Ultrastructural changes in the midguts of Hessian fly larvae feeding on resistant wheat

The focus of the present study was to compare ultrastructure in the midguts of larvae of the Hessian fly, Mayetiola destructor (Say), under different feeding regimens. Larvae were either fed on Hessian fly-resistant or -susceptible wheat, and each group was compared to starved larvae. Within 3 h of larval Hessian fly feeding on resistant wheat, midgut microvilli were disrupted, and after 6 h, microvilli were absent. The disruption in microvilli in larvae feeding on resistant wheat were similar to those reported for midgut microvilli of European corn borer, Ostrinia nubilasis (Hubner), larvae fed a diet containing wheat germ agglutinin. Results from the present ultrastructural study, coupled with previous studies documenting expression of genes encoding lectin and lectin-like proteins is rapidly up-regulated in resistant wheat to larval Hessian fly, are indications that the midgut is a target of plant resistance compounds. In addition, the midgut of the larval Hessian fly is apparently unique among other dipterans in that no peritrophic membrane was observed. Ultrastructural changes in the midgut are discussed from the prospective of their potential affects on the gut physiology of Hessian fly larvae and the mechanism of antibiosis in the resistance of wheat to Hessian fly attack.     

Archives of insect biochemistry and physiology guide for authors

Several carbohydrases and glycosidases from the alimentary cancal and/or salivary glands of feeding larvae of mayetiola destructor have been identified. Pectinase activity was identified in the midgut and may be present in the salivary glands. No endocellulase activity was found in larvae; however, hemicellulase activity was detected in extract of larvae. Amylase activity was present in midguts from feeding larvae and at a low level in extract of salivary glands. Amylases detected in the midgut showed mobilities during polyacrylamide gel electrophoresis similar to the two major amylases in tissues of the insect's host plant. The possibility exists that Hessian fly larvae utilize amylases obtained from their host plant in the digestion of starch. The major glycosidases detected in the midgut lumen of larve were: α-D-glucosidase and α-D-and β-D-galactosidase. The role of these enzymes in the feeding process of Hessian fly larvae is discussed as well as their potential role in feeding damage to wheat.     

Hessian fly (Mayetiola destructor) attack causes a dramatic shift in carbon and nitrogen metabolism in wheat

Carbon and nitrogen (C/N) metabolism and allocation within the plant have important implications for plant-parasite interactions. Many plant parasites manipulate the host by inducing C/N changes that benefit their own survival and growth. Plant resistance can prevent this parasite manipulation. We used the wheat-Hessian fly (Mayetiola destructor) system to analyze C/N changes in plants during compatible and incompatible interactions. The Hessian fly is an insect but shares many features with plant pathogens, being sessile during feeding stages and having avirulence (Avr) genes that match plant resistance genes in gene-for-gene relationships. Many wheat genes involved in C/N metabolism were differentially regulated in plants during compatible and incompatible interactions. In plants during compatible interactions, the content of free carbon-containing compounds decreased 36%, whereas the content of free nitrogen-containing compounds increased 46%. This C/N shift was likely achieved through a coordinated regulation of genes in a number of central metabolic pathways, including glycolysis, the tricarboxylic acid cycle, and amino-acid synthesis. Our data on plants during compatible interactions support recent findings that Hessian fly larvae create nutritive cells at feeding (attack) sites and manipulate host plants to enhance their own survival and growth. In plants during incompatible interactions, most of the metabolic genes examined were not affected or down-regulated.     

Inducible P450s of the CYP9 family from larval Manduca sexta midgut

Several related cytochrome P450 cDNAs belonging to the CYP9 family have been cloned from the midgut of larval tobacco hornworms, Manduca sexta. The first P450, CYP9A2, was obtained by RT-PCR using degenerate primers. Northern blot analysis of expression in the midgut using the CYP9A2 probe revealed a significant induction by a variety of chemicals. Diets supplemented with the wild tomato compound 2-undecanone caused a dose-dependent induction which peaked after 48 h. Induction was also observed after addition to the diet of indole-3-carbinol, phenobarbital, 2-tridecanone and xanthotoxin. Neither alpha-pinene, clofibrate nor nicotine were effective inducers. The CYP9A2 probe hybridized to two mRNA species, one of 2. 0 kb and another of 4.2 kb, suggesting cross-hybridization to other P450 mRNAs. Additional P450 clones of the CYP9 family were then obtained and sequenced. Northern hybridization revealed that the 4.2 kb band also hybridized to CYP9A4 whereas the 2.0 kb hybridized to CYP9A5. Despite being 91% identical, CYP9A4 and CYP9A5 were induced differentially by clofibrate and xanthotoxin. Multiple P450 genes from various families are therefore induced in Lepidoptera in response to plant allelochemicals or xenobiotics.     

Gene-for-gene defense of wheat against the Hessian fly lacks a classical oxidative burst

Genetic similarities between plant interactions with microbial pathogens and wheat interactions with Hessian fly larvae prompted us to investigate defense and counterdefense mechanisms. Plant oxidative burst, a rapid increase in the levels of active oxygen species (AOS) within the initial 24 h of an interaction with pathogens, commonly is associated with defenses that are triggered by gene-for-gene recognition events similar to those involving wheat and Hessian fly larvae. RNAs encoded by Hessian fly superoxide dismutase (SOD) and catalase (CAT) genes, involved in detoxification of AOS, increased in first-instar larvae during both compatible and incompatible interactions. However, mRNA levels of a wheat NADPH oxidase (NOX) gene that generates superoxide (O2-) did not increase. In addition, inhibiting wheat NOX enzyme with diphenyleneiodonium did not result in increased survival of avirulent larvae. However, nitro blue tetrazolium staining indicated that basal levels of O2- are present in both uninfested and infested wheat tissue. mRNA encoded by wheat genes involved in detoxification of the cellular environment, SOD, CAT, and glutathione-S-transferase did not increase in abundance. Histochemical staining with 3,3-diaminobenzidine revealed no increases in wheat hydrogen peroxide (H2O2) during infestation that were correlated with the changes in larval SOD and CAT mRNA. However, treatment with 2',7'-dichlorofluorescin demonstrated the presence of basal levels of H2O2 in the elongation zone of both infested and uninfested plants. The accumulation of a wheat flavanone 3-hydroxylase mRNA did show some parallels with larval gene mRNA profiles. These results suggested that larvae encounter stresses imposed by mechanisms other than an oxidative burst in wheat seedlings.     

MOLECULAR CHARACTERIZATIONS OF TWO CYTOCHROME P450 GENES ENCODING CYP6A41 AND CYP6EK1 FROM THE ORIENTAL FRUIT FLY,Bactrocera dorsalis (DIPTERA: TEPHRITIDAE)

Two P450 genes encoding CYP6A41 and CYP6EK1 were cloned from the oriental fruit fly using polymerase chain reaction (PCR) and rapid amplification of cDNA ends (RACE) techniques. CYP6A41 and CYP6EK1 contained open reading frames of 1,530 and 1,524 nucleotides that encode 510 and 508 amino acid residues, respectively. The putative proteins shared 44% identity with each other. Phylogenetic analysis showed that CYP6A41 and CYP6EK1 were most closely related to Ceratitis capitata CYP6A10 and CYP6A subfamily. Expression patterns of the two genes in different geographical populations (Yunnan, Hainan, Dongguang, and Guangzhou), developmental stages (eggs, larvae, pupae, and adults), and tissues (midguts, fat bodies, and Malpighian tubules) were analyzed by real‐time quantitative PCR (RT‐qPCR) methods. The results showed that the expression levels of CYP6EK1 were significantly different among the four populations, but were not different for CYP6A41. Both the expressions of CYP6A41 and CYP6EK1 were development specific and had significantly higher levels in the larval stage. The expression of CYP6A41 did not vary among the midgut, fat body, or Malpighian tubules; however, CYP6EK1 expression was higher in the Malpighian tubules. The results suggest that CYP6A41 and CYP6EK1 might be involved in detoxification of xenobiotic compounds that were harmful to larval flies or development. Moreover, high expression of CYP6EK1 in the Malpighian tubules also implied participation in detoxification.     

Involvement of cytochrome P450 monooxygenases in the response of mosquito larvae to dietary plant xenobiotics

The response of mosquito larvae to plant toxins found in their breeding sites was investigated by using Aedes aegypti larvae and toxic arborescent leaf litter as experimental models. The relation between larval tolerance to toxic leaf litter and cytochrome P450 monooxygenases (P450s) was examined at the toxicological, biochemical and molecular levels. Larvae pre-exposed to toxic leaf litter show a higher tolerance to those xenobiotics together with a strong increase in P450 activity levels. This enzymatic response is both time- and dose-dependent. The use of degenerate primers from various P450 genes (CYPs) allowed us to isolate 16 new CYP genes belonging to CYP4, CYP6 and CYP9 families. Expression studies revealed a 2.3-fold over-expression of 1 CYP gene (CYP6AL1) after larval pre-exposure to toxic leaf litter, this gene being expressed at a high level in late larval and pupal stages and in fat bodies and midgut. The CYP6AL1 protein has a high level of identity with other insect's CYPs involved in xenobiotic detoxification. The role of CYP genes in tolerance to natural xenobiotics and the importance of such adaptive responses in the capacity of mosquitoes to colonize new habitats and to develop insecticide resistance mechanisms are discussed.     

桃蛀螟CYP6AE76基因参与对Cry1Ab蛋白的解毒作用

【目的】明确桃蛀螟Conogethes punctiferalis幼虫取食Cry1Ab蛋白后体内CYP6AE76的过表达及对Cry1Ab蛋白有解毒作用。【方法】分析桃蛀螟CYP6AE76序列特征;利用RT-qPCR检测CYP6AE76在不同发育阶段(1-5龄幼虫)和4龄幼虫不同组织(头、中肠、血淋巴和脂肪体)以及4龄幼虫取食含有Cry1Ab蛋白(LC₅₀=1.08 ng/cm2)的人工饲料3 d存活的幼虫中肠和血淋巴中的表达量;利用RNAi饲喂法沉默桃蛀螟4 龄幼虫CYP6AE76后检测中肠中CYP6AE76的表达量,并统计120 h后幼虫体重并计算幼虫存活率;利用RNAi饲喂法沉默桃蛀螟初孵幼虫CYP6AE76后饲喂含1.08 ng/cm² Cry1Ab蛋白的饲料,7 d后统计幼虫体重并计算幼虫存活率。【结果】桃蛀螟CYP6AE76基因开放阅读框长1 572 bp,编码524个氨基酸,分子量约为60.34 kD,属于CYP6家族基因。发育表达谱结果表明, CYP6AE76基因在桃蛀螟整个幼虫阶段均有表达且在1龄幼虫期表达量最高,随着幼虫龄期增大而表达量降低;组织表达谱结果表明,CYP6AE76在4龄幼虫中肠中表达量最高。4龄幼虫取食含有Cry1Ab蛋白(1.08 ng/cm²)的人工饲料后,CYP6AE76在中肠和血淋巴中的表达量相比对照显著上调。通过RNAi沉默CYP6AE76后,桃蛀螟初孵幼虫再取食含有Cry1Ab蛋白的人工饲料后体重显著降低。【结论】CYP6AE76可能参与对桃蛀螟幼虫摄入的Cry1Ab蛋白的解毒。