L-Canaline Detoxification: A Seed Predator's Biochemical Mechanism.

The seeds of the Neotropical legume, Dioclea megacarpa, the sole food source for developing larvae of the bruchid beetle, Caryedes brasiliensis, contain about 13 percent L-canavanine (dry weight). Canavanine detoxification and utilization produces L-canaline, a potent neurotoxic and insecticidal amino acid. This seed predator has developed a unique biochemical mechanism for degrading canaline by reductive deamination to form homoserine and ammonia. In this way, canaline is detoxified; canavanine's stored nitrogen is more fully utilized and its carbon skeleton is conserved.

A novel means for dealing with L-canavanine, a toxic metabolite.

L-canavanine is a highly toxic L-arginine analog found in some leguminous seeds. Larvae of the bruchid beetle Caryedes brasiliensis, collected in Costa Rica, subsist solely on tissues of the mature seed of Dioclea megacarpa, which contains more than 8 percent L-canavanine by dry weight. The arginyl-tRNA synthetase of the bruchid beetle larvae discriminates between L-arginine and L-canavanine, and canavanyl proteins are not synthesized. In this way, bruchid beetle larvae avoid an adverse biochemical effect of L-canavanine.

Degradation and detoxification of canavanine by a specialized seed predator.

Larvae of the bruchid beetle Caryedes brasiliensis feed exclusively on seeds of the Neotropical legume Dioclea megacarpa, which contains 13 percent L-canavanine by dry weight. L-Canavanine, a nonprotein amino acid analog of L-arginine, exhibits potent insecticidal properties. Most of the seed nitrogen is sequestered in canavanine, and bruchid beetle larvae do not simply excrete this toxic compound. Instead, these larvae possess extraordinarily high urease activity, which facilitates the conversion of canavanine to ammonia through urea. In this way, canavanine is effectively detoxified and a supply of nitrogen for fixation into organic linkage is ensured.

Blood sugar formation due to abnormally elevated gluconeogenesis: aberrant regulation in a parasitized insect, Manduca sexta Linnaeus.

Alterations of carbohydrate metabolism associated with parasitism were examined in an insect, Manduca sexta L. In insect larvae maintained on a low carbohydrate diet gluconeogenesis from [3-13C]alanine was established from the fractional 13C enrichment in trehalose, a disaccharide of glucose and the blood sugar of insects and other invertebrates. After transamination of the isotopically substituted substrate to [3-13C]pyruvate, the latter was carboxylated to oxaloacetate ultimately leading to de novo glucose synthesis and trehalose formation. Trehalose was selectively enriched with 13C at C1 and C6 followed by C2 and C5. 13C enrichment of blood sugar in insects parasitized by Cotesia congregata (Say) was significantly greater than was observed in normal animals. The relative contributions of pyruvate carboxylation and decarboxylation to trehalose labeling were determined from the 13C distribution in glutamine, synthesized as a byproduct of the tricarboxylic acid cycle. The relative contribution of carboxylation was significantly greater in parasitized larvae than in normal insects providing additional evidence of elevated gluconeogenesis due to parasitism. Despite the increased gluconeogenesis in parasitized insects the level of blood sugar was the same in all animals. Because de novo glucose synthesis does not normally maintain blood sugar level in insects maintained under these dietary conditions the findings suggest an aberrant regulation over gluconeogenesis. The 13C labeling in trehalose was nearly symmetric in all insects but the mean C1/C6 13C ratio was higher in parasitized animals suggesting a lower activity of the pentose phosphate pathway that brings about a redistribution of 13C in trehalose following de novo glucose synthesis. Additional studies with insects maintained on a high carbohydrate diet and administered [1,2-13C2]glucose confirmed a decreased level of pentose cycling during parasitism consistent with a lower level of lipogenesis. It is suggested, however, that the pentose pathway may facilitate the synthesis of trehalose from dietary carbohydrate by directing hexose phosphate cycled through the pathway to the production of energy.

Expression and characterization of a novel teratocyte protein of the braconid, Microplitis croceipes (cresson).

Microplitis croceipes wasps overcome host immunity by inducing changes in host physiology using factors derived from the embryo and/or larva. Teratocytes of some parasitic wasps circulate in the host hemolymph after egg hatch and synthesize proteins (TSPs), some of which are secreted to alter host physiology in support of endoparasitoid development. TSPs appear to alter host physiology, at least in part, by inhibiting synthesis of certain proteins. M. croceipes teratocytes synthesize a 13.9 kDa protein (TSP14), which inhibits synthesis of host proteins that are linked to larval growth and development. A cDNA encoding TSP14 was generated by RT-PCR from teratocyte RNA, and cloned into yeast expression vectors to produce sufficient recombinant protein for functional analyses. RecTSP14 was produced using the yeast expression system at a concentration of more than 300 micrograms/L. The recTSP14 inhibited in vitro translation of larval Heliothis virescens RNA, with the activity sensitive to boiling, protein concentration, incubation time, and storage temperatures. Although recTSP14 inhibited translation of some cellular RNAs in vitro, the in vivo incorporation of [35S]-methionine into proteins of selected insect and mammalian cell lines was not inhibited. These findings suggest that recTSP14 entry is cell type-specific and required to inhibit synthesis of target protein(s).

L-Canavanine and protein synthesis in the tobacco hornworm Manduca sexta.

L-Canavanine, a nonprotein amino acid of certain leguminous plants, manifests potent insecticidal properties in a canavanine-sensitive insect such as the tobacco hornworm Manduca sexta (L.) (Sphingidae). This arginine analog is activated and aminoacylated by arginyl-tRNA synthetase and incorporated into nascent polypeptide chains to create structurally aberrant, canavanine-containing proteins. Analysis of incorporation of [3H]leucine into protein in M. sexta larvae that had been injected with canavanine revealed that this arginine analog stimulates protein synthesis. During the first 3 hr after injection of canavanine, canavanine-mediated net stimulation of protein formation was readily discerned. Thereafter, the stimulation of protein synthesis appeared to be offset by the preferential degradation of anomalous proteins. Double-label protein-turnover experiments with larvae injected with [14C]canavanine- and [3H]arginine-containing hemolymph proteins showed that canavanine-containing proteins were degraded preferentially.

Extended in vitro culture of Microplitis croceipes teratocytes and secretion of TSP14 protein.

Teratocytes, cells which originate from the serosal membrane of some Braconidae and Scelionidae, can be found in the hemocoel of permissive hosts during part or all of the developmental time of the parasitoid larva. Teratocytes from Microplitis croceipes are known to secrete biologically active proteins, which contribute to developmental arrest and failure to pupate of Heliothis virescens larvae. One such protein, which has a molecular weight of approximately 14 kDa is called TSP14. The presence of parasitoid larvae is essential to maintain teratocytes under in vitro conditions with protein-free EX-CELL 400. The teratocyte viability was maintained in vitro for at least 12 days in the presence of larvae when medium was exchanged every three days. Western blots show that TSP14 was secreted during the entire period of exchanges. In the absence of parasitoid larvae, teratocyte viability was only 30% by day 6 and no TSP14 had been secreted. In the absence of parasitoid larvae, teratocytes maintained in vitro in EX-CELL 400 medium supplemented with 10% FBS remained viable for at least nine days and secreted TSP14 for at least six days. This suggests that parasitoid larval secretions are sufficient but not uniquely essential to maintain teratocyte viability. Parasitoid larvae maintained in the absence of teratocytes did not secrete TSP14 and their secretory products did not inhibit pupation of H. virescens larvae.

Interaction of L-canaline with ornithine aminotransferase of the tobacco hornworm, Manduca sexta (Sphingidae).

Ornithine aminotransferase (L-ornithine:2-oxo-acid aminotransferase (EC 2.6.1.13)) has been purified to homogeneity from last instar larvae of the tobacco hornworm, Manduca sexta (Sphingidae). This enzyme is a 144,000-Da tetramer constructed from 36,000-Da protomeric units. It has a high aspartate/asparagine and glutamate/glutamine content and 2 cysteine residues/subunit. All 8 cysteine residues can react with N-ethylmaleimide to inactivate the enzyme. Maintenance of the enzyme in the presence of 2-mercaptoethanol and dithiothreitol maximizes enzymatic activity and improves storage conditions, presumably by protecting these sulfhydryl groups. The apparent Km values for L-ornithine and 2-oxoglutaric acid are 2.3 and 3.2 mM, respectively. The turnover number is 2.0 +/- 0.1 mumol min-1 mumol-1. L-Canaline (L-2-amino-4-(aminooxy)butyric acid) is a potent ornithine aminotransferase inhibitor. Reaction of the enzyme with L-[U-14C]canaline produces an enzyme-bound, covalently linked, radiolabeled canaline-pyridoxal phosphate oxime. The L-[U-14C]canaline-pyridoxal phosphate oxime has been isolated from canaline-treated enzyme. Dialysis of canaline-inactivated ornithine aminotransferase against free pyridoxal phosphate slowly reactivates the enzyme as the oxime is replaced by pyridoxal phosphate. Analysis of L-[U-14C]canaline binding to ornithine aminotransferase reveals the presence of 4 mol of pyridoxal phosphate/mol of enzyme.

Studies of L-canavanine incorporation into insectan lysozyme.

L-Canavanine is incorporated into the lysozyme synthesized, in response to administration of bacterial cell wall materials, by canavanine-treated larvae of the tobacco hornworm Manduca sexta (Sphingidae). Maximum canavanine incorporation into M. sexta lysozyme occurs when the larvae are provided 1 mg of canavanine g-1 fresh body weight. Analysis of canavanine-containing lysozyme purified from these insects reveals that 21% of the arginine residues are replaced by canavanine; this residue substitution results in a loss of 49.5% of the catalytic activity. When the larvae are provided 0.5 mg of canavanine g-1, 16.5% of the arginine residues are substituted by canavanine and 39.5% of the catalytic activity is lost. Canavanine is also incorporated into the lysozyme induced by canavanine-treated pupae of the giant silk moth Hyalophora cecropia (Saturnidae). In contrast, replacement of 17% of the arginine in H. cecropia lysozyme by canavanine fails to affect the catalytic activity. We have determined the primary structure of M. sexta lysozyme and compared it with the primary structure of H. cecropia lysozyme which has been described elsewhere. M. sexta lysozyme has an arginine at positions 23, 42, and 107. H. cecropia contains serine, lysine, and lysine, respectively, at these locations. The ability of incorporated canavanine to inhibit M. sexta lysozyme activity selectively may result from the fact that replacement of any one of the 3 arginine residues at position 23, 42, or 107 by canavanine causes the loss of catalytic activity.

Aberrant nutritional regulation of carbohydrate synthesis by parasitized Manduca sexta L.

The present studies confirm that storage carbohydrate synthesis from [1-(13)C]glucose is elevated in Manduca sexta parasitized by Cotesia congregata, despite a decrease in the rate of metabolism of the labeled substrate. Further, the results demonstrate that a similar pattern of carbohydrate synthesis and glucose metabolism was induced in normal larvae by administration of the glycolytic inhibitor, iodoacetate. (13)C enrichment of C6 of trehalose and glycogen demonstrated randomization of the C1 label at the triose phosphate step of the glycolytic/gluconeogenic pathway and suggested that gluconeogenesis, that is, de novo carbohydrate formation, contributed to the synthesis of carbohydrate in both normal and parasitized insects. Accounting for differences in the (13)C enrichment in C1 of trehalose and glycogen due to direct labeling from [1-(13)C]glucose, the mean C6/C1 labeling ratios in trehalose and glycogen of parasitized larvae and insects treated with iodoacetate were greater than the mean ratio observed in normal larvae, suggesting a greater contribution of gluconeogenesis to trehalose labeling in parasitized insects. This conclusion was confirmed by additional investigations on the metabolism of [3-(13)C]alanine by normal and parasitized insects. The pattern of (13)C enrichment in hemolymph trehalose observed in normal larvae maintained on a low carbohydrate diet indicated a large contribution of gluconeogenesis, while gluconeogenesis contributed very little to trehalose labeling in normal insects maintained on a high carbohydrate diet. Parasitized insects maintained on a high or a low carbohydrate diet displayed a significantly greater contribution of gluconeogenesis to trehalose labeling than was observed in normal larvae maintained on the same diets. In conclusion, these investigations indicate that regulation over the utilization of dietary glucose for trehalose and glycogen synthesis as well as the dietary regulation of de novo carbohydrate synthesis were altered by parasitism.

Microplitis croceipes teratocytes: in vitro culture and biological activity of teratocyte secreted protein.

Teratocytes originate from the dissociation of the extraembryonic serosal membrane in some Braconidae and Scelionidae. Methods used to culture teratocytes in vitro are described and the yield of teratocyte secreted proteins (TSP) was measured. Although 90% are viable after 6 days, in vitro teratocytes reached only half the diameter (32&mgr;m) of the same age teratocytes obtained in vivo. Teratocytes cultured in vitro secrete as much as 0.7&mgr;g of protein per day per larval equivalent ( approximately 900 cells). Presence of parasitoid larvae enhanced teratocyte viability while periodic exchange of medium did not. However, medium exchange significantly increased the total amount of protein secreted. Size and viability were improved with the addition of 10% FBS to the Ex-cell 400 culture medium. Non-denaturing PAGE showed at least 15 proteins with molecular sizes estimated to be between 24 to 347kDa in medium containing teratocytes. An in vitro fat body assay was developed to measure the effect of TSP on protein synthesis and juvenile hormone esterase (JHE) activity. Crude TSP inhibited in vitro incorporation of [(35)S]-methionine into protein synthesized by the fat body. The amount of JHE released from in vitro fat body treated with crude TSP was significantly less than controls, most likely caused by the inhibition of general protein synthesis. The active fraction of TSP passed through a 30kDa molecular weight cutoff filter but was retained by a 3kDa filter. SDS-PAGE revealed four proteins with molecular weights between 8 and 20kDa not present in control medium incubated without teratocytes.

Effects of Microplitis croceipes Teratocytes on Host Haemolymph Protein Content and Fat Body Proliferation.

Qualitative and quantitative changes in haemolymph proteins in Heliothis virescens were observed in larvae injected with either Microplitis croceipes teratocytes or teratocyte secreted proteins (TSP). Haemolymph protein titres in hosts receiving either 0.5 or 1 larval equivalent (LE) of teratocytes were similar to those of parasitized larvae, whereas a single injection of 4LE of TSP was required to induce a similar response. SDS-PAGE showed that the 82kDa monomer of riboflavin-binding protein and the 74/76kDa monomers of storage proteins were significantly reduced in parasitized larvae and in nonparasitized larvae treated with TSP. Concentrations of a 155kDa monomer (insectacyanin chromoprotein) also were reduced in parasitized larvae and those injected with either teratocytes or TSP. Two monomers (56 and 60kDa) were unique to parasitized larvae. Treated larvae required several days longer than controls to reach a comparable premetamorphic stage (burrowing-digging). Reductions in fat body proliferation similar to those seen in parasitized larvae were observed in larvae treated with either 1LE of teratocytes, or with 2 or 4LEs of TSP. Perivisceral fat body weights from larvae treated with either 0.25 or 0.5LE of teratocytes were significantly reduced, but less so than those which received 1LE. Thus, fat body proliferation in both teratocyte- and TSP-treated larvae was inhibited in a dose-dependent manner. Both light- and transmission electron microscopy observations revealed cytological differences in fat body tissues of larvae injected with either teratocytes or TSP from the condition observed in parasitized larvae and noninjected controls. Gross dissection of periviseral fat body from parasitized, teratocyte-injected and TSP-injected larvae showed tissue much less developed and differing considerably in appearance from controls. Observed differences included reduced size and/or number of lipid bodies and qualitative and quantitative changes in other cytoplasmic organelles.

L-Arginine kinase from tobacco hornworm, Manduca sexta (L.). Purification, properties, and interaction with L-canavanine.

Arginine kinase (adenosine 5'-triphosphate: L-arginine phosphotransferase, EC 2.7.3.3) was purified from the larvae of the tobacco hornworm, Manduca sexta (L). This enzyme catalyzes the production of L-phosphoarginine, which is the principal reserve of high energy phosphate compounds in insect muscle. The enzyme also phosphorylates L-canavanine, a guanidinooxy analogue of arginine which severely disrupts all developmental stages of this insect. Evaluations of certain kinetic and thermodynamic parameters of the reactions with arginine and canavanine suggest that reactions known to be much more sensitive to canavanine, such as protein synthesis or genome expression, rather than phosphagen formation and function account for the pronounced toxicity of canavanine in this insect. Sedimentation equilibrium and electrophoresis on polyacrylamide gels containing sodium dodecyl sulfate indicate that this insect enzyme has a molecular weight of about 40,000. This value is consistent with molecular weights of arginine kinases of non-insect arthropods. Its amino acid composition is also very similar to that of other arthropod arginine kinases. Km values for the enzyme are: L-arginine, 0.5 mM; Mg-ATP, 2.5 mM; L-canavanine, 22 mM; L-phosphoarginine, 0.7 mM; Mg-ADP, 0.45 mM; and L-phosphocanavanine, 27 mM. Turnover numbers (expressed as moles of product per min per mol of enzyme) are: L-arginine, 8,320; L-canavanine, 1,635; L-phosphoarginine, 25,875; and L-phosphocanavanine, 3,040. The apparent equilibrium constants at 37 degrees for phosphagen formation are 0.44 with arginine and 0.1 with canavanine. A procedure for L-phosphocanavanine synthesis is also presented.

A teratocyte gene from a parasitic wasp that is associated with inhibition of insect growth and development inhibits host protein synthesis.

After parasitization, some wasps induce hosts prematurely to initiate metamorphic development that is then suspended in a postwandering, prepupal state. Following egression of the parasite larva, the host remains in this developmentally arrested state until death. Teratocytes, cells released at egg hatch from extra-embryonic serosal membranes of some wasp parasites, inhibit growth and development when injected into host larvae independent of other parasite factors (e.g. venom, polydnavirus). Synthesis of some developmentally regulated, abundantly expressed Heliothis virescens host proteins is inhibited in hosts parasitized by Microplitis croceipes and by teratocyte injection. A cDNA encoding a 13.9 kDa protein (TSP14) that inhibited protein synthesis, growth and development was isolated from a protein fraction secreted by teratocytes. TSP14 appears to be responsible, in part, for the teratocyte-mediated inhibition of host growth and development. Interestingly, this cDNA encoded a cysteine-rich amino acid motif similar to that described from Campoletis sonorensis polydnavirus, a mutualistic virus that enables wasp parasitization of lepidopteran larvae. Moreover, TSP14 inhibited protein synthesis in a dose-dependent manner in rabbit reticulocyte lysate and wheat germ extract translation systems. We hypothesize that some wasp parasites inhibit translation as a general means to regulate and redirect lepidopteran host physiology to support endoparasite development.

Insect feeding deterrents in endophyte-infected tall fescue.

The presence of an endophytic fungus, Acremonium coenophialum, in tall fescue (Festuca arundinacea) deterred aphid feeding by Rhopalosiphum padi and Schizaphis graminum. Both species of aphid were unable to survive when confined to endophyte-infected tall fescue plants. Feeding deterrents and toxic factors to R. padi and Oncopeltus fasciatus, large milkweed bug, were primarily associated with a methanol extract obtained when endophyte-infected tall fescue seed was serially extracted with hexane, ethyl acetate, and methanol. The concentrations of pyrrolizidine alkaloids were determined to be 30 to 100 times greater in the methanol extract than in the hexane and ethyl acetate extracts.