elegans ortholog of Chp and Wrch, CHW-1. Using a transgenic assay of the distal tip cell migration, we found that wild-type CHW-1 is likely to be partially constitutively active and that we can alter ectopic CHW-1-dependent migration phenotypes with mutations predicted to increase or decrease intrinsic GTP hydrolysis rate. The vulval P7.p polarity decision balances multiple antagonistic Wnt signals, and also uses different types of Wnt signaling. Previously described cooperative Wnt receptors LIN-17/Frizzled and LIN-18/Ryk orient P7.p posteriorly, with LIN-17/Fz contributing approximately two-thirds of polarizing activity. CHW-1 deletion appears to equalize the contributions of these two receptors. We hypothesize that CHW-1 increases LIN-17/Fz activity at the expense of LIN-18/Ryk, thus making the contribution of these signals unequal. For P7.p to polarize correctly and form a proper vulva, LIN-17/Fz and LIN-18/Ryk antagonize other Wnt transmembrane systems VANG-1/VanGogh and CAM-1/Ror. Our genetic data suggest that LIN-17/Fz represses both VANG-1/VanGogh and CAM-1/Ror, while LIN-18/Ryk represses only VANG-1. These data expand our knowledge of a sophisticated signaling network to control P7.p polarity, and suggests that CHW-1 can alter ligand gradients or receptor priorities in the system.

Hisamoto N et al. (2021) J Neurosci "CDK14 promotes axon regeneration by regulating the non-canonical Wnt signaling pathway in a kinase-independent manner."

Hanafusa H, Hisamoto N, Li C, Sakai Y, Ohta K, Shimizu T, Matsumoto K

[J Neurosci, 2021]

The post-injury regenerative capacity of neurons is known to be mediated by a complex interaction of intrinsic regenerative pathways and external cues. In Caenorhabditis elegans, the initiation of axon regeneration is regulated by the non-muscle myosin light chain (MLC-4) phosphorylation signaling pathway. In this study, we have identified svh-16/cdk-14, a mammalian CDK14 homolog, as a positive regulator of axon regeneration in motor neurons. We then isolated the CDK-14-binding protein MIG-5/Disheveled (Dsh) and found that EGL-20/Wnt and the MIG-1/Frizzled receptor (Fz) are required for efficient axon regeneration. Further, we demonstrate that CDK-14 activates EPHX-1, the C. elegans homolog of the mammalian ephexin Rho-type GTPase guanine nucleotide-exchange factor (GEF), in a kinase-independent manner. EPHX-1 functions as a GEF for the CDC-42 GTPase, inhibiting myosin phosphatase, which maintains MLC-4 phosphorylation. These results suggest that CDK14 activates the RhoGEF-CDC42-MLC phosphorylation axis in a non-canonical Wnt signaling pathway that promotes axon regeneration. Significance Statement:Non-canonical Wnt signaling is mediated by Fz, Dsh, Rho-type GTPase, and non-muscle MLC phosphorylation. This study identified svh-16/cdk-14, which encodes a mammalian CDK14 homolog, as a regulator of axon regeneration in Caenorhabditis elegans motor neurons. We show that CDK-14 binds to MIG-5/Dsh and that EGL-20/Wnt, MIG-1/Fz, and EPHX-1/RhoGEF are required for axon regeneration. The phosphorylation-mimetic MLC-4 suppressed axon regeneration defects in mig-1, cdk-14, and ephx-1 mutants. CDK-14 mediates kinase-independent activation of EPHX-1, which functions as a GEF for CDC-42 GTPase. Activated CDC-42 inactivates myosin phosphatase and thereby maintains MLC phosphorylation. Thus, the non-canonical Wnt signaling pathway controls axon regeneration via the CDK-14-EPHX-1-CDC-42-MLC phosphorylation axis.