The sarco-endoplasmic reticulum Ca2+ ATPase is required for development and muscle function in Caenorhabditis elegans.

The sarco-endoplasmic reticulum Ca(2+)-transport ATPase (SERCA) loads intracellular releasable Ca(2+) stores by transporting cytosolic Ca(2+) into the endoplasmic (ER) or sarcoplasmic reticulum (SR). We characterized the only SERCA homologue of the nematode Caenorhabditis elegans, which is encoded by the sca-1 gene. The sca-1 transcript is alternatively spliced in a similar mode as the vertebrate SERCA2 transcript, giving rise to two protein variants: CeSERCAa and CeSERCAb. These proteins showed structural and functional conservation to the vertebrate SERCA2a/b proteins. The CeSERCAs were primarily expressed in contractile tissues. Loss of CeSERCA through gene ablation or RNA interference resulted in contractile dysfunctioning and in early larval or embryonic lethality, respectively. Similar defects could be induced pharmacologically using the SERCA-specific inhibitor thapsigargin, which bound CeSERCA at a conserved site. The conservation of SERCA2 homologues in C. elegans will allow genetic and chemical suppressor analyses to identify promising drug targets and lead molecules for treatment of SERCA-related diseases such as heart disease.

Two neuronal G proteins are involved in chemosensation of the Caenorhabditis elegans Dauer-inducing pheromone.

Caenorhabditis elegans uses chemosensation to determine its course of development. Young larvae can arrest as dauer larvae in response to increasing population density, which they measure by a nematodeexcreted pheromone, and decreasing food supply. Dauer larvae can resume development in response to a decrease in pheromone and increase in food concentration. We show here that two novel G protein alpha subunits (GPA-2 and GPA-3) show promoter activity in subsets of chemosensory neurons and are involved in the decision to form dauer larvae primarily through the response to dauer pheromone. Dominant activating mutations in these G proteins result in constitutive, pheromone-independent dauer formation, whereas inactivation results in reduced sensitivity to pheromone, and, under certain conditions, an alteration in the response to food. Interactions between gpa-2, gpa-3 and other genes controlling dauer formation suggest that these G proteins may act in parallel to regulate the neuronal decision making that precedes dauer formation.

G proteins are required for spatial orientation of early cell cleavages in C. elegans embryos.

Heterotrimeric G proteins are signal-transducing molecules activated by seven transmembrane domain receptors. In C. elegans, gpb-1 encodes the sole Gbeta subunit; therefore, its inactivation should affect all heterotrimeric G protein signaling. When maternal but no zygotic gpb-1 protein (GPB-1) is present, development proceeds until the first larval stage, but these larvae show little muscle activity and die soon after hatching. When, however, the maternal contribution of GPB-1 is also reduced, spindle orientations in early cell divisions are randomized. Cell positions in these embryos are consequently abnormal, and the embryos die with the normal number of cells and well-differentiated but abnormally distributed tissues. These results indicate that maternal G proteins are important for orientation of early cell division axes, possibly by coupling a membrane signal to centrosome position.

Target-selected gene inactivation in Caenorhabditis elegans by using a frozen transposon insertion mutant bank.

To understand how genotype determines the phenotype of the animal Caenorhabditis elegans, one ideally needs to know the complete sequence of the genome and the contribution of genes to phenotype, which requires an efficient strategy for reverse genetics. We here report that the Tc1 transposon induces frequent deletions of flanking DNA, apparently resulting from Tc1 excision followed by imprecise DNA repair. We use this to inactivate genes in two steps. (i) We established a frozen library of 5000 nematode lines mutagenized by Tc1 insertion, from which insertion mutants of genes of interest can be recovered. Their address within the library is determined by PCR. (ii) Animals are then screened, again by PCR, to detect derivatives in which Tc1 and 1000-2000 base pairs of flanking DNA are deleted, and thus a gene of interest is inactivated. We have thus far isolated Tc1 insertions in 16 different genes and obtained deletion derivatives of 6 of those.

Conserved genes encode guide RNAs in mitochondria of Crithidia fasciculata.

RNA editing is the post-transcriptional alteration of the nucleotide sequence of RNA, which in trypanosome mitochondria is characterized by the insertion and deletion of uridine residues. It has recently been proposed that the information for the sequence alteration in Leishmania tarentolae is provided by small guide (g) RNAs encoded in the mitochondrial DNA [Blum et al. (1990) Cell, 60, 189-198]. We are studying the mechanism of RNA editing in the insect trypanosome Crithidia fasciculata and report that: (i) a full length, conventional DNA gene or an independently replicating RNA gene that could encode the edited MURF3 transcript is absent when probed for in sensitive, calibrated assay systems; (ii) in all cases (seven) investigated in C. fasciculata so far, putative gRNA genes are found in a position in the mitochondrial DNA virtually identical to that in L. tarentolae and (iii) also in C. fasciculata, the putative gRNA genes are transcribed into small RNAs with discrete 5' ends. These results provide strong evolutionary evidence in support of the participation of gRNAs in RNA editing. Remarkably, in C. fasciculata the basepaired region of some putative gRNA:mRNA hybrids contains a C:A non-Watson-Crick basepair.