昆虫几丁质合成及其调控研究前沿

几丁质合成与降解是昆虫最重要的生理过程之一。本文根据国外和作者自己的研究,综述了昆虫几丁质合成及其调控研究进展。昆虫几丁质的生物合成通路始于海藻糖,终止于几丁质,其中共有8个酶参与。目前研究最多的为海藻糖酶和几丁质合成酶。昆虫存在2个海藻糖酶基因和2个几丁质合成酶基因。可溶性海藻糖酶基因对昆虫表皮的几丁质合成影响更大,而膜结合海藻糖酶基因则主要影响中肠的几丁质合成。几丁质合成酶A主要负责表皮和气管几丁质的合成,而几丁质合成酶B则负责中肠围食膜的几丁质合成。目前,昆虫几丁质合成的调控途径主要有两种:利用RNAi技术和几丁质合成抑制剂。     

Sequences of cDNAs and expression of genes encoding chitin synthase and chitinase in the midgut of Spodoptera frugiperda

The focus of this study was on the characterization and expression of genes encoding enzymes responsible for the synthesis and degradation of chitin, chitin synthase (SfCHSB) and chitinase (SfCHI), respectively, in the midgut of the fall armyworm, Spodoptera frugiperda. Sequences of cDNAs for SfCHSB and SfCHI were determined by amplification of overlapping PCR fragments and the expression patterns of these two genes were analyzed during insect development by RT-PCR. SfCHSB encodes a protein of 1523 amino acids containing several transmembrane segments, whereas SfCHI encodes a protein of 555 amino acids composed of a catalytic domain, a linker region and a chitin-binding domain. SfCHSB is expressed in the midgut during the feeding stages, whereas SfCHI is expressed during the wandering and pupal stages. Both genes are expressed along the whole midgut. Chitin staining revealed that this polysaccharide is present in the peritrophic membrane (PM) only when SfCHSB is expressed. There is little or no chitin in the midgut when SfCHI is expressed. These results support the hypothesis that SfCHSB is responsible for PM chitin synthesis during the larval feeding stages and SfCHI carries out PM chitin degradation during larval-pupal molting, suggesting mutually exclusive temporal patterns of expression of these genes.     

Physiological and morphological aspects of Aedes aegypti developing larvae: effects of the chitin synthesis inhibitor novaluron

Population control of the dengue vector mosquito, Aedes aegypti, is difficult due to many reasons, one being the development of resistance to neurotoxic insecticides employed. The biosynthesis of chitin, a major constituent of insect cuticle, is a novel target for population control. Novaluron is a benzoylphenylurea (BPU) that acts as a chitin synthesis inhibitor, already used against mosquitoes. However, information regarding BPU effects on immature mosquito stages and physiological parameters related with mosquito larval development are scarce. A set of physiological parameters were recorded in control developing larvae and novaluron was administered continuously to Ae. aegypti larvae, since early third instar. Larval instar period duration was recorded from third instar until pupation. Chitin content was measured during third and fourth instars. Fourth instars were processed histochemically at the mesothorax region, stained with hematoxylin and eosin (HE) for assessment of internal tissues, and labeled with WGA-FITC to reveal chitinized structures. In control larvae: i) there is a chitin content increase during both third and fourth instars where late third instars contain more chitin than early fourth instars; ii) thoracic organs and a continuous cuticle, closely associated with the underlying epidermis were observed; iii) chitin was continuously present throughout integument cuticle. Novaluron treatment inhibited adult emergence, induced immature mortality, altered adult sex ratio and caused delay in larval development. Moreover, novaluron: i) significantly affected chitin content during larval development; ii) induced a discontinuous and altered cuticle in some regions while epidermis was often thinner or missing; iii) rendered chitin cuticle presence discontinuous and less evident. In both control and novaluron larvae, chitin was present in the peritrophic matrix. This study showed quantitatively and qualitatively evidences of novaluron effects on Ae. aegypti larval development. To our knowledge, this is the first report describing histological alterations produced by a BPU in immature vector mosquitoes.     

The effects of blood feeding and exogenous supply of tryptophan on the quantities of xanthurenic acid in the salivary glands of Anopheles stephensi (Diptera: Culicidae)

Xanthurenic acid (XA), produced as a byproduct during the biosynthesis of insect eye pigment (ommochromes), is a strong inducer of Plasmodium gametogenesis at very low concentrations. In previous studies, it was shown that XA is present in Anopheles stephensi (Diptera: Culicidae) mosquito salivary glands and that during blood feeding the mosquitoes ingested their own saliva into the midgut. Considering these two facts together, it is therefore likely that XA is discharged with saliva during blood feeding and is swallowed into the midgut where it exerts its effect on Plasmodium gametocytes. However, the quantities of XA in the salivary glands and midgut are unknown. In this study, we used high performance liquid chromatography with electrochemical detection to detect and quantify XA in the salivary glands and midgut. Based on the results of this study, we found 0.28+/-0.05 ng of XA in the salivary glands of the mosquitoes, accounting for 10% of the total XA content in the mosquito whole body. The amounts of XA in the salivary glands reduced to 0.13+/-0.06 ng after mosquitoes ingested a blood meal. Approximately 0.05+/-0.01 ng of XA was detected in the midgut of nonblood fed An. stephensi mosquitoes. By adding synthetic tryptophan as a source of XA into larval rearing water (2 mM) or in sugar meals (10 mM), we evaluated whether XA levels in the mosquito (salivary glands, midgut, and whole body) were boosted and the subsequent effect on infectivity of Plasmodium berghei in the treated mosquito groups. A female specific increase in XA content was observed in the whole body and in the midgut of mosquito groups where tryptophan was added either in the larval water or sugar meals. However, XA in the salivary glands was not affected by tryptophan addition to larval water, and surprisingly it reduced when tryptophan was added to sugar meals. The P. berghei oocyst loads in the mosquito midguts were lower in mosquitoes fed tryptophan treated sugar meals than in mosquitoes reared on tryptophan treated larval water. Our results suggest that mosquito nutrition may have a significant impact on whole body and midgut XA levels in mosquitoes. We discuss the observed parasite infectivity results in relation to XA's relationship with malaria parasite development in mosquitoes.     

Obstructor-A is required for epithelial extracellular matrix dynamics, exoskeleton function, and tubulogenesis

The epidermis and internal tubular organs, such as gut and lungs, are exposed to a hostile environment. They form an extracellular matrix to provide epithelial integrity and to prevent contact with pathogens and toxins. In arthropods, the cuticle protects, shapes, and enables the functioning of organs. During development, cuticle matrix is shielded from premature degradation; however, underlying molecular mechanisms are poorly understood. Previously, we identified the conserved obstructor multigene-family, which encodes chitin-binding proteins. Here we show that Obstructor-A is required for extracellular matrix dynamics in cuticle forming organs. Loss of obstructor-A causes severe defects during cuticle molting, wound protection, tube expansion and larval growth control. We found that Obstructor-A interacts and forms a core complex with the polysaccharide chitin, the cuticle modifier Knickkopf and the chitin deacetylase Serpentine. Knickkopf protects chitin from chitinase-dependent degradation and deacetylase enzymes ensure extracellular matrix maturation. We provide evidence that Obstructor-A is required to control the presence of Knickkopf and Serpentine in the extracellular matrix. We propose a model suggesting that Obstructor-A coordinates the core complex for extracellular matrix protection from premature degradation. This mechanism enables exoskeletal molting, tube expansion, and epithelial integrity. The evolutionary conservation suggests a common role of Obstructor-A and homologs in coordinating extracellular matrix protection in epithelial tissues of chitinous invertebrates.     

Infection and dissemination of West Nile virus in China by the potential vector,Culex pipiens pallens

The distribution of the West Nile virus (WNV) in the organs and tissues of the mosquito Culex pipiens pallens, a potential vector of WNV in China, was investigated up to 14 days after oral infection. The WNV antigen was detected in paraffin‐embedded mosquitoes using immunocytochemistry and viral titers of post‐infected mosquitoes determined by plaque assay. Viral titers sharply decreased 24 h post‐infection, were undetectable for the first few days, then rose over the course of infection. The first midgut infection appeared after one day, and the overall infection rate (based on midgut infection) was 43.9%. Other tissues, including hindgut, foregut, ovarian follicles, Malpighian tubules, and ommatidia, showed weak WNV antigens as early as three days post‐infection. Staining in the salivary glands first appeared after seven days, and the salivary gland infection rate on the 14th day was 37.5%. Specimens with no detectable WNV antigens in any tissues, and with positive results confined to the midgut, anterior midgut, and hindgut, were observed on the 14th day. The route of viral dissemination from the midgut, and the relative importance of amplifying tissues in mosquitoes' susceptibility to infection, were evaluated. The results indicate that Cx. p. pallens has the ability to harbor WNV throughout its alimentary system and that midgut epithelial cells may be the initial site of the replication of this virus in this species.     

Macrophage migration inhibitory factor expression and protein localization in <Emphasis Type="Italic">Amblyomma americanum</Emphasis> (Ixodidae)

Amblyomma americanum (L.) ticks continue to emerge as disease vectors in many areas of the United States. Tick macrophage migration inhibitory factor (MIF) was first identified in A. americanum females and has been demonstrated to inhibit macrophage movement to the same extent as human MIF. This study was conducted to further characterize and elucidate the physiological role for MIF in tick feeding. A relative quantitative PCR assay was developed to determine the level of MIF gene expression during tick feeding. In addition, RNAi techniques were used to silence MIF prior to blood feeding. Physiological parameters of tick engorgement weight, length of feeding interval, and egg masses were observed to check for phenotypic manifestations of RNA silencing. Specific tick MIF antibody was used to localize MIF protein in frozen tick tissue sections. Tissue specific gene expression indicated that the midgut tissues were the most highly enriched for the MIF. Levels of gene expression did not parallel MIF protein pools seen in tissue sections. Of particular importance was the finding that unfed tick salivary glands appear to contain vesicles that are specific for MIF protein. This is the first demonstration of a pool of MIF that could be secreted during the first hours of tick feeding. While MIF silencing was demonstrated at the molecular level, no physiological phenotype was apparent. The MIF protein pools already available in the tissues may be sufficient to accomplish female tick feeding. Our studies show that the most prominent source of MIF during tick feeding is the midgut tissue. Future studies will address the role of MIF in blood feeding and nutrient digestion in the immature life stages of the tick.     

Genome‐wide identification of chitin‐binding proteins and characterization of BmCBP1 in the silkworm,Bombyx mori

The insect cuticle plays important roles in numerous physiological functions to protect the body from invasion of pathogens, physical injury and dehydration. In this report, we conducted a comprehensive genome-wide search for genes encoding proteins with peritrophin A-type (ChtBD2) chitin-binding domain (CBD) in the silkworm, Bombyx mori. One of these genes, which encodes the cuticle protein BmCBP1, was additionally cloned, and its expression and location during the process of development and molting in B. mori were investigated. In total, 46 protein-coding genes were identified in the silkworm genome, including those encoding 15 cuticle proteins analogous to peritrophins with one CBD (CPAP1s), nine cuticle proteins analogous to peritrophins with three CBD (CPAP3s), 15 peritrophic membrane proteins (PMPs), four chitinases, and three chitin deacetylases, which contained at least one ChtBD2 domain. Microarray analysis indicated that CPAP-encoding genes were widely expressed in various tissues, whereas PMP genes were highly expressed in the midgut. Quantitative polymerase chain reaction and western blotting showed that the cuticle protein BmCBP1 was highly expressed in the epidermis and head, particularly during molting and metamorphosis. An immunofluorescence study revealed that chitin co-localized with BmCBP1 at the epidermal surface during molting. Additionally, BmCBP1 was notably up-regulated by 20-hydroxyecdysone treatment. These results provide a genome-level view of the chitin-binding protein in silkworm and suggest that BmCBP1 participates in the formation of the new cuticle during molting.     

Hydrocarbon accumulation and lipid biosynthesis during larval development in the cabbage looper,Trichoplusia ni

Larvae of the cabbage looper, Trichoplusia ni, were analyzed for the accumulation and biosynthesis of cuticular and internal hydrocarbon at closely spaced and accurately timed intervals during the fourth and fifth stadia. Large differences in the incorporation of [1-¹⁴C]acetate into hydrocarbon were observed at different times during larval development. Much higher incorporation was observed during feeding stages as compared to wandering stages, while lowest rates of biosynthesis occurred just prior to ecdysis. Fourth stadia wanderers accumulated increased amounts of internal hydrocarbon, which is apparently used to cover the newly forming cuticle. During the fourth to fifth stadium moult insects lost all cuticular hydrocarbon that was present on the old cuticle (about 8 μg/insect) and had about 8 μg/insect on the surface of the newly exposed cuticle. During the fourth stadium incorporation of [1-¹⁴C]acetate into total lipid declined between feeding and wandering stages from 24% of injected radiolabel to 7%. Similar decreases in lipid biosynthesis were observed between feeders and wanderers in fifth stadium larvae with the greatest decrease found in the triacylglycerol fraction. These results document dramatic changes in the accumulation and biosynthesis of hydrocarbon and other lipids during larval development.     

Different Functions of the Insect Soluble and Membrane-Bound Trehalase Genes in Chitin Biosynthesis Revealed by RNA Interference

Background

Trehalase, an enzyme that hydrolyzes trehalose to yield two glucose molecules, plays a pivotal role in various physiological processes. In recent years, trehalase proteins have been purified from several insect species and are divided into soluble (Tre-1) and membrane-bound (Tre-2) trehalases. However, no functions of the two trehalases in chitin biosynthesis in insects have yet been reported.

Principal Findings

The membrane-bound trehalase of Spodoptera exigua (SeTre-2) was characterized in our laboratory previously. In this study, we cloned the soluble trehalase gene (SeTre-1) and investigated the tissue distribution and developmental expression pattern of the two trehalase genes. SeTre-1 was expressed highly in cuticle and Malpighian tubules, while SeTre-2 was expressed in tracheae and fat body. In the midgut, the two trehalase genes were expressed in different locations. Additionally, the expression profiles of both trehalase mRNAs and their enzyme activities suggest that they may play different roles in chitin biosynthesis. The RNA interference (RNAi) of either SeTre-1 or SeTre-2 was gene-specific and effective, with efficiency rates up to 83% at 72 h post injection. After RNAi of SeTre-1 and SeTre-2, significant higher mortality rates were observed during the larva-pupa stage and pupa-adult stage, and the lethal phenotypes were classified and analyzed. Additionally, the change trends of concentration of trehalose and glucose appeared reciprocally in RNAi-mutants. Moreover, knockdown of SeTre-1 gene largely inhibited the expression of chitin synthase gene A (CHSA) and reduced the chitin content in the cuticle to two-thirds relative to the control insects. The chitin synthase gene B (CHSB) expression, however, was inhibited more by the injection of dsRNA for SeTre-2, and the chitin content in the midgut decreased by about 25%.

Conclusions

SeTre-1 plays a major role in CHSA expression and chitin synthesis in the cuticle, and SeTre-2 has an important role in CHSB expression and chitin synthesis in the midgut.     

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.     

Relationship between feeding,mating, vitellogenin production and vitellogenesis in the tickDermacentor variabilis

Anti-vitellin IgG directed againstDermacentor variabilis egg vitellin was used in sodium dodecyl sulfate polyacrylamide (SDS-PAGE) gradient gel immunoblots to detect the presence of vitellin and its precursor, vitellogenin, in the organs of feeding adults and in the immature stages of this tick. Vitellin polypeptides were found in the egg, larvae, nymph, and in the unfed adult stages of both sexes. Vitellin polypeptides were first detected in the ovary of mated females during the rapid-engorgement feeding, period. These polypeptides were also present in the ovaries of ovipositing females, unmated females fed for extended periods, and fed unmated females that were detached from the host and held for 12 h before dissection. The same anti-vitellin antibody was used in immunoblots to monitor the appearance of vitellogenin in the organs and hemolymph of female ticks. Immunoreactive peptides of vitellogenin were found in the fat body, midgut, and hemolymph of pre-rapid-engorging mated and unmated females. These polypeptides were not found in fed males nor in Malpighian tubes of feeding or ovipositing females Our data supported the following conclusions: 1) presence of immunoreactive vitellogenin in the adult female fat body, hemolymph, and midgut was, dependent upon feeding; 2) in mated feeding females, we could not detect the uptake of vitellogenin by the ovary until rapid engorgement; 3) in unmated females, vitellogenesis did not, begin unless prolonged feeding occurred; and 4) during the early developmental stages of this tick, vitellin served as an embryonic nutrient reserve and as a reserve against starvation between feedings.     

Tickcidal effect of monoclonal antibodies against hemocytes, Om21, in an adult female tick, Ornithodoros moubata (Acari: Argasidae)

In the present study, monoclonal antibodies (mAbs) against adult Ornithodoros moubata hemocytes were established. Afterward, artificial feeding was performed to assess the tickcidal effect of fetal bovine serum meal containing each mAb. As a result, Om21 showed the strongest tickcidal effect on adult female O. moubata. The reactivity of various tick cells and organs, including the hemocyte, midgut, trachea, ovary, fat body, and muscle, to Om21 was then examined by an indirect immunofluorescent antibody test and by immunoelectron microscopy. Om21 reacted with not only hemocytes but also with fat body cells, epidermis, cuticle of the trachea, connective tissue of the muscle, and the basement membrane of the midgut, trachea, fat body, oocyte, and epidermis. These results suggest that Om21 passing through the midgut epithelium induced a tickcidal effect on hemocytes or various organs. However, the target of Om21 could not be identified in the present study. The antihemocyte mAb produced in this study, Om21, may be useful for the immunological control of ticks.