Cho CE et al. (2016) Elife "Parallel encoding of sensory history and behavioral preference during Caenorhabditis elegans olfactory learning."

L'Etoile ND, Cho CE, Bargmann CI, Brueggemann C

[Elife, 2016]

Sensory experience modifies behavior through both associative and non-associative learning. In Caenorhabditis elegans, pairing odor with food deprivation results in aversive olfactory learning, and pairing odor with food results in appetitive learning. Aversive learning requires nuclear translocation of the cGMP-dependent protein kinase EGL-4 in AWC olfactory neurons and an insulin signal from AIA interneurons. Here we show that the activity of neurons including AIA is acutely required during aversive, but not appetitive, learning. The AIA circuit and AGE-1, an insulin-regulated PI3 kinase, signal to AWC to drive nuclear enrichment of EGL-4 during conditioning. Odor exposure shifts the AWC dynamic range to higher odor concentrations regardless of food pairing or the AIA circuit, whereas AWC coupling to motor circuits is oppositely regulated by aversive and appetitive learning. These results suggest that non-associative sensory adaptation in AWC encodes odor history, while associative behavioral preference is encoded by altered AWC synaptic activity.

Mullen GP et al. (2007) Genetics "Choline transport and de novo choline synthesis support acetylcholine biosynthesis in Caenorhabditis elegans cholinergic neurons."

Osborne JD, Frisby DL, Duke A, Mathews EA, Grundahl K, Rand JB, Crowell JA, Mullen GP, Vu MH, Hunter JW

[Genetics, 2007]

The cho-1 gene in C. elegans encodes a high-affinity plasma membrane choline transporter believed to be rate limiting for acetylcholine (ACh) synthesis in cholinergic nerve terminals. We found that CHO-1 is expressed in most, but not all cholinergic neurons in C. elegans. cho-1 null mutants are viable, but exhibit mild deficits in cholinergic behavior: they are slightly resistant to the acetylcholinesterase inhibitor aldicarb, and they exhibit reduced swimming rates in liquid. cho-1 mutants also fail to sustain swimming behavior: over a 33-minute time course, cho-1 mutants slow down or stop swimming, whereas wild-type animals sustain the initial rate of swimming over the duration of the experiment. A functional CHO-1::GFP fusion protein rescues these cho-1 mutant phenotypes, and is enriched at cholinergic synapses. Although cho-1 mutants clearly exhibit defects in cholinergic behaviors, the loss of cho-1 function has surprisingly mild effects on cholinergic neurotransmission. However, reducing endogenous choline synthesis strongly enhances the phenotype of cho-1 mutants, giving rise to a synthetic uncoordinated phenotype. Our results indicate that both choline transport and de novo synthesis provide choline for acetylcholine synthesis in C. elegans cholinergic neurons.

Inoue T et al. (1997) Arch Biochem Biophys "Caenorhabditis elegans has two isozymic forms, CE-1 and CE-2, of fructose-1,6-bisphosphate aldolase which are encoded by different genes."

Takasaki Y, Inoue T, Nikoh N, Miyata T, Hori K, Kusakabe T, Yatsuki H, Joh K

[Arch Biochem Biophys, 1997]

Two distinct types of cDNAs for fructose-1,6-bisphosphate (FBP) aldolase, Ce-1 and Ce-2, have been isolated from nematode Caenorhabditis elegans, and the respective recombinant aldolase isozymes, CE-1 and CE-2, have been purified and characterized. The Ce-1 and Ce-2 are 1282 and 1248 bp in total length, respectively, and both have an open reading frame of 1098 bp, which encodes 366 amino acid residues. The entire amino acid sequences deduced from Ce-1 and Ce-2 show a high degree of identity to one another and to those of vertebrate and invertebrate aldolases. The highest sequence diversity was found in the carboxyl-terminal region that corresponds to one of the isozyme group-specific sequences of vertebrate aldolase isozymes that play a role in determining isozyme-specific functions. Southern blot analysis suggests that CE-1 and CE-2 are encoded by different genes. Concerning general or kinetic properties, CE-2 is quite different from CE-1. CE-1 exhibits unique characteristics which are not identical to any aldolase isozymes previously reported, whereas CE-2 is similar to vertebrate aldolase C. These results suggest that CE-2 might preserve the properties of a progenitor aldolase with a moderate preference for FBP over fructose 1-phosphate (F1P) as a substrate, whereas CE-1 evolved to act as an intrinsic enzyme that exhibits a much broader substrate specificity than dose CE-2.

Angelo RG et al. (2000) J Biol Chem "Characterization of structural features that mediate the tethering of Caenorhabditis elegans protein kinase A to a novel A kinase anchor protein. Insights into the anchoring of PKAI isoforms."

Angelo RG, Rubin CS

[J Biol Chem, 2000]

Caenorhabditis elegans protein kinase A (PKAI(CE)) is tethered to organelles in vivo. A unique A kinase anchor protein (AKAP(CE)) avidly binds the RI-like regulatory subunits (R(CE)) of PKAI(CE) and stringently discriminates against RIIalpha and RIIbeta subunits, the preferred ligands for classical AKAPs. We elucidated structural features that stabilize AKAP(CE).R(CE) complexes and confer atypical R isoform specificity on the anchor protein. Three large aliphatic amino acids (Leu(236), Ile(248), and Leu(252)) in the tethering domain of AKAP(CE) (residues 236-255) are crucial for ligation of R(CE). Their side chains apparently generate a precisely configured hydrophobic binding pocket that accommodates an apolar surface on R(CE) dimers. Basic residues (His(254)-Arg(255)-Lys(256)) at the C terminus of the tethering site set an upper limit on affinity for R(CE.) A central dipeptide (Phe(243)-Ser(244)) contributes critical and distinctive properties of the tethering site. Ser(244) is essential for selective binding of R(CE) and exclusion of RII isoforms. The aromatic hydrophobic character of Phe(243) ensures maximal R(CE) binding activity, thereby supporting a "gatekeeper" function of Ser(244). Substitution of Phe(243)-Ser(244) with Leu-Val generated an RII-specific AKAP. R(CE) and RII subunits contain similar dimerization domains. AKAP-binding domains of R(CE) (residues 23-47) and RII differ markedly in size, amino acid sequence, and docking specificity. Four hydrophobic residues (Cys(23), Val(27), Ile(32), and Cys(44)) in R(CE) are crucial for avid binding with AKAP(CE), whereas side chains from Leu(20), Leu(35), Val(36), Ile(40), and Ile(41) have little impact on complex formation. Tyr(26) is embedded in the docking domain, but its aromatic ring is required for R(CE)-R(CE) dimerization. Residues 236-255 in AKAP(CE) also constitute a binding site for mammalian RIalpha. RIalpha (PKAIalpha) is tightly sequestered by AKAP(CE) in vitro (K(D) = approximately 10 nM) and in the environment of intact cells. The tethering domain of AKAP(CE) provides a molecular module for manipulating intracellular localization of RI and elucidating functions of anchored PKAI in eukaryotes.

Liu J et al. (2003) Proc Natl Acad Sci U S A "MAN1 and emerin have overlapping function(s) essential for chromosome segregation and cell division in Caenorhabditis elegans."

Gruenbaum Y, Neufeld E, Lee KK, Wilson KL, Liu J, Segura-Totten M

[Proc Natl Acad Sci U S A, 2003]

Emerin and MAN1 are LEM domain-containing integral membrane proteins of the vertebrate nuclear envelope. The function of MAN1 is unknown, whereas emerin is known to interact with nuclear lamins, barrier-to-auto integration factor (BAF), nesprin-1alpha, and a transcription repressor. Mutations in emerin cause X-linked recessive Emery-Dreifuss muscular dystrophy. Emerin and MAN1 homologs are both conserved in Caenorhabditis elegans, but loss of Ce-emerin has no detectable phenotype. We therefore used C elegans to test the hypothesis that Ce-MAN1 overlaps functionally with Ce-emerin. Supporting this model, Ce-MAN1 interacted directly with Ce-lamin and Ce-BAF in vitro and required Ce-lamin for its nuclear envelope localization. Interestingly, RNA interference-mediated removal of approximate to90% of Ce-MAN1 was lethal to approximate to15% of embryos. However, in the absence of Ce-emerin, approximate to90% reduction of Ce-MAN1 was lethal to all embryos by the 100-cell stage, with a phenotype involving repeated cycles of anaphase chromosome bridging and cytokinesis ["cell untimely torn" (cut) phenotype]. Immunostaining showed that the anaphase-bridged chromatin specifically retained a mitosis-specific phosphohistone H3 epitope and failed to recruit detectable Ce-lamin or Ce-BAF. These findings show that LEM domain proteins are essential for cell division and that Ce-emerin and Ce-MAN1 share at least one and possibly multiple overlapping functions, which may be relevant to Emery-Dreifuss muscular

Margalit A et al. (2005) Proc Natl Acad Sci U S A "Barrier-to-autointegration factor is required to segregate and enclose chromosomes within the nuclear envelope and assemble the nuclear lamina."

Segura-Totten M, Gruenbaum Y, Margalit A, Wilson KL

[Proc Natl Acad Sci U S A, 2005]

Barrier-to-autointegration factor (BAF) binds dsDNA, LEM-domain proteins, and lamins. Caenorhabditis elegans BAF requires Ce-lamin and two LEM-domain proteins (Ce-emerin and Ce-MAN1) to localize during nuclear assembly. It was unknown whether Ce-lamin and LEM proteins, in turn, depend on Ce-BAF (mutually dependent structural roles). RNA interference-mediated down-regulation of Ce-BAF caused gross defects in chromosome segregation, chromatin decondensation, and mitotic progression as early as the two-cell stage, and embryos died at the approximately 100-cell stage. Nuclear pores reassembled, whereas Ce-lamin, Ce-emerin, and Ce-MAN1 bound chromatin but remained patchy and disorganized. The nuclear membranes formed but failed to enclose anaphase-bridged chromatin. Time-lapse imaging showed two phenotypes: anaphase-bridged chromatin that eventually resolved, and segregated chromatin that returned to the midzone. Thus, the assembly of BAF, lamins, and LEM-domain proteins is mutually dependent, and is required to capture segregated chromosomes within the nascent nuclear envelope. Embryos that escaped lethality by down-regulation of Ce-BAF grew into sterile adults with misplaced distal tip cells and gonads, further suggesting that mild postembryonic reductions in BAF disrupt tissue-specific functions.

Rossbach LM et al. (2022) Environ Sci Technol "Synchrotron XRF Analysis Identifies Cerium Accumulation Colocalized with Pharyngeal Deformities in CeO2 NP-Exposed Caenorhabditis elegans."

Brede DA, Olsson RMS, Janssens K, Lind OC, Rossbach LM, Oughton DH, Falkenberg G, Cagno S, Nuyts G

[Environ Sci Technol, 2022]

A combination of synchrotron radiation-based elemental imaging, in vivo redox status analysis, histology, and toxic responses was used to investigate the uptake, biodistribution, and adverse effects of Ce nanoparticles (CeO2 NP; 10 nm; 0.5-34.96 mg Ce L-1) or Ce(NO3)3 (2.3-26 mg Ce L-1) in Caenorhabditis elegans. Elemental mapping of the exposed nematodes revealed Ce uptake in the alimentary canal prior to depuration. Retention of CeO2 NPs was low compared to that of Ce(NO3)3 in depurated individuals. X-ray fluorescence (XRF) mapping showed that Ce translocation was confined to the pharyngeal valve and foregut. Ce(NO3)3 exposure significantly decreased growth, fertility, and reproduction, caused slightly reduced fecundity. XRF mapping and histological analysis revealed severe tissue deformities colocalized with retained Ce surrounding the pharyngeal valve. Both forms of Ce activated the sod-1 antioxidant defense, particularly in the pharynx, whereas no significant effects on the cellular redox balance were identified. The CeO2 NP-induced deformities did not appear to impair the pharyngeal function or feeding ability as growth effects were restricted to Ce(NO3)3 exposure. The results demonstrate the utility of integrated submicron-resolution SR-based XRF elemental mapping of tissue-specific distribution and adverse effect analysis to obtain robust toxicological evaluations of metal-containing contaminants.

Kamikura DM et al. (2003) Genes Dev "Lipoprotein receptors and a disabled family cytoplasmic adaptor protein regulate EGL-17/FGF export in C. elegans."

Cooper JA, Kamikura DM

[Genes Dev, 2003]

Growth factors and morphogens need to be secreted to act on distant cells during development and in response to injury. Here, we report evidence that efficient export of a fibroblast growth factor (FGF), EGL-17, from the Caenorhabditis elegans developing vulva requires the lipoprotein receptor-related proteins Ce-LRP-1 and Ce-LRP-2 and a cytoplasmic adaptor protein, Ce-DAB-1 (Disabled). Lipoprotein receptors are transmembrane proteins best known for their roles in endocytosis. Ce-LRP-1 and Ce-LRP-2 possess a conserved intraluminal domain that can bind to EGL-17, as well as a cytosolic FXNPXY motif that can bind to Ce-DAB-1. Ce-DAB-1 contains signals that confer subcellular localization to Golgi-proximal vesicles. These results suggest a model in which Ce-DAB-1 coordinates selection of receptors and cargo, including EGL-17, for transport through the secretory pathway.

Agulnik SI et al. (1997) Genome "Three novel T-box genes in Caenorhabditis elegans."

Ruvinsky I, Agulnik SI, Silver LM

[Genome, 1997]

The T-box gene family consists of members that share a unique DNA binding domain. The best characterized T-box gene, Brachyury or T, encodes a transcription factor that plays an important role in early vertebrate development. Seven other recently described mouse T-box genes are also expressed during development. In the nematode Caenorhabditis elegans, four T-box genes have been characterized to date. In this study, we describe three new C. elegans T-box genes, named Ce-tbx-11, Ce-tbx-12, and Ce-tbx-17. Ce-tbx-11 and Ce-tbx-17 were uncovered through the sequencing efforts of the C. elegans Genome Project. Ce-tbx-12 was uncovered through degenerate PCR analysis of C. elegans genomic DNA. Ce-tbx-11 and Ce-tbx-17 are located in close proximity to the four other previously described T-box genes in the central region of chromosome III. In contrast, Ce-tbx-12 maps alone to chromosome II. Phylogenetic analysis of all known T-box domain sequences provides evidence of an ancient origin for this gene family.

Slice LW et al. (1990) J Biol Chem "Purification, characterization, and cDNA cloning of a novel metallothionein-like, cadmium-binding protein from Caenorhabditis elegans."

Slice LW, Rubin CS, Freedman JH

[J Biol Chem, 1990]

Caenorhabditis elegans adapted for survival in high concentrations of Cd(II) express a heavy metal binding protein designated C. elegans metallothionein-like protein or MT-Ce. This protein was purified to homogeneity and characterized. MT-Ce binds 6 mol of Cd(II)/mol protein. The sequence of 39 amino-terminal residues in MT-Ce was determined. A radiolabeled 41-mer oligonucleotide, designed from the partial MT-Ce sequence, was used in conjunction with sucrose gradient centrifugation to obtain size-fractionated poly(A+) RNA enriched in MT-Ce sequences. Subsequently, cloned cDNAs, corresponding to MT-Ce mRNA sequences, were isolated from a lambda ZapII cDNA library prepared from the enriched template mRNA. cDNA and protein sequence analysis revealed that MT-Ce comprises 62 amino acid residues and has a predicted Mr of 6462. Seventeen of the 18 Cys residues in the nematode cadmium-binding protein are included in Cys-X-Cys and X-Cys-Cys-X motifs that are characteristic of mammalian metallothioneins (MTs). However, the resemblance of MT-Ce to mammalian MTs is superficial. The amino acid sequence of MT-Ce is unique, and neither its putative alpha and beta domains nor its Cys residues can be readily aligned with the corresponding regions of other eukaryotic MTs. This suggests that MT-Ce is an example of convergent evolution. The MT-Ce mRNA level in nematodes that were selected and grown with Cd(II) concentrations that are lethal for wild-type worms, was 55-fold higher than the level of MT-Ce mRNA in wild-type C. elegans. Comparison of the sequences of MT-Ce cDNAs revealed the occurrence of two types of MT-Ce mRNA. Each contains an identical coding region, but the cDNAs diverge markedly in their 5'-untranslated regions. This suggests the possibilities of regulation by alternative splicing and/or the presence of multiple MT-Ce genes encoding a single protein, but controlled by different regulatory elements.