RNA interference of a trehalose-6-phosphate synthase gene reveals its roles in the biosynthesis of chitin and lipids in Heortia vitessoides(Lepidoptera:Crambidae)

Trehalose 6-phosphate synthase(TPS),an enzyme that hydrolyzes two glucose molecules to yield trchalose,plays a pivotal role in various physiological processes.In this study,we cloned the trehalose-6-phosphate synthase gene(HvTPS)and investigated its expression patterns in various tssues and d:velopmental stages in Heortia vitessoides Moore(Lepidoptera:Crambidac).HvTPS was highly expressed in the fat body and after pupation or before molting.We knocked down TPS in H.vitessoides by RNA interference and found that 3.0μg of dsHvTPS resulted in optimal interference at 24 h and 36 h post-injection and caused a sharp decline in the survival rate during the 5th instar larval-pupal stage and obviously abnormal or lethal phenotypes.Additionally.compared to the controls,TPS activity and trehalose contents were significantly lower and the glucose content was significantly higher 24 h or 36 h after injection with 3.0μg of dsHIvTPS.Furthermore,the silencing of HvTPS suppressed the cxpression of six key genecs in the chitin biosynthesis pathway and one key gene related to lipid catabolism.The expression levels of two genes associated with lipid biosynthesis were upregulated.These results strongly suggest that HvTPS is essential for the normal growth and development of H.vitessoides and provide a reference for further studies of the utility of key genes involved in chitin and lipid biosynthesis for controlling insect development.     

Knockdown of β‐N‐acetylglucosaminidase gene disrupts molting process in Heortia vitessoides Moore

β‐N‐acetylglucosaminidase (NAG) is a key enzyme in insect chitin metabolism and plays an important role in many physiological activities of insects. The HvNAG1 gene was identified from the Heortia vitessoides Moore (Lepidoptera: Crambidae) cDNA library and its expression patterns were determined using quantitative real‐time polymerase chain reaction. The results indicated that HvNAG1 mRNA levels were high in the midgut and before molting, and 20E could induce its expression. Subsequently, the HvNAG1 gene was knocked down via RNA interference to identify its functions. We found that 3 μg of dsNAG1 resulted in optimal interference at 48 and 72 hr after injection, causing a decrease in NAG1 protein content, which resulted in abnormal or lethal phenotypes, and a sharp decrease in the survival rate. These results indicate that HvNAG1 plays a key role in the molting process of H. vitessoides. However, the silencing of HvNAG1 had no significant effect on the chitin metabolism‐related genes tested in this study. Our present study provides a reference for further research on the utility of key genes involved in the chitin metabolic pathway in the insect molting process.     

黄野螟群体大小对幼虫个体生存和发育的影响

幼虫聚集取食是一些鳞翅目昆虫提高幼虫生长和存活的手段。通过对聚集取食的黄野螟Heortia vitessoides Moore幼虫在室内条件下进行饲养,探究黄野螟幼虫的群体数量大小(分别为30、60、90头幼虫)对幼虫体长、发育速度、达末龄(5龄)时的存活率的影响。分析发现在排除天敌捕食和食物缺乏的前提下,从3龄开始,大群体(90头)的体长显著大于小群体(30头),大群体的幼虫发育速度显著快于小群体,大群体对幼虫前4个龄期时的成活率没有显著提高,尽管大群体的存活率在均值上高于小群体,但是幼虫总体存活率在不同群体中差异不显著。黄野螟幼虫的聚集取食对幼虫的生长的促进作用明显,显著促进了幼虫的生长,加快了幼虫的发育。     

The role of eclosion hormone in the larval ecdyses of Manduca sexta

Each larval moult in Manduca sexta consists of an identical series of developmental and behavioural events leading up to ecdysis. Injections of eclosion hormone into staged larvae in any instar resulted in the premature elicitation of the larval pre-ecdysis behaviour, comprising a rhythmic sequence of muscle contractions, followed by the larval ecdysis behaviour.A marked depletion of eclosion hormone stores form the ventral chain of ganglia coincided with each larval ecdysis and in the moult to the fifth instar, eclosion hormone activity appeared in the blood at the onset of the pre-ecdysis behaviour.Responsiveness to eclosion hormone for pre-ecdysis and ecdysis behaviour developed about 12 and 6 hr before normal ecdysis, respectively. Elicitation of ecdysis behaviour by exogenous hormone inhibited both subsequent behavioural responses to eclosion hormone and endogenous hormonal release.In conclusion, the behavioural programme involved in each larval ecdysis appears to be controlled by the eclosion hormone.     

The roles of central and peripheral eclosion hormone release in the control of ecdysis behavior in Manduca sexta

1. Ecdysis, a behavior by which insects shed the old cuticle at the culmination of each molt, is triggered by a unique peptide hormone, eclosion hormone (EH). In pupal Manduca sexta, EH is released into the hemolymph just prior to ecdysis, and circulating hormone is sufficient to elicit this behavior. 2. Removal of the proctodeal nerves in prepupal animals eliminated the appearance of blood-borne EH, but ecdysis behavior occurred on schedule. Therefore, circulating EH is not necessary for the triggering of ecdysis. 3. In contrast, a set of dermal glands failed to show their expected bout of secretion after proctodeal nerve removal. Injection of exogenous EH rescued this secretion. Thus, circulating EH appears necessary for action on peripheral but not central targets. 4. A major reduction in EH immunostaining is seen in the proctodeal nerves just preceding ecdysis; this coincides with a greater than 90% reduction in extractable EH from this structure and the appearance of circulating EH. A similar, concomitant reduction was seen in central EH cell processes, suggesting release of peptide within the CNS. 5. Antidromic stimulation of the proctodeal nerve stumps following proctodeal nerve removal triggered precocious ecdysis. This result further supports the conclusion that centrally released EH is sufficient to trigger the motor program.     

A whole genome screening and RNA interference identify a juvenile hormone esterase-like gene of the diamondback moth,Plutella xylostella

Juvenile hormone (JH) plays a crucial role in preventing precocious metamorphosis and stimulating reproduction. Thus, its hemolymph titer should be under a tight control. As a negative controller, juvenile hormone esterase (JHE) performs a rapid breakdown of residual JH in the hemolymph during last instar to induce a larval-to-pupal metamorphosis. A whole genome of the diamondback moth (DBM), Plutella xylostella, has been annotated and proposed 11 JHE candidates. Sequence analysis using conserved motifs commonly found in other JHEs proposed a putative JHE (Px004817). Px004817 (64.61 kDa, pI = 5.28) exhibited a characteristic JHE expression pattern by showing high peak at the early last instar, at which JHE enzyme activity was also at a maximal level. RNA interference of Px004817 reduced JHE activity and interrupted pupal development with a significant increase of larval period. This study identifies Px004817 as a JHE-like gene of P. xylostella.     

RNA interference mediated knockdown of juvenile hormone esterase gene in Bemisia tabaci (Gennadius): Effects on adults and their progeny

Juvenile hormone is responsible for regulating metamorphosis and reproduction in insects. Analysis of key elements of juvenile hormone regulation would enhance the understanding of this complex mechanism. Juvenile hormone esterase plays an important role in maintaining juvenile hormone titres in insects. In this study, effects of knockdown of juvenile hormone esterase gene (jhe) in Bemisia tabaci were studied using RNA interference (RNAi) technique. dsRNA corresponding to two conserved regions of jhe gene, substrate binding pocket site (jhe1), catalytic triad site (jhe2), green fluorescent protein gene (gfp) as control were synthesized. dsRNAs incorporated in artificial diet (20% sucrose solution) @ 2.5, 1.0, 0.5 and 0.1 μg/μl were fed to adult whiteflies for 48 h, followed by shifting whiteflies to live plants for next generation biology study. Based on qRT-PCR analyses, reduced jhe gene expression was observed in adult whiteflies after dsRNA feeding @ 2.5 and 1.0 μg/μl. jhe gene knockdown affects the survival and reproduction of whiteflies adversely in a dose-dependent manner. Moreover, oral feeding of dsRNA to adult whiteflies @ 2.5 and 1.0 μg/μl showed adverse effects on next generation of whitefly viz., lower egg hatchability and shortened egg incubation period. Minimum number of viable eggs (1.04 and 1.80 eggs/female) were observed when whiteflies were fed with highest concentration of dsjhe1 and dsjhe2 as compared to control (16.58 eggs/female). These data suggest that jhe gene acts as a major biological player in whitefly and its progeny and further indicate to be potential target for managing whitefly population.     

亚洲玉米螟神经肽羽化激素基因cDNA的克隆及组织表达

羽化激素对调节昆虫的蜕皮和发育起关键作用。亚洲玉米螟Ostrinia furnacalis是亚洲农业重要害虫之一,本实验研究了亚洲玉米螟羽化激素基因cDNA的分子结构和表达模式。利用兼并性引物RT-PCR技术,克隆了亚洲玉米螟羽化激素基因cDNA的中间片段,然后再用RACE方法,获得羽化激素基因的 cDNA全长序列。结果表明： 亚洲玉米螟羽化激素基因cDNA全长986 bp（GenBank登录号： DQ668369）,开放阅读框为267 bp,编码88个氨基酸的前体蛋白,其中包括前26个氨基酸组成的信号肽和62个氨基酸的成熟肽。亚洲玉米螟羽化激素基因与烟草天蛾、棉铃虫和家蚕已报道同源基因的同源性较高,分别为79.5%、77.3%和67.0%,与黑腹果蝇同源基因的同源性最低,仅45.5%。亚洲玉米螟羽化激素基因mRNA只在脑中表达,在咽下神经节、胸神经节、腹神经节等神经组织中检测不到,在非神经组织如中肠、脂肪体和表皮中也不表达。     

Circadian clock and prothoracicotropic hormone secretion in relation to the larval-larval ecdysis rhythm of the saturniid Samia cynthia ricini

Observations on the timing of ecdysis and neck ligation experiments on larvae of Samia cynthia ricini under various light-dark conditions show that an endogenous circadian clock controls the timing of larval ecdysis and prothoracicotropic hormone (PTTH) secretion preceding it. The clock, upon reaching a specific phase point, causes the brain to secrete PTTH provided that the brain has acquired the secretory competence. This time may vary, in relation to a previous ecdysis, according to the light-dark conditions by which the clock phase is specifically determined, but is fixed relative to a subsequent ecdysis. Thus, in the case of the ecdysis to the 5th instar, PTTH is secreted [15+nτ] hr (τ: free-running period, slightly less than 24 hr) after the clock has started when the rhythm is free-running, and in the second and third nights of the 4th instar under a photoperiod of 12 hr light and 12 hr dark. Full secretion of ecdysone occurs 6 hr after PTTH secretion and ecdysis ensues 34 hr thereafter to complete the ultimate sequence of ecdysis.     

RNA interference unveils functions of the hypertrehalosemic hormone on cyclic fluctuation of hemolymph trehalose and oviposition in the virgin female Blattella germanica

Hypertrehalosemic hormone (HTH) is a neuropeptide within the adipokinetic hormone (AKH) family that induces a release of trehalose from fat body into hemolymph in a number of insects. In this study, we first showed that female adult German cockroach, Blattella germanica, displayed a cyclic fluctuation of hemolymph trehalose levels correlated to the maturation of oocytes in the reproductive cycle. After cloning the HTH cDNA from the German cockroach (Blage-HTH), expression studies indicated that Blage-HTH mRNA showed the cyclic changes during the first reproductive cycle, where peak values occurred in 8-day-old virgin female cockroaches, which were going to produce oothecae. The functions of Blage-HTH were studied using RNA interference (RNAi) to knockdown its expression. Adult virgin females of B. germanica injected with Blage-HTH dsRNA increased hemolymph trehalose levels in the late period of vitellogenesis more slowly than control. Furthermore, RNAi of Blage-HTH delayed oviposition time and some (10%) individuals did not produce the first ootheca until 15 days after eclosion, whereas the control group produced ootheca before 9 days in all cases.     

RNAi技术在昆虫功能基因研究中的应用进展

RNA干扰（RNA interference,RNAi）是指外源或内源的双链RNA（dsRNA）特异性地引起基因表达沉默的现象,它作为一种有效的工具用来产生转录后沉默,从而抑制特定基因的表达,成为基因功能研究的一种新方法,除了在模式昆虫如果蝇Drosophila中广泛应用之外,也在非模式昆虫中得到成功应用。近年来,RNAi技术在导入方法和基因功能分析方面都取得了飞速发展,且与转基因技术相结合成功应用于害虫防治领域。本文综述了RNAi技术在导入方法、昆虫功能基因组功能分析及害虫防治等领域新近的研究成果,并展望了该技术的应用前景。     

Functional analysis of two chitinase genes during the pupation and eclosion stages of the beet armyworm Spodoptera exigua by RNA interference

Insect chitinases are a multigene family that is encoded by a rather large and diverse group of genes. The main function of chitinases is to digest the chitin contained in tissues such as the cuticles and gut lining during molting. In this study, we examined the role of a chitinase (SeChi) and a bacterial type chitinase (SeChi-h) during the pupation and eclosion stages of Spodoptera exigua. First, efficient silencing of the SeChi and SeChi-h genes through specific double-stranded RNA (dsRNA) injection led to a significant reduction in the mRNA levels of SeChi and SeChi-h. Additionally, different phenotypic defects were observed at the pupal and adult stages after injection of the SeChi and SeChi-h dsRNAs. After injecting SeChi dsRNA in the pupal stage, the cuticle of the head split open and the pupal cuticle was visible under the old larval cuticle. However, after injecting the SeChi-h dsRNA, animals died without exhibiting any special phenotypes. At the adult death stage, animals injected with dsSeChi could not shed their pupal shell completely, and their old cuticles remained attached to their head or chest. However, the main lethal phenotype was that insects did not emerge after dsSeChi-h injection. Additionally, the average survival rates of S. exigua were 52.02% and 40.38% at the pupal and adult stages, respectively, after injection with SeChi dsRNA. For the insects injected with SeChi-h dsRNA, the survival rates were 72.38% and 48.52%, respectively. These results suggest that SeChi and SeChi-h may have different biologic functions during the pupal-adult molting.     

Adipokinetic hormone receptor gene identification and its role in triacylglycerol mobilization and sexual behavior in the oriental fruit fly (Bactrocera dorsalis)

Energy homeostasis requires continuous compensation for fluctuations in energy expenditure and availability of food resources. In insects, energy mobilization is under control of the adipokinetic hormone (AKH) where it is regulating the nutritional status by supporting the mobilization of lipids. In this study, we characterized the gene coding for the AKH receptor (AKHR) and investigated its function in the oriental fruit fly (Bactrocera dorsalis) that is economically one of the most important pest insects of tropical and subtropical fruit. Bacdo-AKHR is a typical G protein-coupled receptor (GPCR) and phylogenetic analysis confirmed that Bacdo-AKHR is closely related to insect AKHRs from other species. When expressed in Chinese hamster ovary (CHO) cells, Bacdo-AKHR exhibited a high sensitivity and selectivity for AKH peptide (EC₅₀ = 19.3 nM). Using qPCR, the developmental stage and tissue-specific expression profiles demonstrated that Bacdo-AKHR was highly expressed in both the larval and adult stages, and also specifically in the fat body and midgut of the adult with no difference in sex. To investigate the role of AKHR in B. dorsalis, RNAi assays were performed with dsRNA against Bacdo-AKHR in adult flies of both sexes and under starvation and feeding condition. As major results, the knockdown of this gene resulted in triacylglycerol (TAG) accumulation. With RNAi-males, we observed a severe decrease in their sexual courtship activity when starved, but there was a partial rescue in copulation when refed. Also in RNAi-males, the tethered-flight duration declined compared with the control group when starved, which is confirming the dependency on energy metabolism. In RNAi-females, the sexual behavior was not affected, but their fecundity was decreased. Our findings indicate an interesting role of AKHR in the sexual behavior of males specifically. The effects are associated with TAG accumulation, and we also reported that the conserved role of AKH-mediated system in B. dorsalis is nutritional state-dependent. Hence, we provided further understanding on the multiple functions of AKH/AKHR in B. dorsalis.     

Immunotherapeutic strategies employing RNA interference technology for the control of cancers

Summary The human immune system is comprised of several types of cells that have the potential to eradicate tumors without inflicting damage on normal tissue. Over the past decade, progress in the understanding of tumor biology and immunology has offered the exciting possibility of treating malignant disease with vaccines that exploit the capacity of T cells to effectively and selectively kill tumor cells. However, the immune system frequently fails to mount a successful defense against cancers despite vaccination with tumor-associated antigens. The ability of these vaccines to generate an abundant supply of armed effector T cells is often limited by immunoregulatory signaling pathways that suppress T cell activation. In addition, many tumors create a local microenvironment that inhibits the function of T cells. The attenuation of these pathways, which facilitate the evasion of tumors from immune surveillance, thus represents a potentially effective approach for cancer immunotherapy. Specifically, it may be of interest to modify the properties of dendritic cells, T cells, and tumor cells to downregulate the expression of proteins that diminish the immune response to cancers. RNA interference (RNAi) techniques have developed into a highly effective means of intracellular gene ‘knockdown’ and may be successfully employed in this way to improve cancer immunotherapies. This strategy has recently been explored both in vitro and in vivo, and has generated significantly enhanced antitumor immunity in numerous studies. Nevertheless, several practical concerns remain to be resolved before RNAi technology can be implemented safely and efficiently in humans. As novel developments and discoveries in molecular biology rapidly continue to unfold, it is likely that this technology may soon translate into a potent form of gene silencing in the clinic with profound applications to cancer immunotherapy.     

RNA interference of two acetylcholinesterase genes in Plutella xylostella reveals their different functions

Acetylcholinesterase (AChE, EC 3.1.1.7) is an important enzyme with a typical function of degrading the neurotransmitter acetylcholine. Although two ace genes were reported in Plutella xylostella, their function differences remain largely unknown. The chemically synthesized siRNAs (si‐Pxace1 and si‐Pxace2) were injected into the second instar larvae to knock down Pxace1 and Pxace2, either respectively or simultaneously. The mRNA abundance of Pxace1 and Pxace2 was significantly reduced to 7–33.5% of the control levels at 72 h after siRNA injection. The AChE activities were significantly decreased at 96 h after treatment. Silencing of Pxace1 or Pxace2 resulted in mortality of 33.9 and 22.9%, respectively. The survivors in siRNA‐treated groups had apparent growth inhibition such as reduction in larvae weights and lengths, malformation and motor retardation. Knockdown of Pxace1 apparently affected more on larvae growth than that of Pxace2, suggesting that Pxace1 had more important roles than Pxace2. Both Pxace1 and Pxace2 genes might have atypical functions in regulating larvae growth and motor ability.