Comparing thyroid and insect hormone signaling

Transitions between different states of development, physiology,and life history are typically mediated by hormones. In insects,metamorphosis and reproductive maturation are regulated by aninteraction between the sesquiterpenoid juvenile hormone (JH)and the steroid 20-hydroxy-ecdysone (20E). In vertebrates andsome marine invertebrates, the lipophilic thyroid hormones (THs)affect metamorphosis and other life history transitions. Interestingly,when applied to insects, THs can physiologically mimic manyfacets of JH action, suggesting that the molecular actions ofTHs and JH/20E might be similar. Here we discuss functionalparallels between TH and JH/20E signaling in insects, with aparticular focus on the fruit fly, Drosophila melanogaster,a genetically and physiologically tractable model system. Comparingthe effects of THs with the well defined physiological rolesof insect hormones such as JH and 20E in Drosophila might provideimportant insights into hormone function and the evolution ofendocrine signaling.     

中华蜜蜂化学感受蛋白基因Acer-CSP1克隆与表达特征分析

化学感受蛋白(chemosensory proteins, CSPs)是昆虫化学感受系统中重要的组成部分之一。本研究克隆了中华蜜蜂Apis cerana cerana化学感受蛋白基因Acer-CSP1, 其核苷酸全长351 bp （GenBank登录号为FJ157352）, 编码116个氨基酸残基, 预测蛋白分子量为13.85 kD, 等电点为4.89, 且含有4个保守的半胱氨酸残基, 均符合昆虫CSPs的一般特征, 且与意蜂CSP1基因具有99.1%的相似性, 与其他昆虫也有45.3%~68.0%的相似性。利用2^-ΔΔCt法及绝对定量法的real-time PCR技术对Acer-CSP1在中蜂不同器官表达特征进行了研究, 得出的一致结论为Acer-CSP1显著水平地高丰度表达于中华蜜蜂触角, 其次大量表达于头部。由于触角为中华蜜蜂最主要的嗅觉器官, 而头部则具有发达的感觉神经系统和味觉系统, 这也提示Acer-CSP1极有可能参与中华蜜蜂的嗅觉以及其他化学感受功能。     

<Emphasis Type="Italic">odd-skipped</Emphasis> homologs function during gut development in<Emphasis Type="Italic"> C. elegans</Emphasis>

Genes in the odd-skipped (odd) family encode a discrete subset of C2H2 zinc finger proteins that are widely distributed among metazoan phyla. Although the initial member (odd) was identified as a Drosophila pair-rule gene, various homologs are expressed within each of the three germ layers in complex patterns that suggest roles in many pathways beyond segmentation. To further investigate the evolutionary history and extant functions of genes in this family, we have initiated a characterization of two homologs, odd-1 and odd-2, identified in the genome of the nematode, Caenorhabditis elegans. Sequence comparisons with homologs from insects (Drosophila and Anopheles) and mammals suggest that two paralogs were present within an ancestral metazoan; additional insect paralogs and both extant mammalian genes likely resulted from gene duplications that occurred after the split between the arthropods and chordates. Analyses of gene function using RNAi indicate that odd-1 and odd-2 play essential and distinct roles during gut development. Specific expression of both genes in the developing intestine and other cells in the vicinity of the gut was shown using GFP-reporters. These results indicate primary functions for both genes that are most like those of the Drosophila paralogs bowel and drumstick, and support a model in which gut specification represents the ancestral role for genes in this family.Edited by C. Desplan     

Patterning with clocks and genetic cascades: Segmentation and regionalization of vertebrate versus insect body plans

Oscillatory and sequential processes have been implicated in the spatial patterning of many embryonic tissues. For example, molecular clocks delimit segmental boundaries in vertebrates and insects and mediate lateral root formation in plants, whereas sequential gene activities are involved in the specification of regional identities of insect neuroblasts, vertebrate neural tube, vertebrate limb, and insect and vertebrate body axes. These processes take place in various tissues and organisms, and, hence, raise the question of what common themes and strategies they share. In this article, we review 2 processes that rely on the spatial regulation of periodic and sequential gene activities: segmentation and regionalization of the anterior–posterior (AP) axis of animal body plans. We study these processes in species that belong to 2 different phyla: vertebrates and insects. By contrasting 2 different processes (segmentation and regionalization) in species that belong to 2 distantly related phyla (arthropods and vertebrates), we elucidate the deep logic of patterning by oscillatory and sequential gene activities. Furthermore, in some of these organisms (e.g., the fruit fly Drosophila), a mode of AP patterning has evolved that seems not to overtly rely on oscillations or sequential gene activities, providing an opportunity to study the evolution of pattern formation mechanisms.     

Human Intellectual Disability Genes Form Conserved Functional Modules in Drosophila

Intellectual Disability (ID) disorders, defined by an IQ below 70, are genetically and phenotypically highly heterogeneous. Identification of common molecular pathways underlying these disorders is crucial for understanding the molecular basis of cognition and for the development of therapeutic intervention strategies. To systematically establish their functional connectivity, we used transgenic RNAi to target 270 ID gene orthologs in the Drosophila eye. Assessment of neuronal function in behavioral and electrophysiological assays and multiparametric morphological analysis identified phenotypes associated with knockdown of 180 ID gene orthologs. Most of these genotype-phenotype associations were novel. For example, we uncovered 16 genes that are required for basal neurotransmission and have not previously been implicated in this process in any system or organism. ID gene orthologs with morphological eye phenotypes, in contrast to genes without phenotypes, are relatively highly expressed in the human nervous system and are enriched for neuronal functions, suggesting that eye phenotyping can distinguish different classes of ID genes. Indeed, grouping genes by Drosophila phenotype uncovered 26 connected functional modules. Novel links between ID genes successfully predicted that MYCN, PIGV and UPF3B regulate synapse development. Drosophila phenotype groups show, in addition to ID, significant phenotypic similarity also in humans, indicating that functional modules are conserved. The combined data indicate that ID disorders, despite their extreme genetic diversity, are caused by disruption of a limited number of highly connected functional modules.     

To see or not to see: evolution of eye degeneration in mexican blind cavefish

The evolutionary mechanisms responsible for the loss of eyesin cave animals are still unresolved. Hypotheses invoking naturalselection or neutral mutation have been advanced to explaineye regression. Here we describe comparative molecular and developmentalstudies in the teleost Astyanax mexicanus that shed new lighton this problem. A. mexicanus is a single species consistingof a sighted surface-dwelling form (surface fish) and many blindcave-dwelling forms (cavefish) from different caves. We firstreview the evolutionary relationships of Astyanax cavefish populationsand conclude that eye degeneration may have evolved multipletimes. We then compare the mechanisms of eye degeneration indifferent cavefish populations. We describe the results of experimentsshowing that programmed cell death of the lens plays a key rolein controlling eye degeneration in these cavefish populations.We also show that Pax6 gene expression and fate determinationin the optic primordia are modified similarly in different cavefishpopulations, probably due to hyperactive midline signaling.We discuss the contributions of the comparative developmentalapproach toward resolving the evolutionary mechanisms of eyedegeneration. A new hypothesis is presented in which both naturalselection and neutral mutation are proposed to have roles incavefish eye degeneration.     

Metamorphic Competence, a Major Adaptive Convergence in Marine Invertebrate Larvae

Larvae from diverse marine-invertebrate phyla are able to respondrapidly to environmental cues to settlement and to undergo veryrapid metamorphic morphogenesis because they share the developmentaltrait of metamorphic competence. The competent state, characteristicof larvae as diverse as those of cnidarian planulae, molluscanveligers, and barnacle cyprids, is one in which nearly all requisitejuvenile characters are present in the larva prior to settlement.Thus metamorphosis, in response to more or less specific environmentalcues (inducers), is mainly restricted to loss of larva-specificstructures and physiological processes. Competent larvae oftwo "model marine invertebrates" studied in the authors' laboratory,the serpulid polychaete Hydroides elegans and the nudibranchPhestilla sibogae, complete metamorphosis in about 12 and 20hr, respectively. Furthermore, little or no de novo gene actionappears to be required during the metamorphic induction processin these species. Contrasting greatly with the slow, hormonallyregulated metamorphic transitions of vertebrates and insects,competence and consequent rapid metamorphosis in marine invertebratelarvae are conjectured to have arisen in diverse phylogeneticclades because they allow larvae to continue to swim and feedin the planktonic realm while simultaneously permitting extremelyfast morphological transition from larval locomotory and feedingmodes to a different set of such modes that are adaptive tolife on the sea bottom.     

Over-expression of transglutaminase in the Drosophila eye imaginal disc induces a rough eye phenotype

Transglutaminases (TGs) catalyze the cross-linking of proteins and are involved in various biological processes in mammals. In invertebrates, except for the involvement in the hemolymph clotting, the functions of TG have not been revealed. Drosophila has a single TG gene (CG7356), from which two kinds of mRNAs (dTG-RA and dTG-RB) are formed. RT-PCR analyses indicated that both dTGs-RA and -RB are synthesized in all the developmental stages tested. To reveal the roles of dTG during the development, we examined a phenotype induced through the ectopic expression of dTG by using a GAL4-UAS targeted expression system. Over-expression of dTG-A in the eye imaginal disc of larva induced a rough eye phenotype in adult compound eyes. Co-expression of P35, an inhibitor of apoptosis, suppressed the rough eye phenotype, suggesting that the rough eye phenotype induced by the over-expression of dTG-A in the eye imaginal disc is due to the occurrence of apoptosis. The rough eye phenotype induced by the over-expression of dTG-A was suppressed by the crossing with mutant fly lines lacking Drosophila JNK gene basket (bsk) or Drosophila JNKK gene hemipterous. FLP-out experiments using an enhancer trap line showed that the over-expression of dTG-A in the eye imaginal disc increased the puckered enhancer activity, a reporter of Bsk activity. These results suggested that the rough eye phenotype induced by the over-expression of dTG-A is related to an enhancement of JNK signaling pathway.     

家蚕先天免疫基因 Bmimd 的克隆、表达及序列分析

昆虫的先天免疫应答由一组基因通过级联网络调控实现。果蝇 Drosophila 免疫缺陷(immune deficiency, imd)基因在体液免疫信号传递途径中起着重要的作用。我们利用生物信息学方法进行电子克隆,成功地找到了 imd 基因在家蚕 Bombyx mori 中的同源体,命名为 Bmimd。该基因全长1 092 bp,由 4 个外显子和 3 个内含子组成,开放阅读框(open reading frame, ORF)长 750 bp,编码 250 个氨基酸,预测蛋白质分子量为 28.6 kD。Bmimd 序列中含有一个致死结构域,经聚类分析表明该结构域与哺乳动物的受体相互作用蛋白(receptor interacting protein, RIP)相似。将该基因亚克隆到 PET-50b 载体进行原核表达,表达出了带有 2 个 6×His tag 和 1 个 Nus·Tag 标签的重组蛋白。Western blotting 结果表明 Bmimd 蛋白在 5 龄 4 天家蚕的头、脂肪体 、生殖腺、表皮和中肠中都有表达,但丝腺中没有检测到表达。     

家蝇细胞凋亡起始酶Caspase-1基因的克隆及在不同虫态的表达

为了研究Caspases家族在昆虫发育变态中的作用,通过RT-PCR扩增并结合RACE技术,克隆得到家蝇Musca domestica Caspase-1基因1条,命名为Mdom-Caspase-1（GenBank中cDNA序列号为EU854472, 氨基酸序列号为ACF71490）。该基因全长1 295 bp,阅读框序列870 bp,共编码289个氨基酸,理论分子量32.83 kDa,等电点8.67。 Mdom-Caspase-1蛋白有5个保守的半胱氨酸位点QACQG, 具有Caspase的典型特征; 整个分子呈现亲水性, 有8个区域共89个氨基酸为亲酯性, 蛋白质二级结构主要由11个α螺旋区、7个β-折叠区、17个β-转角区组成。昆虫间Caspase-1分子具有明显的保守性, Mdom-Caspase-1与黑腹果蝇Drosophila melanogaster、埃及伊蚊Aedes aegypti和致倦库蚊Culex quinquefasciatus的Caspase-1氨基酸序列相似性为65%~77%。RT-PCR半定量分析结果表明, Mdom-Caspase-1基因在家蝇各个虫态中均有表达, 但在卵期、3龄幼虫、预蛹、蛹和羽化5 d的雌虫中的表达量明显高于其他虫态。这些结果提示Caspase-1可能与昆虫发育变态关系密切, 为进一步研究昆虫Caspase-1功能、设计Caspase-1抑制剂提供了分子基础。     

The Role of Compartmentalization in the Activation of Particular Control Genes and in the Generation of Proximo-Distal Positional Information in Appendages

SYNOPSIS. A mechanism is proposed for the activation of particulargenes during interpretation of positional information and duringsequential addition of new structures during outgrowth. Theprimary event is assumed to be an alternation between two states.The alternation of anterior-posterior-anterior compartmentsin insects or bone-joint-bone in the chicken wing is assumedto be a trace of this primary subdivision into two alternativestates. Each (or each second) transition from one state to theother causes a switch from one structure-controlling gene tothe next. This enables a counting of alternations on the DNA-leveland a high resolution in the corresponding activation of controlgenes. The model explains the formation of compartments andsegmental specification in perfect register. The elements ofthe bithorax gene complex become understandable assuming thismechanism. It is shown further that such a "compartmentalization" can beused for the reproducible generation of subpatterns for thefiner subdivision of a developing embryo. By "cooperation ofcompartments," a cone-shaped morphogen distribution can be generated,accounting, e.g., for the circular arrangement of structuresin the fate map of the leg disk of Drosophila. The most distalstructures are formed at the intersection of compartments anddistal transformation occurs whenever cells of all three orfour major compartments are close to each other.     

Eyes absent: A gene family found in several metazoan phyla

Genes related to the Drosophila eyes absent gene were identified in vertebrates (mouse and human), mollusks (squid), and nematodes (C. elegans). Proteins encoded by these genes consist of conserved C-terminal and variable N-terminal domains. In the conserved 271-amino acid C-terminal region, Drosophila and vertebrate proteins are 65–67% identical. A vertebrate homolog of eyes absent, designated Eya2, was mapped to Chromosome (Chr) 2 in the mouse and to Chr 20q13.1 in human. Eya2 shows a dynamic pattern of expression during development. In the mouse, expression of Eya2 was first detected in 8.5-day embryos in the region of head ectoderm fated to become the forebrain. At later stages of development, Eya2 is expressed in the olfactory placode and in a variety of neural crest derivatives. In the eye, expression of Eya2 was first detected after formation of the lens vesicle. At day 17.5, the highest level of Eya2 mRNA was observed in primary lens fibers. Low levels of Eya2 expression was detected in retina, sclera, and cornea. By postnatal day 10, Eya2 was expressed in secondary lens fibers, cornea, and retina. Although Eya2 is expressed relatively late in eye development, it belongs to the growing list of factors that may be essential for eye development across metazoan phyla. Like members of the Pax-6 gene family, eyes absent gene family members were probably first involved in functions not related to vision, with recruitment for visual system formation and function occurring later. Received: 23 November 1996 / Accepted: 25 February 1997     

Molecular Genetic Analysis of Ethanol Intoxication in Drosophila melanogaster

Recently, the fruit fly Drosophila melanogaster has been introducedas a model system to study the molecular bases of a varietyof ethanol-induced behaviors. It became immediately apparentthat the behavioral changes elicited by acute ethanol exposureare remarkably similar in flies and mammals. Flies show signsof acute intoxication, which range from locomotor stimulationat low doses to complete sedation at higher doses and they developtolerance upon intermittent ethanol exposure. Genetic screensfor mutants with altered responsiveness to ethanol have beencarried out and a few of the disrupted genes have been identified.This analysis, while still in its early stages, has alreadyrevealed some surprising molecular parallels with mammals. Theavailability of powerful tools for genetic manipulation in Drosophila,together with the high degree of conservation at the genomiclevel, make Drosophila a promising model organism to study themechanism by which ethanol regulates behavior and the mechanismsunderlying the organism's adaptation to long-term ethanol exposure.     

Polygenic Control of Drosophila Morphogenesis During the Stages of Determination and Specification of Adult Structures

There are three processes in the development of Drosophila whichmay be studied independendy but which are a manifestation ofinterdependent events which result in the formation of the adultphenotype. These processes are determination, specificationand differentiation. The mutant phenotype Abnormal-abdomen ischaracterized by a loss of abdominal tergites and is controlledby a major mutant gene,A^53g and a polygenic modifier system.The development of the abnormal phenotype is influenced by eventsin early embryogenesis and in mid-larval stages. These developmentallysensitive stages are correlated with the periods of determinationand specification of the cells which constitute the larval histoblastnests and which differentiate into the adult abdominal hypoderm.Evidence for gene control at these two development stages are1) a maternal effect of the genome correlated with changes inthe efficiency of enzymes catalyzing tRNA aminoacylating reactions,2) observations which relate histological defects of embryosat the blastoderm stage to the action of the mutant genotype,and 3) a temperature sensitive period for the expression ofthe abnormal phenotype which has defined limits in the latesecond and early third larval instars. Developmental eventswhich take place during oogenesis, early embryogenesis, andmid-larval stages are discussed with regard to their relationshipto each other and to the final differentiation of the adultphenotype.     

巨尾阿丽蝇在自由状态下的电击回避学习能力(英文)

蜜蜂和果蝇具有良好的学习记忆能力。利用自主改良的研究装置对另一种具有强大生存本能的双翅目昆虫——巨尾阿丽蝇(Aldrichina grahami)在自由状态下电击回避学习能力进行研究。结果表明,巨尾阿丽蝇具有良好的学习记忆能力,因为当刺激电压范围为5V到45V时,观察到巨尾阿丽蝇有显著的回避电刺激行为,而当电压达到60V时会受到明显伤害。由此推测,巨尾阿丽蝇适合作为神经系统研究的动物模型。本实验所采用的实验范例较以往有所改进,适合作为自由状态下研究昆虫的工具。     

Evolution of Eye Regression in the Cavefish Astyanax: Apoptosis and the Pax-6 Gene

SYNOPSIS. The eye is an extraordinary organ in terms of itsdevelopment and evolution. In cave animals, the eye is sometimesreduced or eliminated as a consequence of adaptation to lifein perpetual darkness. We have used the characid teleost Astyanaxmexicanus as a model system to investigate the mechanisms ofeye degeneration during the evolution of a cave vertebrate.Eyed surface populations of Astyanax entered caves during thePleistocene, and their descendants lost their eyes and pigmentation.Astyanax populations exhibiting various degrees of eye regressionhave been reported in 29 Mexican caves. Surface populationswith characteristics of the ancestral stock still exist in thevicinity of these caves. Thus, Astyanax represents one of thefew instances in which the ancestral (surface fish) and thederived (cavefish) developmental modes are extant and availablefor comparative studies. The cavefish embryo develops an opticprimordium consisting of a lens vesicle and optic cup but therudimentary eye arrests in development and degenerates. Herewe report that eye degeneration is accompanied by extensiveapoptosis and downregulation of the Pax-6 gene in the developinglens. The results suggest that alterations in lens developmentare important factors in eye regression during cavefish evolution.