Vidal-Gadea A G et al. (2010) Neuronal Development, Synaptic Function and Behavior, Madison, WI "Biogenic amines mediate transition between crawling and swimming in C. elegans"

Brauner M, Gottschalk A, Erbguth K, Kressin L, Vidal-Gadea A G, Topper S, Young L, Pierce-Shimomura J T

[Neuronal Development, Synaptic Function and Behavior, Madison, WI, 2010]

A wide variety of animals must quickly adjust their pattern of locomotion to successfully navigate through different environmental niches. Selection and execution of the appropriate locomotory pattern is therefore paramount to survival. Although C. elegans is capable of performing many adaptive behaviors, it has been controversial whether forward crawling and swimming represent distinct gait-like forms of locomotion or the modulation of a single form of locomotion [1-3]. Biogenic amines have been shown to mediate the transition between gait-like forms of locomotion across taxa as diverse as sea slugs, leeches, lampreys and humans. We previously reported that C. elegans crawls and swims with distinct kinematics and different patterns of muscle activity [2]. We now combine quantitative behavioral analysis, optogenetic tools and neuronal ablation to show that C. elegans uses biogenic amines to switch between crawling and swimming in a gait-like manner. As in other invertebrates, we find that serotonin mediates the smooth transition from crawling to swimming in C. elegans. Serotonin is further required to inhibit motor behaviors (e.g. foraging and pharyngeal pumping) during swimming that normally only accompany crawling. Mirroring the role of dopamine in other invertebrates, C. elegans uses dopamine to successfully initiate and maintain crawling when emerging from liquid. Over 600 million years of separate evolution notwithstanding, the highly conserved role played by biogenic amines such as dopamine and serotonin across taxa attests to how vital their function is to adaptive strategies for locomotion. Korta J, Clark DA, Gabel CV, Mahadevan L, Samuel AD. J. Exp. Bio. 2007 210:2383-9.Pierce-Shimomura JT, Chen BL, Mun JJ, Ho R, Sarkis R, McIntire SL. PNAS. 2008 105:20982-7.Berri S, Boyle JH, Tassieri M, Hope IA, Cohen N. HSFP J. 2009 3:186-93.

Topper S et al. (2010) Neuronal Development, Synaptic Function and Behavior, Madison, WI "A Role for Dopamine in Switching Locomotory Patterns in C. elegans"

Young L, Pierce-Shimomura J, Erbguth K, Brauner M, Vidal-Gadea A, Kressin L, Gottschalk A, Topper S

[Neuronal Development, Synaptic Function and Behavior, Madison, WI, 2010]

Humans have the ability to switch smoothly between a wide variety of movement patterns including distinct locomotory gaits. This ability is severely disrupted in certain neurological diseases such as Parkinson's disease which is caused by degeneration of dopamine neurons. We have found that C. elegans displays alternate forms of locomotion; crawling when on firm substrates and swimming when in liquid [1]. Moreover, we examined worm locomotion in different viscosities and found that C. elegans swims at low viscosities, crawls at high viscosities, and continually switches between bouts of crawl- and swim-like motions at intermediate viscosities. This suggests that the worm switches between two distinct forms of locomotion. To investigate a potential role for dopamine in this switching, we examined how activation of dopamine neurons with channelrhodopsin2 (ChR2) affected locomotion.ChR2 is a light-activated cation channel which depolarizes neurons after stimulation with blue light. Activation of dopamine neurons was sufficient to induce a switch from swimming to crawl-like behavior. Application of exogenous dopamine to swimming worms also induced bouts of crawl-like behavior suggesting that dopamine alone acts as a chemical switch sufficient to initiate crawling. Exogenous application of serotonin, which is known to encourage swimming behavior in other species [2], significantly reduced the probability of switching to crawl-like behavior during dopaminergic activation. Lastly, we also have found that ablation of dopamine neurons specifically perturbs the worm's ability to switch from swimming to crawling. Dopamine has been previously implicated in reducing the rate of crawling in the basal-slowing response [3]. Consistent with this, we found that activation of dopamine neurons in animals crawling on unseeded plates induced a transition to a slower form of crawling. This suggests that dopamine can induce context-dependent changes in locomotory patterns. The fact that dopamine is both necessary and sufficient for the swim to crawl transition suggests that C. elegans can be used to model the abnormal motor switching in human Parkinson's disease. Further investigations should shed light on the fundamental neural mechanisms that underlie the switching between distinct patterns of neural activity.1. Pierce-Shimomura JT, Chen BL, Mun JJ, Ho R, Sarkis R, McIntire SL. PNAS. 20082. Friesen WO, Kristan WB.Current Opinion in Neurobiology. 20073. Sawin ER, Ranganathan R, Horvitz HR. Neuron. 2000

Okano H et al. (2000) Japanese Worm Meeting "The SWI/SNF complex is required for asymmetric cell division in C. elegans"

Kouike H, Sawa H, Okano H

[Japanese Worm Meeting, 2000]

In C. elegans, the polarities of many cells undergoing asymmetric divisions are regulated by LIN-44/Wnt and LIN-17/Frizzled. To identify more genes required for asymmetric division, we are screening for mutants affecting the asymmetric division of the T cell in the tail that is regulated by lin-17 and lin-44. We have so far identified 17 new mutants corresponding to 13 different genes. Lineage analyses have shown that the T cell division can be symmetric in mutants of at least 7 of the genes (psa-1 through psa-7). Using temperature-sensitiveness of the psa-1 and psa-4 mutant, we found that these genes are required during the mitosis of the T cell. We have cloned psa-1 and psa-4 to found that they encode homologs of SWI3 and SWI2 of yeast, respectively. These proteins are known to be components of the complex called SWI/SNF. The complex can remodel chromatin structure by destabilizing histone-DNA interaction. These results suggest that the chromatin structure is altered by the SWI/SNF complex in one of the daughter cells during the T cell division. In budding yeast, the SWI/SNF complex is required for the asymmetric expression of HO endonuclease in the mother but not in the daughter cell. HO catalyzes switching of the mating types in the mother cell. Therefore, our findings demonstrate that at least some aspects of the mechanisms of asymmetric cell division are conserved between yeast and a multicellular organism.

Williams, Kyle C. et al. (2011) International Worm Meeting "Essential Functions of IFA-2 Domains in C. elegans Fibrous Organelles."

Plenefisch, John, Williams, Kyle C.

[International Worm Meeting, 2011]

The C. elegans fibrous organelle (FO) complex consists of apical and basal hemidesmosomes linked by cytoplasmic intermediate filaments (IFs). FOs are found most prominently in the epidermis where they overlie body wall muscle and serve to transmit force from the muscle to the cuticle. IFA-2, one of four epidermally expressed IFs whose loss results in epidermal fragility and failure of muscle-cuticle force transmission, localizes to FOs. Unlike IFB-1 and IFA-3 that are required embryonically, IFA-2, although expressed in the embryo, is not essential for FO function until postembryonic stages. This distinctive phenotype allows us to specifically explore the functions of IFA-2 domains, and map their interactions with other FO associated proteins. All IFs contain three domains: a central rod domain and globular head and tail domains. The rod is essential for assembly of IFs into mature filaments while less is known about the functions of the head and tail domains. Roles of the head and tail domains of IFA-2 were examined by expressing GFP-tagged IFA-2 variants in transgenic animals and examining their phenotype and localization in wild-type and null backgrounds. Mutant variants included IFA-2 deleted for the head domain (DH), deleted for the tail domain (DT), deleted for both (RO), and variants that contained only the head domain (HO) or tail domain (TO). The expression and function of DH is virtually indistinguishable from full-length IFA-2. DT results in a lowered incorporation of IFA-2 into FOs and is unable to rescue a null allele of ifa-2, suggesting the tail domain is essential to IFA-2 function. Though both HO and TO are expressed well in the hypodermis at all stages, incorporation into FOs is variable between individual animals. High levels of early-stage HO incorporation into FOs correlate with a dominant-negative muscle detachment phenotype, while low-level incorporation results in healthy animals. This suggests the head domain interacts with FO components essential to tissue integrity. To determine the protein components of the FOs that interact with the head and tail domains, yeast two-hybrid and co-localization experiments are in progress. This work should help to elucidate the role of IFA-2 in FO function and reveal the underlying defects leading to tissue fragility.

Rand JB et al. (2000) East Coast Worm Meeting "UNC-13 in the C. elegans Nervous System"

Kohn RE, Rand JB, McManus JR, Moulder GL, Duke A, Barstead RJ, Duerr JS

[East Coast Worm Meeting, 2000]

C. elegans unc-13 and its homologues in vertebrates and Drosophila are involved in neurotransmitter release. UNC-13 has several regions homologous to PKC regulatory domains; these domains confer it with calcium, phorbol ester and phospholipid binding properties (Maruyama and Brenner, PNAS 88, 1991). A 5.9kb transcript coding for a 200kDa protein was initially identified (now designated L-R for left and right regions). We have identified two additional types of transcripts. One transcript includes a 1kb novel exon (L-M-R, M for middle region) and another transcript lacks the 5' region included in the other two transcripts (M-R). All three transcripts are identical at the 3' end (R). C. elegans with mutations in the 5' end of the gene (L) alter two types of transcripts (L-R and L-M-R) resulting in an uncoordinated coily phenotype and resistance to the anti-cholinesterease, aldicarb. A 2.7kb deletion near the 3' end (R) (identified by Bob Barstead using PCR analysis) affects all unc-13 transcripts and results in a lethal phenotype. Antibodies recognizing the N-terminal region of UNC-13 (L) label synapses, but not synaptic vesicles, of most or all neurons; many mutations in L and R remove staining with this antibody. Supported by grants from the NIH and OCAST.

Abergel, Z. et al. (2017) International Worm Meeting "Adaptation of the nematode C. elegans to hypoxia and reoxygenation stress reveals an unexpected function of the neuroglobin GLB-5 in innate immunity."

Zuckerman, B., Zelmanovich, V., Abergel, Z., Abergel, R., Gross, E., Smith, Y., Romero, L., Livshits, L.

[International Worm Meeting, 2017]

Deprivation of oxygen (hypoxia) followed by reoxygenation (H/R stress) is a major component in several pathological conditions such as vascular inflammation, myocardial ischemia, and stroke. However how animals adapt and recover from H/R stress remains an open question. Previous studies showed that the neuroglobin GLB-5(Haw) is essential for the fast recovery of the nematode Caenorhabditis elegans (C. elegans) from H/R stress. Here, we characterize the changes in neuronal gene expression during the adaptation of worms to hypoxia and recovery from H/R stress. Our analysis shows that innate immunity genes are differentially expressed during both adaptation to hypoxia and recovery from reoxygenation stress. Moreover, we reveal that the prolyl hydroxylase EGL-9, a known regulator of both adaptation to hypoxia and the innate immune response, inhibits the fast recovery from H/R stress through its activity in the O2-sensing neurons AQR, PQR, and URX. Finally, we show that GLB-5(Haw) acts in AQR, PQR, and URX to increase the tolerance of worms to bacterial pathogenesis. Together, our studies suggest that innate immunity and recovery from H/R stress are regulated by overlapping signaling pathways.

A V Bicknell et al. (2002) European Worm Meeting "The C. elegans F47F2.1 gene encodes a cyclic AMP-dependent protein kinase (PK-A) catalytic subunit"

A V Bicknell, M J Fisher, M Tabish, R A Clegg, H H Rees

[European Worm Meeting, 2002]

PK-A mediates all known effects of cyclic AMP on cellular activity in eukaryotes. The holoenzyme is an inactive tetramer of two regulatory (R) subunits and two catalytic (C) subunits. Following binding of cyclic AMP to the R subunits, dissociation of active C-subunits occurs. In mammals, , and isoforms of C-subunit, encoded by different genes, have been identified.

Angelo RG et al. (1997) International C. elegans Meeting "DISCOVERY OF A POTENTIAL ANCHOR/SCAFFOLD PROTEIN FOR C. ELEGANS PROTEIN KINASE A (PKA)"

Angelo RG, Rubin CS

[International C. elegans Meeting, 1997]

C. elegans PKA is composed exclusively of catalytic and regulatory (R) subunits encoded by the kin-1 and kin-2 genes. Since C. elegans lacks other PKA isoforms, this enzyme must disseminate signals carried by cAMP to all cell compartments. Approximately 60% of total R (PKA) is in the particulate fraction of disrupted C. elegans, indicating that protein/protein interactions may diversify PKA signaling by anchoring the kinase at specific intracellular locations. Co-localization of PKA with upstream activators and/or downstream effectors can create target sites for cAMP action. To understand the mechanism of PKA localization in C. elegans, a cDNA expression library was screened with recombinant radiolabeled-R (0.5 nM) to obtain high-affinity binding proteins. A cDNA encoding a novel, 143 kDa A kinase anchor protein (AKAP1) was retrieved and sequenced. The corresponding gene (rap-1) is located in LGII and contains 17 exons. AKAP1 is an acidic protein (pI=4.4) that is unrelated to previously characterized proteins. C. elegans R is avidly bound by both soluble and immobilized fragments of AKAP1. Competition binding studies indicate that C. elegans R is a preferred ligand, whereas mammalian RII and RI isoforms are only weakly sequestered. Scatchard analysis yielded a Kd value of ~10 nM for the R/AKAP1 complex. Deletion mutagenesis, coupled with protein expression in E. coli and in vitro assays, demonstrated that residues 235 to 255 govern high-affinity binding of R by AKAP1. A hydrophobic surface generated by amino acids with branched aliphatic side chains may be a key determinant of R binding activity. Site directed mutagenesis will pinpoint essential residues involved in PKA binding. Studies aimed at identifying the AKAP1 binding site on R are also in progress. High-affinity anti-AKAP1 IgGs are being used to determine (a) whether AKAP1 expression is developmentally-regulated and cell- specific and (b) the relationship between R (PKA) and AKAP1 in vivo.

Hicks, Tara et al. (2021) International Worm Meeting "R-loop-induced irreparable DNA damage in C. elegans meiosis"

Hicks, Tara, Koury, Emily, Williams, Cameron, Smolikove, Sarit

[International Worm Meeting, 2021]

Most DNA-RNA hybrids are formed naturally during transcription and are composed of a nascent RNA strand hybridized to DNA as part of R-loops. The accumulation of these structures in S-phase can result in replication-transcription conflict, an outcome which can lead to the formation of double strand breaks (DSBs). While R-loops' role in mitotically dividing cells has been characterized, there are only a handful of studies describing the effect of R-loops in meiosis and these studies present a complex picture of the outcome of R-loop formation on germ cells. Here we show that DSBs formed by R-loops trigger an altered cellular response to DNA damage. RNase H is an enzyme responsible for degradation of the RNA strand in DNA-RNA hybrids and plays an essential role in preventing this outcome and its deleterious consequences. Using null mutants for the two Caenorhabditis elegans genes encoding for RNase H1 and RNase H2 (hereby rnh mutants), our studies explore the effects of replication stress-induced DNA-RNA hybrid accumulation on meiosis. As expected, rnh mutants exhibit an increase in R-loop formation. Consequently, an elevation of DSBs in germline nuclei is evidenced by the accumulation of RAD-51 foci. Despite no repair mechanism abrogation, rnh mutants fail to repair all DSBs generated, leading to a fragmentation of chromosomes in diakinesis oocytes. By combining our double mutant with a spo-11 null mutation, we show that although replicative defects are the main contributor to the phenotype, R-loops formed in meiosis are likely contributors as well. We present evidence that while rnh mutants accumulate DNA-RNA hybrids and subsequent DSBs may signal a degree of checkpoint activation in mitosis, some damaged nuclei prevail past the checkpoint, enter into meiosis, and remain unrepaired throughout. Moreover, we find no evidence of an increase in apoptosis, which indicates that DNA damage generated by R-loops remain undetected by an apoptotic checkpoint. This data altogether points to DSBs initiated by R-loops representing an irreparable type of DNA damage that evades cellular machineries designed for damage recognition.

Cao, Jianfeng et al. (2021) International Worm Meeting "Establishment of a morphological atlas of the Caenorhabditis elegans embryo using deep-learning-based 4D segmentation"

Yan, Hong, Zhao, Zhongying, Tang, Chao, Chan, Lu-Yan, Guan, Guoye, Cao, Jianfeng, Wong, Ming-Kin, Ho, Vincy Wing Sze

[International Worm Meeting, 2021]

The invariant development and transparent body of the nematode Caenorhabditis elegans enables complete delineation of cell lineages throughout development. Despite extensive studies of cell division, cell migration and cell fate differentiation, cell morphology during development has not yet been systematically characterized in any metazoan, including C. elegans. This knowledge gap substantially hampers many studies in both developmental and cell biology. Here we report an automatic pipeline, CShaper, which combines automated segmentation of fluorescently labeled membranes with automated cell lineage tracing. We apply this pipeline to quantify morphological parameters of densely packed cells in 17 developing C. elegans embryos. Consequently, we generate a time-lapse 3D atlas of cell morphology for the C. elegans embryo from the 4- to 350-cell stages, including cell shape, volume, surface area, migration, nucleus position and cell-cell contact with resolved cell identities. We anticipate that CShaper and the morphological atlas will stimulate and enhance further studies in the fields of developmental biology, cell biology and biomechanics (Cao†, Guan†, Ho†, et al. Nat. Commun., 2020, 11: 6254).