Functional characterization of bursicon receptor and genome-wide analysis for identification of genes affected by bursicon receptor RNAi

Bursicon is an insect neuropeptide hormone that is secreted from the central nervous system into the hemolymph and initiates cuticle tanning. The receptor for bursicon is encoded by the rickets (rk) gene and belongs to the G protein-coupled receptor (GPCR) superfamily. The bursicon and its receptor regulate cuticle tanning as well as wing expansion after adult eclosion. However, the molecular action of bursicon signaling remains unclear. We utilized RNA interference (RNAi) and microarray to study the function of the bursicon receptor (Tcrk) in the model insect, Tribolium castaneum. The data included here showed that in addition to cuticle tanning and wing expansion reported previously, Tcrk is also required for development and expansion of integumentary structures and adult eclosion. Using custom microarrays, we identified 24 genes that are differentially expressed between Tcrk RNAi and control insects. Knockdown in the expression of one of these genes, TC004091, resulted in the arrest of adult eclosion. Identification of genes that are involved in bursicon receptor mediated biological processes will provide tools for future studies on mechanisms of bursicon action.     

昆虫鞣化激素研究进展

鞣化激素是调控昆虫体壁黑化及翅伸展的一类激素, 是由BURS和PBURS两个亚基组成的一种异源二聚体蛋白质。BURS和PBURS亚基在结构及其进化上相对较为保守, 氨基酸序列中均含有11个半胱氨酸残基。鞣化激素主要是在胸腹神经节中合成的, 一旦释放到血淋巴就与其受体LGR2结合进而激活cAMP/PKA信号, 从而促进酪氨酸羟化酶(tyrosine hydroxylase, TH)的磷酸化。活化后的TH将酪氨酸(tyrosine)转变为多巴（DOPA）, 引起昆虫表皮鞣化。同时, cAMP/PKA信号也引起翅真皮细胞凋亡从而促进翅的伸展。除了鞣化激素异聚体调控表皮鞣化及翅的伸展外, BURS亚基或PBURS亚基组成的同源二聚体经IMD路径, 激活转录因子Relish调控昆虫的免疫反应。本文就鞣化激素分子结构特性、 作用机制及功能等方面的研究进展进行了综述, 旨在为进一步研究昆虫鞣化激素提供借鉴和参考。     

From bioassays to Drosophila genetics: strategies for characterizing an essential insect neurohormone, bursicon

We describe the molecular analysis and cellular expression of the insect peptide neurohormone, bursicon. Bursicon triggers the sclerotization of the soft insect cuticle after ecdysis. Using protein elution analyses from SDS gels, we determined the molecular weight of bursicon from different insects to be approximately 30 kDa. Four partial peptide sequences of Periplaneta americana bursicon were obtained from purified nerve cord homogenates separated on two-dimensional gels. Antibodies produced against one of the sequences identified the cellular location of bursicon in different insects and showed that bursicon is co-produced with crustacean cardioactive peptide (CCAP) in the same neurons in all insects tested so far. Additionally, using the partial peptide sequences, we successfully searched the Drosophila genome project for the gene encoding bursicon. With Drosophila as a tool, we can now verify the function of the sequence using transgenic flies. Sequence comparisons also allowed us to verify that bursicon is conserved, corroborating the older data from bioassays and immunohistochemical analyses. The sequence of bursicon will enable further analysis of its function, release, and evolution.     

Identification of the gene encoding bursicon, an insect neuropeptide responsible for cuticle sclerotization and wing spreading

To accommodate growth, insects must periodically replace their exoskeletons. After shedding the old cuticle, the new soft cuticle must sclerotize. Sclerotization has long been known to be controlled by the neuropeptide hormone bursicon, but its large size of 30 kDa has frustrated attempts to determine its sequence and structure. Using partial sequences obtained from purified cockroach bursicon, we identified the Drosophila melanogaster gene CG13419 as a candidate bursicon gene. CG13419 encodes a peptide with a predicted final molecular weight of 15 kDa, which likely functions as a dimer. This predicted bursicon protein belongs to the cystine knot family, which includes vertebrate transforming growth factor-beta (TGF-beta) and glycoprotein hormones. Point mutations in the bursicon gene cause defects in cuticle sclerotization and wing expansion behavior. Bioassays show that these mutants have decreased bursicon bioactivity. In situ hybridization and immunocytochemistry revealed that bursicon is co-expressed with crustacean cardioactive peptide (CCAP). Transgenic flies that lack CCAP neurons also lacked bursicon bioactivity. Our results indicate that CG13419 encodes bursicon, the last of the classic set of insect developmental hormones. It is the first member of the cystine knot family to have a defined function in invertebrates. Mutants show that the spectrum of bursicon actions is broader than formerly demonstrated.     

小菜蛾鞣化激素基因克隆及其功能分析

鞣化激素是调节昆虫表皮骨化和翅膀发育的一种神经激素, 尽管已经在许多不同种昆虫上克隆了鞣化激素基因, 但是关于小菜蛾 Plutella xylostella鞣化激素及其基因的研究至今未见报道。本研究克隆了两个小菜蛾鞣化激素基因Pxbursα和Pxbursβ （GenBank 登录号分别为KF498645和KF498646）全长cDNA, 其序列长度分别为537 bp和360 bp, 与已报道的其他昆虫的鞣化激素氨基酸序列一致性分别为51%~68% 和37%~57%。实时定量PCR分析发现Pxbursα和Pxbursβ均在蛹期表达量高, 而在幼虫期和成虫期的表达量低。以Pxbursα部分序列的双链RNA（dsRNA）饲喂小菜蛾4龄末期幼虫, 发现蛹期Pxbursα的表达受到了显著抑制, 小菜蛾的发育停滞在蛹期而无法正常羽化, 并最终死亡。由此推测, 小菜蛾鞣化激素基因在蛹期的大量表达对其生长发育和羽化具有重要的作用。     

灰飞虱Bursicon基因的克隆、序列分析及在不同发育阶段的表达

Bursicon是通过G蛋白受体调节昆虫表皮硬化及展翅的功能蛋白, 它在昆虫蜕皮后的表皮硬化过程中起着关键作用。为探讨灰飞虱Laodelphax striatellus的 bursicon的功能, 利用RT-PCR和RACE技术克隆获得1 126 bp的bursicon α和761 bp的bursicon β全长序列, 将其分别命名为Lsburs-α和Lsburs-β。生物信息学分析表明： Lsburs-α开放阅读框长483 bp, 编码160个氨基酸, 该蛋白具有2个N-豆蔻酰化位点、 3个酪蛋白激酶Ⅱ磷酸化位点以及2个蛋白激酶C磷酸化位点。Lsburs-β开放阅读框长417 bp, 编码138个氨基酸, 该蛋白具有2个N-豆蔻酰化位点、 3个酪蛋白激酶Ⅱ磷酸化位点以及1个酪氨酸激酶磷酸化位点。qRT-PCR结果表明： Lsburs-α和Lsburs-β在灰飞虱各龄期均有转录表达, 并在若虫期随龄期增加呈上升趋势, 在羽化期达到峰值, 成虫期表达量逐渐降低。结果提示bursicon与灰飞虱蜕皮后的外表皮硬化关系密切。本文结果为深入研究bursicon的功能、受体调节和信号通路等奠定了基础。     

Drosophila molting neurohormone bursicon is a heterodimer and the natural agonist of the orphan receptor DLGR2

Bursicon is a neurohumoral agent responsible for tanning and hardening of the cuticle and expansion of the wings during the final phase of insect metamorphosis. Although the hormonal activity was described more than 40 years ago, the molecular nature of bursicon has remained elusive. We identify here Drosophila bioactive bursicon as a heterodimer made of two cystine knot polypeptides. This conclusion was reached in part from the unexpected observation that in the genome of the honey bee, the orthologs of the two Drosophila proteins are predicted to be fused in a single open reading frame. The heterodimeric Drosophila protein displays bursicon bioactivity in freshly enclosed neck-ligated flies and is the natural agonist of the orphan G protein-coupled receptor DLGR2.     

The essential role of bursicon during <Emphasis Type="Italic">Drosophila</Emphasis>development

Background  

The protective external cuticle of insects does not accommodate growth during development. To compensate for this, the insect life cycle is punctuated by a series of molts. During the molt, a new and larger cuticle is produced underneath the old cuticle. Replacement of the smaller, old cuticle culminates with ecdysis, a stereotyped sequence of shedding behaviors. Following each ecdysis, the new cuticle must expand and harden. Studies from a variety of insect species indicate that this cuticle hardening is regulated by the neuropeptide bursicon. However, genetic evidence from Drosophila melanogaster only supports such a role for bursicon after the final ecdysis, when the adult fly emerges. The research presented here investigates the role that bursicon has at stages of Drosophila development which precede adult ecdysis.     

Activation of the cAMP/PKA signaling pathway is required for post-ecdysial cell death in wing epidermal cells of Drosophila melanogaster

At the last step of metamorphosis in Drosophila, the wing epidermal cells are removed by programmed cell death during the wing spreading behavior after eclosion. The cell death was accompanied by DNA fragmentation demonstrated by the TUNEL assay. Transmission electron microscopy revealed that this cell death exhibited extensive vacuoles, indicative of autophagy. Ectopic expression of an anti-apoptotic gene, p35, inhibited the cell death, indicating the involvement of caspases. Neck ligation and hemolymph injection experiments demonstrated that the cell death is triggered by a hormonal factor secreted just after eclosion. The timing of the hormonal release implies that the hormone to trigger the death might be the insect tanning hormone, bursicon. This was supported by evidence that wing cell death was inhibited by a mutation of rickets, which encodes a G-protein coupled receptor in the glycoprotein hormone family that is a putative bursicon receptor. Furthermore, stimulation of components downstream of bursicon, such as a membrane permeant analog of cAMP, or ectopic expression of constitutively active forms of G proteins or PKA, induced precocious death. Conversely, cell death was inhibited in wing clones lacking G protein or PKA function. Thus, activation of the cAMP/PKA signaling pathway is required for transduction of the hormonal signal that induces wing epidermal cell death after eclosion.     

Model reactions for insect cuticle sclerotization: cross-linking of recombinant cuticular proteins upon their laccase-catalyzed oxidative conjugation with catechols

The quinone-tanning hypothesis for insect cuticle sclerotization proposes that N-acylcatecholamines are oxidized by a phenoloxidase to quinones and quinone methides, which serve as electrophilic cross-linking agents to form covalent cross-links between cuticular proteins. We investigated model reactions for protein cross-linking that occurs during insect cuticle sclerotization using recombinant pupal cuticular proteins from the tobacco hornworm, Manduca sexta, fungal or recombinant hornworm laccase-type phenoloxidase, and the cross-linking agent precursor N-acylcatecholamines, N-beta-alanydopamine (NBAD) or N-acetyldopamine (NADA). Recombinant M. sexta pupal cuticular proteins MsCP36, MsCP20, and MsCP27 were expressed and purified to near homogeneity. Polyclonal antisera to these recombinant proteins recognized the native proteins in crude pharate brown-colored pupal cuticle homogenates. Furthermore, antisera to MsCP36, which contains a type-1 Rebers and Riddiford (RR-1) consensus sequence, also recognized an immunoreactive protein in homogenates of larval head capsule exuviae, indicating the presence of an RR-1 cuticular protein in a very hard, sclerotized and nonpigmented cuticle. All three of the proteins formed small and large oligomers stable to boiling SDS treatment under reducing conditions after reaction with laccase and the N-acylcatecholamines. The optimal reaction conditions for MsCP36 polymerization were 0.3mM MsCP36, 7.4mM NBAD and 1.0U/mul fungal laccase. Approximately 5-10% of the monomer reacted to yield insoluble oligomers and polymers during the reaction, and the monomer also became increasingly insoluble in SDS solution after reaction with the oxidized NBAD. When NADA was used instead of NBAD, less oligomer formation occurred, and most of the protein remained soluble. Radiolabeled NADA became covalently bound to the MsCP36 monomer and oligomers during cross-linking. Recombinant Manduca laccase (MsLac2) also catalyzed the polymerization of MsCP36. These results support the hypothesis that during sclerotization, insect cuticular proteins are oxidatively conjugated with catechols, a posttranslational process termed catecholation, and then become cross-linked, forming oligomers and subsequently polymers.     

Aspects of cuticular sclerotization in the locust, Scistocerca gregaria, and the beetle, Tenebrio molitor

The number of reactive amino groups in cuticular proteins decreases during the early period of insect cuticular sclerotization, presumably due to reaction with oxidation products of N-acetyldopamine (NADA) and N-beta-alanyldopamine (NBAD). We have quantitated the decrease in cuticular N-terminal amino groups and lysine epsilon-amino groups during the first 24h of sclerotization in adult locusts, Schistocerca gregaria, and in larval and adult beetles, Tenebrio molitor, as well as the increase in beta-alanine amino groups in Tenebrio cuticle. The results indicate that nearly all glycine N-terminal groups and a significant part of the epsilon-amino groups from lysine residues are involved in the sclerotization process in both locusts and Tenebrio. A pronounced increase in the amount of free beta-alanine amino groups was observed in cuticle from adult Tenebrio and to a lesser extent also in Tenebrio larval cuticle, but from locust cuticle no beta-alanine was obtained. Hydrolysis of sclerotized cuticles from locusts and Tenebrio by dilute hydrochloric acid released a large number of compounds containing amino acids linked to catecholic moieties. Products have been identified which contain histidine residues linked via their imidazole group to the beta-position of various catechols, such as dopamine, 3,4-dihydroxyphenyl-ethanol (DOPET), and 3,4-dihydroxyphenyl-acetaldehyde (DOPALD), and a ketocatecholic compound has also been identified composed of lysine linked via its epsilon-amino group to the alpha-carbon atom of 3,4-dihydroxyacetophenone. Some of the hydrolysis products have previously been obtained from sclerotized pupal cuticle of Manduca sexta [Xu, R., Huang, X., Hopkins, T.L., Kramer, K.J., 1997. Catecholamine and histidyl protein cross-linked structures in sclerotized insect cuticle. Insect Biochemistry and Molecular Biology 27, 101-108; Kerwin, J.L., Turecek, F., Xu, R., Kramer, K.J., Hopkins, T.L., Gatlin, C.L., Yates, J.R., 1999. Mass spectrometric analysis of catechol-histidine adducts from insect cuticle. Analytical Biochemistry 268, 229-237; Kramer, K.J., Kanost, M.R., Hopkins, T.L., Jiang, H., Zhu, Y.C., Xu, R., Kerwin, J.L., Turecek, F., 2001. Oxidative conjugation of catechols with proteins in insect skeletal systems. Tetrahedron 57, 385-392], but the lysine-dihydroxyacetophenone compound and the histidine-DOPALD adduct have not been reported before. It is suggested that the compounds are derived from NADA and NBAD residues which were incorporated into the cuticle during sclerotization, and that the lysine-dihydroxyacetophenone as well as the DOPET and DOPALD containing adducts are degradation products derived from cross-links between the cuticular proteins, whereas the dopamine-containing adducts are derived from a non-crosslinking reaction product.     

Cuticular sclerotization in larval and adult locusts, Schistocerca gregaria

The sclerotization of both larval and adult cuticle from the desert locust, Schistocerca gregaria, has been studied by measuring the incorporation of radioactive dopamine and N-acetyldopamine into the cuticle. The results are compared with the degree of sclerotization of the cuticle and the amount of sclerotizing enzyme present. The various parts of the cuticle differ considerably with respect to the degree of sclerotization: in adult locusts the mandibles and the dorsal mesothoracic cuticle contain about twenty times as much cross-linking material per mg cuticle than is present in the abdominal tergites and sclerites.The degree of sclerotization in the various types of cuticle is apparently not determined by the amounts of sclerotizing enzyme present, and the rate at which radioactive dopamine or N-acetyldopamine is incorporated into the cuticle appears also to be unrelated to the amount of enzyme.The degree of sclerotization of the various parts of the cuticle from fifth instar larvae corresponds with the amounts of labelled dopamine which are incorporated during the first day after ecdysis, whereas there is no correlation between sclerotization and the amounts of labelled dopamine which are incorporated in older larvae. The degree of sclerotization of adult cuticle after 1 day corresponds to the incorporation of dopamine during the first day. When older animals are compared only little correlation is observed. The relative rates of sclerotization in the various parts of the cuticle must therefore change as the adult insect grows older.The changes in the incorporation pattern during the development of the locust are discussed in relation to the physiological control of the sclerotization process.     

Mass spectrometric analysis of catechol-histidine adducts from insect cuticle

Adducts of catechols and histidine, which are produced by reactions of 1,2-quinones and p-quinone methides with histidyl residues in proteins incorporated into the insect exoskeleton, were characterized using electrospray ionization mass spectrometry (ESMS), tandem electrospray mass spectrometry (ESMS-MS, collision-induced dissociation), and ion trap mass spectrometry (ITMS). Compounds examined included adducts obtained from acid hydrolysates of Manduca sexta (tobacco hornworm) pupal cuticle exuviae and products obtained from model reactions under defined conditions. The ESMS and ITMS spectra of 6-(N-3')-histidyldopamine [6-(N-3')-His-DA, pi isomer] isolated from M. sexta cuticle were dominated by a [M + H]+ ion at m/z 308, rather than the expected m/z 307. High-resolution fast atom bombardment MS yielded an empirical formula of C14H18N3O5, which was consistent with this compound being 6-(N-1')-histidyl-2-(3, 4-dihydroxyphenyl)ethanol [6-(N-1')-His-DOPET] instead of a DA adduct. Similar results were obtained when histidyl-catechol compounds linked at C-7 of the catechol were examined; the (N-1') isomer was confirmed as a DA adduct, and the (N-3') isomer identified as an (N-1')-DOPET derivative. Direct MS analysis of unfractionated cuticle hydrolysate revealed intense parent and product ions characteristic of 6- and 7-linked adducts of histidine and DOPET. Mass spectrometric analysis of model adducts synthesized by electrochemical oxidative coupling of N-acetyldopamine (NADA) quinone and N-acetylhistidine (NAcH) identified the point of attachment in the two isomers. A prominent product ion corresponding to loss of CO2 from [M + H]+ of 2-NAcH-NADA confirmed this as being the (N-3') isomer. Loss of (H2O + CO) from 6-NAcH-NADA suggested that this adduct was the (N-1') isomer. The results support the hypothesis that insect cuticle sclerotization involves the formation of C-N cross-links between histidine residues in cuticular proteins, and both ring and side-chain carbons of three catechols: NADA, N-beta-alanyldopamine, and DOPET.