Lipid metabolism of caddisfly larvae at low pH

The influence of low pH (5.0 and 4.0) on lipid metabolism of caddisworms Hydropsyche contubernalis L. (Trichoptera) was studied in 48 h toxicity experiments. The results were correlated with lipid composition of caddisworms directly isolated from natural water. Phospholipids, cholesterol, mono-, di-, triacylglycerols, and fatty acids were detected by thin-layer and liquid chromatography. Minimal environmental changes were shown to initiate the biochemical adaptation mechanisms strengthening the cellular membranes through their condensation due to additional phospholipid and cholesterol synthesis. In the natural medium the adaptation processes are more active than in the artificial medium. More serious changes, such as pH decrease to 4.0, suppress the adaptation processes in the first medium and terminated them in the second one.     

Carbohydrate metabolism in starved fifth instar larvae of Manduca sexta

The influence of starvation on carbohydrate metabolism in fifth instar larvae of Manduca sexta was studied. The percentage of active fat body glycogen phosphorylase increased from 10% to approximately 50% within 3 h of starvation; afterward the enzyme was slowly inactivated. The increase of phosphorylase activity might have been caused by a peptide(s) from the CC. The amount of fat body glycogen in starved animals decreased over 24 h by approximately 20 mg. The released glucose molecules seem to be converted mainly to trehalose because the hemolymph trehalose concentration in starved animals was always slightly higher than in the fed controls, and the glucose concentration decreased even when phosphorylase was activated. The chitosan content in starved larvae increased during the first 9 h of treatment to the same extent as in fed controls. It is suggested that fat body glycogen phosphorylase was activated during starvation to provide substrates for chitin synthesis and energy metabolism.     

Diabetic larvae and obese flies-emerging studies of metabolism in Drosophila

The past few years have seen a shift in the use of Drosophila, from studies of growth and development toward genetic characterization of carbohydrate, sterol, and lipid metabolism. This research, reviewed below, establishes a new foundation for using this simple genetic model system to define the basic regulatory mechanisms that underlie metabolic homeostasis and holds the promise of providing new insights into the causes and treatments of critical human disorders such as diabetes and obesity.     

Energy metabolism in eggs and larvae of the Senegal sole

Oxygen consumption in Solea senegalensis increased during the egg stage reaching values close to 4 nmol O₂ ind⁻¹ at hatching. After hatching, larval oxygen consumption continued to increase, reaching a maximum rate of 9.97⁻¹±87 nmol O₂ ind⁻¹ h⁻¹ 2 days after the opening of the mouth. Body nitrogen content decreased mainly after exhaustion of yolk reserves. Carbon content decreased during the whole endogenous feeding phase, although it decreased twice as quickly after yolk-sac absorption. The free amino acid (FAA) depletion rate was higher during egg development and the yolk-sac period. Complete yolk absorption coincided with the consumption of the 90% of initial FAA content in the eggs and the remaining FAA were consumed at a lower rate. Based on stoichiometrical calculations, FAA appears to be the most important energy substrate during the egg stage (86%) in the Senegal sole. During the period from hatching to the mouth opening, contributions of FAA and lipids as metabolic fuels were similar (41 and 47%, respectively). The decrease in larval protein content during starvation indicates that amino acids from body protein are used as energy substrates under food deprivation.     

Adipokinetic hormone controls lipid metabolism in adults and carbohydrate metabolism in larvae of Manduca sexta

The peptide hormone which controls activation of fat body glycogen phosphorylase in starving larvae of Manduca sexta was isolated from larval corpora cardiaca and sequenced by FAB tandem mass spectrometry. It was found to be identical with Manduca AKH. This, together with earlier observations, demonstrates that in M. sexta AKH controls glycogen phosphorylase activation in starving larvae while in adults it controls lipid mobilization during flight. Larval corpora cardiaca contain about 10 times less AKH than the corpora cardiaca of adults. The corpora cardiaca of M. sexta appear to contain only one AKH.     

Regulation of glutamine metabolism during the development of Bombyx mori larvae

Waste ammonia is re-assimilated into amino acids via the amide group of glutamine and the amino group of glutamate (i.e. through glutamine synthetase/glutamate synthase pathway) for silk synthesis in the silkworm, Bombyx mori, in the last larval stadium. Glutamine concentration in hemolymph gradually decreased with the progress of the fifth instar and it remained at very low levels during the spinning stage, then followed by a sharp increase at the larval-pupal ecdysis. The changes in glutamine synthetase (GS) activity in silkworm tissues were relatively small through the larval development, while the changes in glutamate synthase (GOGAT) activity, especially in the posterior silk glands, were more drastic. In addition, activities of GOGAT in the tissues were much higher than those of the other enzymes involved in glutamine utilization, suggesting that glutamine pool was regulated mainly by the changes in GOGAT activity. Western blot analysis indicated that the changes in GOGAT protein level correlated with the changes in GOGAT activity. Topical application of a juvenile hormone analogue, methoprene, induced an accumulation of glutamine in the hemolymph of the fifth instar larvae. The levels of GOGAT protein and activity in the tissues of the methoprene treated larvae were much lower than those of the control larvae, whereas the methoprene treatment had no effect on the levels of GS activity. In conclusion, GOGAT expression promoted by reduction of juvenile hormone titer is quite important for enhanced utilization of nitrogen for synthesis of silk protein during the last larval instar.     

The anaerobic metabolism of the larvae of the midge Chaoborus crystallinus

In third and fourth instar larvae of the midge Chaoborus crystallinus the concentrations of various metabolites were estimated during anoxia and in the course of recovery from anaerobiosis. The glycogen reserves were found to be unusually low, whereas malate is present in quantities exceeding those of total glucans. Under anoxic conditions the concentration of malate drops rapidly and, concomitantly, the level of succinate rises in a reciprocal manner. In addition, large quantities of alanine are accumulated, while lactate is produced as a minor end product. During recovery from anaerobiosis the concentrations of malate and succinate are restored to the values of normoxia within less than 3 hr. In contrast, alanine and lactate decrease rather slowly and are still substantially higher than normal after 12 hr. The possible significance of malate utilization by the larvae in relation to the demands of their normal conditions of life is discussed.     

Female dimorphism in honey-bee larvae with respect to glucose metabolism

The rate of conversion of glucose-1-¹⁴C and glucose-6-¹⁴C to ¹⁴CO₂ and lipid was monitored in queen and worker larvae between 48 and 96 hr of age. A definite dimorphism in glucose metabolism between castes was established. Worker larvae 72 hr of age have a much greater $\text{C}{}_6\text{C}{}_1$ ratio than do queen larvae of the same age. The ratios were of the same order of magnitude for both castes of larvae younger or older than 72 hr. Queen larvae were shown to have a greater rate of lipid synthesis than worker larvae.     

The involvement of catalase in alcohol metabolism in Drosophila melanogaster larvae

The involvement of catalase (H2O2:H2O2 oxidoreductase, EC 1.11.1.6) in the metabolism of alcohols was investigated by comparing Drosophila melanogaster larvae in which catalase was inhibited by dietary 3-amino-1,2,4-triazole (3AT) to larvae fed a diet without 3AT. 3AT inhibited up to 80% of the catalase activity with concordant small increases in the in vitro activities of sn-glycerol-3-phosphate dehydrogenase, fumarase, and malic enzyme, but with a 16% reduction in the in vivo incorporation of label from [14C]glucose into lipid. When the catalase activity was inhibited to different degrees in ADH-null larvae, there was a simple linear correlation between the catalase activity and flux from [14C]ethanol into lipid. By feeding alcohols simultaneously with 3AT, ethanol and methanol were shown to react efficiently with catalase in wild-type larvae at moderately low dietary concentrations. Drosophila catalase did not react with other longer chain alcohols. Catalase apparently represents a minor pathway for ethanol degradation in D. melanogaster larvae, but it may be an important route for methanol elimination from D. melanogaster larvae.     

Chitin-bound protein of sarcophagid larvae: metabolism of covalently linked aromatic constituents

The borate-insoluble chitin-protein complex, CB-I, from prepupal sarcophagid larvae was cleaved with chymotrypsin and trifluoromethanesulfonic acid releasing a polypeptide fragment of Mr 68 000. The intact glycoprotein was blocked at the C terminus; the N-terminal sequence of Asp-Val-Ala-His-Tyr was not homologous with seven of the borate-soluble nonglycosylated structural proteins. Bityrosine was identified as a component of the primary chain, both half-residues occupied in peptide linkages. Sclerotization initiated a decline in bityrosine coincident with the addition of soluble proteins to the tanned matrix. The chitin-protein complex also included bound peroxidase, propolyphenol oxidase, and an o-diphenol subject to oxidation on activation of the zymogen. In the course of the oxidation N termini declined in accordance with the formation of 1,4 quinonoid cross-links.