Characterization of the Ryanodine Receptor Gene With a Unique 3'-UTR and Alternative Splice Site From the Oriental Fruit Moth.

The ryanodine receptor (RyR), the largest calcium channel protein, has been studied because of its key roles in calcium signaling in cells. Insect RyRs are molecular targets for novel diamide insecticides. The target has been focused widely because of the diamides with high activity against lepidopterous pests and safety for nontarget organisms. To study our understanding of effects of diamides on RyR, we cloned the RyR gene from the oriental fruit moth, Grapholita molesta, which is the most serious pest of stone and pome tree fruits throughout the world, to investigate the modulation of diamide insecticides on RyR mRNA expression in G. molesta (GmRyR). The full-length cDNAs of GmRyR contain a unique 3'-UTR with 625 bp and an open reading frame of 15,402 bp with a predicted protein consisting of 5,133 amino acids. GmRyR possessed a high level of overall amino acid homology with insect and vertebrate isoforms, with 77-92% and 45-47% identity, respectively. Furthermore, five alternative splice sites were identified in GmRyR. Diagnostic PCR showed that the inclusion frequency of one optional exon (f) differed between developmental stages, a finding only found in GmRyR. The lowest expression level of GmRyR mRNA was in larvae, the highest was in male pupae, and the relative expression level in male pupae was 25.67 times higher than that of in larvae. The expression level of GmRyR in the male pupae was 8.70 times higher than in female pupae, and that in male adults was 5.70 times higher than female adults.

In cultured chick embryo fibroblasts the hexose transport components are not the 75 000 and 95 000 dalton polypeptides synthesized following glucose deprivation.

Glucose deprivation of chick embryo fibroblasts results in a cycloheximide-sensitive stimulation of hexose transport and an increase in the levels of glucose-regulated polypeptides of molecular weights 75 000 and 95 000. The relationship between these two phenomena is evaluated in this study. The glucose deprivation-induced stimulation of hexose transport was observed to occur in two phases: a rapid (complete by 15 min) cycloheximide-insensitive increase of 50-100% and a slower (observable by 6 h) cycloheximide-sensitive increase in transport to about five times the basal level. The time course of the latter increase preceded that of the appearance of the 75 000 and 95 000 dalton polypeptides; by the time that increases in the levels of these polypeptides were observed, the hexose uptake rates had almost reached their maximum value. Upon cellular fractionation, the greatest enrichment of the 75 000 and 95 000 dalton polypeptides was observed in the endoplasmic reticulum fraction, which was devoid of vesicular stereospecific D-glucose uptake activity. The plasma membrane fraction was enriched in stereospecific D-glucose uptake activity. The plasma membrane fraction was enriched in stereospecific D-glucose uptake activity but not in the 75 000 and 95 000 dalton polypeptides. The glucose deprivation-induced increase in hexose uptake was not prevented by tunicamycin, although this inhibitor of protein glycosylation decreased the hexose uptake of glucose-fed cells by 80% after 24 h. However, under these latter conditions an increase in the levels of the 75 000 and 95 000 dalton polypeptides was observed. On the basis of this data, we conclude that the polypeptides of molecular weights 75 000 and 95 000 are not involved in glucose transport.