Gopal E et al. (2015) J Pharmacol Exp Ther "Species-specific influence of lithium on the activity of SLC13A5 (NaCT): lithium-induced activation is specific for the transporter in primates."

Ganapathy V, Ramachandran S, Gopal E, Babu E, Prasad PD, Bhutia YD

[J Pharmacol Exp Ther, 2015]

NaCT (SLC13A5) is a Na(+)-coupled transporter for Krebs cycle intermediates and is expressed predominantly in the liver. Human NaCT is relatively specific for citrate compared with other Krebs cycle intermediates. The transport activity of human NaCT is stimulated by Li(+), whereas that of rat NaCT is inhibited by Li(+). We studied the influence of Li(+) on NaCTs cloned from eight different species. Li(+) stimulated the activity of only NaCTs from primates (human, chimpanzee, and monkey); by contrast, NaCTs from nonprimate species (mouse, rat, dog, and zebrafish) were inhibited by Li(+). Caenorhabditis elegans NaCT was not affected by Li(+). With human NaCT, the Li(+)-induced increase in transport activity was associated with the conversion of the transporter from a low-affinity/high-capacity type to a high-affinity/low-capacity type. H(+) was able to substitute for Li(+) in eliciting the stimulatory effect. The amino acid Phe500 in human NaCT was critical for Li(+)/H(+)-induced stimulation. Mutation of this amino acid to tryptophan (F500W) markedly increased the basal transport activity of human NaCT in the absence of Li(+), but the ability of Li(+) to stimulate the transporter was almost completely lost with this mutant. Substitution of Phe500 with tryptophan in human NaCT converted the transporter from a low-affinity/high-capacity type to a high-affinity/low-capacity type, an effect similar to that of Li(+) on the wild-type NaCT. These studies show that Li(+)-induced activation of NaCT is specific for the transporter in primates and that the region surrounding Phe500 in primate NaCTs is important for the Li(+) effect.

Tabuse Y (1997) International C. elegans Meeting "LITHIUM CAUSES DEVELOPMENTAL DISORDER IN C. ELEGANS"

Tabuse Y

[International C. elegans Meeting, 1997]

Lithium (Li) has long been known to have teratogenic effects on the development of many organisms, including sea urchin, Xenopus and Dictyostelium. In Li-treated Xenopus embryos, ventral blastmeres are respecified to develop into dorsal structures, leading to dorsalized embryos lacking ventral mesodermal tissues. In Dictyostelium, Li alters the fate of prespore cells to become prestalk cells instead. Besides teratogenic effects, Li is also known to be a most effective treatment of manic-depressive illness.!@Although several models have been proposed to explain Li action, the molecular mechanism has remained unclear. Recently, GSK (glycogen synthase kinase)-3b was proposed to be a target of Li, suggesting that Li affects the wnt signaling pathway. To understand the mechanism of Li action, I first examined the effect of Li on C. elegans embryogenesis. I inoculated N2 animals at the late L4 stage onto NG plates containing 20 mM LiCl, incubated them at 20 oC. The number of eggs produced by treated animals was reduced to about half of the untreated control. Although cell division seemed to proceed, no embryos hatched on Li plates. Treated-embryos developed to produce gut granules, but did not execute normal morphogenesis at later embryonic stages. To identify genes involved in the action of Li, I have begun to screen for Li-resistant mutants that propagated on Li-containing medium. Several mutants were isolated, and one of them was mapped on the left side of unc-42 on chromosome V. On Li plates, the hatching rate of mutant eggs cross-fertilized by wild-type males was essentially the same as that for self-fertilized mutant eggs. On the contrary, no wild-type eggs cross-fertilized by mutant males hatched on Li-containing plates. So, this mutation appeared to be maternal. Further genetic analyses of the mutants and the observation on the cellular phenotype of Li-treated embryos are underway.

Tabuse Y (1996) Worm Breeder's Gazette "Lithium arrests embryonic development of C. elegans"

Tabuse Y

[Worm Breeder's Gazette, 1996]

Lithium (Li) has long been known to have teratogenic effects on the development of many organisms, including sea urchin, Xenopus and Dictyostelium. In Li-treated Xenopus embryos, ventral blastmeres are respecified to develop into dorsal structures, leading to dorsalized embryos lacking ventral mesodermal tissues. In Dictyostelium, Li alters the fate of prespore cells to become prestalk cells instead. Besides teratogenic effects, Li is also known to bea most effective treatment of manic-depressive illness. Although several models have been proposed to explain Li action, the molecular mechansm remains unclear. The most widely accepted model is the inositol depletion hypothesis, in which Li is thought to affect inositol phosphate turnover by inhibiting inositol monophosphatase, thus resulting in the depletion of endogenous inositol. To understand the mechanism of Li action, I first examined the effect of Li on C. elegans embryogenesis. I inoculated N2 animals at the late L4 stage onto NG plates containing 20 mM LiCl, incubated them at 20 C and observed the laid embryos. The number of eggs produced by treated animals was reduced to about half of the untreated control. Although cell division seemed to proceed, no embryos hatched on Li plates. Treated-embryos developed to produce gut granules, but did not execute normal morphogenesis at later embryonic stages. To identify genes involved in the action of Li, I have begun to screen for Li-resistant mutants, which propagated on Li-containing medium. So far, I obtained one mutant. The mutation was tentatively assigned to chromosome V. Preliminary genetic analysis showed that the mutation showed maternal effect. On Li plates, the hatching rate of mutant eggs cross-fertilized by wild-type males was essentially the same as that for self-fertilized mutant eggs. On the contrary, no wild-type eggs cross-fertilized by mutant males hatched on Li-containing plates. I am now trying to isolate other mutants and also to identify early defects of embryogenesis caused by lithium treatment. I would like to thank J. Miwa for encouragement and discussions.

Ch'ng Q et al. (2003) Genetics "Identification of genes that regulate a left-right asymmetric neuronal migration in Caenorhabditis elegans."

Lie YS, Williams L, Whangbo J, Kenyon C, Ch'ng Q, Sym M

[Genetics, 2003]

In C. elegans cells of the QL and QR neuroblast lineages migrate with left-right asymmetry; QL and its descendants inigrate posteriorly odiereas QR and its descendants inigrate anteriorly. One kcy step in generating this asymmetry is the expression of the Hox gene mab-5 in the QL descendants but not in the QR descendants. This asymmetry appears to be coupled to the asymmetric polarizations and movements of QL and QR as they migrate and relies on an asymmetric response to an EGL-20/Wnt signal. To identify genes involved in these complex layers of regulation and to isolate targets of mab-5 that direct posterior migrations, we screened visually for mutants with cell migration defects in the QL and QR lineages. Here, we describe a set of new mutants (qid-5, qid-6, qid-7, and qid-8) that primarily disrupt the migrations of the QL descendants. Most of these mutants were defective in mab-5 expression in the QL lineage and might identify genes that interact directly or indirectly with the EGL-20/Wnt signaling

Inokuchi A et al. (2015) J Appl Toxicol "Effects of lithium on growth, maturation, reproduction and gene expression in the nematode Caenorhabditis elegans."

Matsusaki H, Yamamoto R, Takumi S, Morita F, Inokuchi A, Arizono K, Tominaga N, Ishibashi H

[J Appl Toxicol, 2015]

Lithium (Li) has been widely used to treat bipolar disorder, and industrial use of Li has been increasing; thus, environmental pollution and ecological impacts of Li have become a concern. This study was conducted to clarify the potential biological effects of LiCl and Li(2)CO(3) on a nematode, Caenorhabditis elegans as a model system for evaluating soil contaminated with Li. Exposure of C. elegans to LiCl and Li(2)CO(3) decreased growth/maturation and reproduction. The lowest observed effect concentrations for growth, maturation and reproduction were 1250, 313 and 10 000m, respectively, for LiCl and 750, 750 and 3000m, respectively, for Li(2)CO(3). We also investigated the physiological function of LiCl and LiCO(3) in C. elegans using DNA microarray analysis as an eco-toxicogenomic approach. Among approximately 300 unique genes, including metabolic genes, the exposure to 78m LiCl downregulated the expression of 36 cytochrome P450, 16 ABC transporter, 10 glutathione S-transferase, 16 lipid metabolism and two vitellogenin genes. On the other hand, exposure to 375m Li(2)CO(3) downregulated the expression of 11 cytochrome P450, 13 ABC transporter, 13 lipid metabolism and one vitellogenin genes. No gene was upregulated by LiCl or Li(2)CO(3). These results suggest that LiCl and Li(2)CO(3) potentially affect the biological and physiological function in C. elegans associated with alteration of the gene expression such as metabolic genes. Our data also provide experimental support for the utility of toxicogenomics by integrating gene expression profiling into a toxicological study of an environmentally important organism such as C. elegans.

McColl G et al. (2008) J Biol Chem "Pharmacogenetic analysis of lithium-induced delayed aging in Caenorhabditis elegans."

Melov S, McColl G, Lithgow GJ, Vantipalli MC, Killilea DW, Hubbard AE

[J Biol Chem, 2008]

Lithium (Li+) has been used to treat mood affect disorders, including bipolar, for decades (1;2). This drug is neuroprotective and has several identified molecular targets. However, it has a narrow therapeutic range and the underlying mechanism(s) of its therapeutic action is not understood. Here we describe a pharmacogenetic study of Li+ in the nematode Caenorhabditis elegans. Exposure to Li+ at clinically relevant concentrations throughout adulthood increases survival during normal aging (up to 46% median increase). Longevity is extended via a novel mechanism with altered expression of genes encoding nucleosome-associated functions. Li+ treatment results in reduced expression of the worm ortholog of LSD-1 (T08D10.2), a histone demethylase; knockdown by RNA interference (RNAi) of T08D10.2 is sufficient to extend longevity (~25% median increase), suggesting Li+ regulates survival by modulating histone methylation and chromatin structure.

D Royal et al. (2001) International C. elegans Meeting "Towards the Cloning of Gene That Can Mutate to Confer Lithium Resistance In C. elegans"

J White, M Driscoll, E Hsieh, N Sirotin, M A Royal, D Royal, S Kwok, K O'Connell, B Bowerman

[International C. elegans Meeting, 2001]

Little is known about how ions permeate the C. elegans gut and cuticle. How various ions influence development and behavior is also not understood. One ion with considerable impact in human biology is Li + , which modulates bipolar disorder by an unknown mechanism. In particular, the targets of lithium that cause side effects remain to be identified. We are using C. elegans to genetically identify targets of lithium and to elaborate on mechanisms of transport, which may have an impact on human health. Li + has dosage-dependent effects on C. elegans embryos. When L4 animals mature on NGM plates with Li + added to the final concentrations of 10mM-20mM, they produce embryos that are unable to hatch. We demonstrated that this failure to hatch is due to defects in cytokinesis that result in multi-nucleated embryos and symmetrically partitioned cells. Li + also has a dosage-dependent effect on larval development. When adult hermaphrodites are permitted to lay embryos on 10mM-20mM Li + NGM plates, the resulting offspring experience a developmental delay proportional to the concentration of Li + . The offspring become progressively paralyzed as they reach adulthood. We demonstrated earlier that there is a delay in the entry into the S phase of the cell cycle larval stages. To learn more about the biology of Li + sensitivity, we screened for Li + resistant mutants. We developed three screens that took advantage of the embryonic arrest and the larval delay caused by Li + . We isolated one mutant bz71 , in a screen of 44,000 haploid genomes, that is resistant to both the larval and embryonic blocks of 16mM Li + . bz71 is dominant. Using classical mapping techniques, we positioned it on LGIII between unc-32 and dpy-18 . We are currently using SNP strategy to obtain a higher resolution map and we hope to report on the identification and cloning of this locus.

JS Whangbo et al. (1999) International C. elegans Meeting "How the EGL-20/Wnt protein specifies two different migratory behaviors in the Q cell lineage"

CJ Kenyon, JS Whangbo

[International C. elegans Meeting, 1999]

The QL and QR neuroblasts are bilateral homologues that give rise to cells that migrate in opposite directions along the anteroposterior (A/P) body axis. These cells undergo identical division patterns, yet they have opposite migratory behaviors. QL and its descendants migrate posteriorly, whereas QR and its descendants migrate anteriorly. We have investigated the role of a C. elegans Wnt homolog, egl-20 , in regulating these differences. This gene has two very different roles in Q cell migration. First, egl-20 leads to the expression of the Hox gene mab-5 in QL, but not QR. mab-5 then acts as a developmental switch that programs the QL descendants to migrate into the posterior body region. Interestingly, egl-20 has a very different function in the QR lineage, where it promotes migration toward the anterior. How does egl-20 have such different functions in the QL and QR lineages? By examining the expression pattern of a rescuing egl-20 ::GFP fusion, we find that EGL-20 is evenly distributed on the left and right sides of the animal. Thus, the different effects of egl-20 on the QL and QR lineages cannot be caused by left-right asymmetric expression of EGL-20. EGL-20 is expressed only in the posterior body region; however, we find that misexpression of the gene in the anterior (using a myo-2 :: egl-20 -GFP fusion) can fully rescue the Egl-20 mutant phenotype, indicating that its asymmetric localization along the A/P body axis is not responsible for the different effects it has on the QL vs. QR lineages. Finally, we asked whether the response of the QL and QR cells to EGL-20 might be dose dependent . By varying the duration of heat-shock in animals carrying a hs:: egl-20 fusion, we found that it is. High levels of EGL-20 activate mab-5 expression, whereas low levels promote anterior migration. In addition, we found that although EGL-20 is capable of triggering either response in either Q cell, QL is more sensitive than QR. Thus, the ability of EGL-20 to elicit these different responses resides in mechanisms that allow different levels of EGL-20 to initiate different migratory behaviors, as well as mechanisms that make QL and QR sensitive to different levels of EGL-20.

Honigberg LA et al. (1995) International C. elegans Meeting "dpy-19 is required for two early steps in the Q cell migrations."

Honigberg LA, Kenyon CJ

[International C. elegans Meeting, 1995]

We have found that mutations in dpy-19 disrupt two specific aspects of the migrations of the QL and QR neuroblasts and their descendants. The first defect is in the initial migrations of the Q lineages: in wild-type, QL migrates toward the posterior and QR migrates toward the anterior, but in dpy-19 mutants these initial migrations are blocked. Using the clr-1 mutation to reveal the outlines of cells, we see that in wild-type, QL and QR send out extensive processes before migrating -- QL pointing to the posterior and QR to the anterior. In dpy-19 mutants, these processes are shortened, absent, or pointed in the wrong direction. The second defect is in the regulation of the HOX gene mab-5. Following their initial migration, QL and QR divide. In wild-type, QL's daughters start expressing Mab-5, which is then required for them to remain in the posterior, while QR's daughters do not express Mab-5 and migrate towards the anterior. In dpy-19, the QL daughters sometimes fail to express Mab-5 and as expected, sometimes migrate anteriorly. Interestingly, the QR daughters sometimes ectopically express Mab-5 and subsequently remain in the posterior. In the mab-5 dpy-19 double mutant, as in mab-5 alone, the QL and QR descendants always follow the anterior migration pattern. Thus, when Q descendants remain in the posterior in dpy-19, they are doing so because they express Mab-5, not because they are unable to migrate. We are interested in how dpy-19 is involved in these two steps and whether the normal L/R asymmetry in the initial migration might position QL and QR to receive a localized signal that leads to the L/R asymmetry in Mab-5 expression. We are working to clone dpy-19 and have been aided by the identification of the site of a Tc1 insertion in the region in the strain MT3126 mut-2(r459);dpy-19(n1347) (S. Colloms & R. Plasterk).

Sundararajan L et al. (2014) Dev Biol "The fat-like cadherin CDH-4 acts cell-non-autonomously in anterior-posterior neuroblast migration."

Sundararajan L, Schoneich S, Ackley BD, Lundquist EA, Norris ML

[Dev Biol, 2014]

Directed migration of neurons is critical in the normal and pathological development of the brain and central nervous system. In Caenorhabditis elegans, the bilateral Q neuroblasts, QR on the right and QL on the left, migrate anteriorly and posteriorly, respectively. Initial protrusion and migration of the Q neuroblasts is autonomously controlled by the transmembrane proteins UNC-40/DCC, PTP-3/LAR, and MIG-21. As QL migrates posteriorly, it encounters and EGL-20/Wnt signal that induces MAB-5/Hox expression that drives QL descendant posterior migration. QR migrates anteriorly away from EGL-20/Wnt and does not activate MAB-5/Hox, resulting in anterior QR descendant migration. A forward genetic screen for new mutations affecting initial Q migrations identified alleles of cdh-4, which caused defects in both QL and QR directional migration similar to unc-40, ptp-3, and mig-21. Previous studies showed that in QL, PTP-3/LAR and MIG-21 act in a pathway in parallel to UNC-40/DCC to drive posterior QL migration. Here we show genetic evidence that CDH-4 acts in the PTP-3/MIG-21 pathway in parallel to UNC-40/DCC to direct posterior QL migration. In QR, the PTP-3/MIG-21 and UNC-40/DCC pathways mutually inhibit each other, allowing anterior QR migration. We report here that CDH-4 acts in both the PTP-3/MIG-21 and UNC-40/DCC pathways in mutual inhibition in QR, and that CDH-4 acts cell-non-autonomously. Interaction of CDH-4 with UNC-40/DCC in QR but not QL represents an inherent left-right asymmetry in the Q cells, the nature of which is not understood. We conclude that CDH-4 might act as a permissive signal for each Q neuroblast to respond differently to anterior-posterior guidance information based upon inherent left-right asymmetries in the Q neuroblasts.