DOCSLIB.ORG

The Role of Nutrition in Creation of the Eye Imaginal Disc and Initiation of Metamorphosis in Manduca Sexta

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
The Role of Nutrition in Creation of the Eye Imaginal Disc and Initiation of Metamorphosis in Manduca Sexta View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by Elsevier - Publisher Connector Developmental Biology 285 (2005) 285 – 297 www.elsevier.com/locate/ydbio The role of nutrition in creation of the eye imaginal disc and initiation of metamorphosis in Manduca sexta Steven G.B. MacWhinniea, J. Paul Alleea, Charles A. Nelsonb, Lynn M. Riddifordb, James W. Trumanb, David T. Champlina,* aDepartment of Biology, University of Southern Maine, 96 Falmouth Street, Portland, ME 04103-9300, USA bDepartment of Biology, University of Washington, 24 Kincaid Hall, Box 351800, Seattle, WA 98195-1800, USA Received for publication 31 May 2005, revised 1 June 2005, accepted 1 June 2005 Available online 15 August 2005 Abstract With the exception of the wing imaginal discs, the imaginal discs of Manduca sexta are not formed until early in the final larval instar. An early step in the development of these late-forming imaginal discs from the imaginal primordia appears to be an irreversible commitment to form pupal cuticle at the next molt. Similar to pupal commitment in other tissues at later stages, activation of broad expression is correlated with pupal commitment in the adult eye primordia. Feeding is required during the final larval instar for activation of broad expression in the eye primordia, and dietary sugar is the specific nutritional cue required. Dietary protein is also necessary during this time to initiate the proliferative program and growth of the eye imaginal disc. Although the hemolymph titer of juvenile hormone normally decreases to low levels early in the final larval instar, eye disc development begins even if the juvenile hormone titer is artificially maintained at high levels. Instead, creation of the late- forming imaginal discs in Manduca appears to be controlled by unidentified endocrine factors whose activation is regulated by the nutritional state of the animal. D 2005 Elsevier Inc. All rights reserved. Keywords: Imaginal disc; Insect metamorphosis; Juvenile hormone; Ecdysteroid; Eye; Manduca sexta Introduction occur (Nijhout, 2003). Early during the final feeding stage, the imaginal primordia initiate proliferative programs to form In holometabolous insects, many adult-specific structures the adult structures (Miles and Booker, 1993; Monsma and are formed from cells that either are set aside early and Booker, 1996; Kremen and Nijhout, 1998; Tanaka and proliferate throughout most of larval life, e.g., the imaginal Truman, 2005; Allee et al., submitted for publication). Later, discs of Drosophila (Cohen, 1993), or form from regions of the animal achieves a critical size, and the endocrine events the larval epidermis during the final larval instar, e.g., the that lead to the cessation of feeding and overt metamorphosis imaginal primordia for the eye, leg, proboscis, and antenna of are set in motion. Lepidoptera (Sehnal et al., 1996; Truman and Riddiford, Insect molting and metamorphosis are governed primarily 1999, 2002). In Lepidoptera, larval growth occurs during a by two hormones, ecdysteroids that cause the molts and species-specific number of instars followed by metamorpho- juvenile hormone (JH) that prevents metamorphic molts sis after attaining an appropriate size (Nijhout, 2003). The (Nijhout, 1994). In the final larval instar of the tobacco final larval instar is determined by the body size at the outset hornworm, Manduca sexta, the JH titer declines to undetect- of the instar, but nutrient intake and further growth are able levels by the time the larva attains its critical size for necessary during this instar in order for metamorphosis to feeding to cease (Nijhout and Williams, 1974a,b; Fain and Riddiford, 1975; Baker et al., 1987; Davidowitz et al., 2003) * Corresponding author. Fax: +1 207 228 8116. (Fig. 1). A small surge of ecdysteroid in the absence of JH E-mail address: [email protected] (D.T. Champlin). causes the cessation of feeding, commitment of the general 0012-1606/$ - see front matter D 2005 Elsevier Inc. All rights reserved. doi:10.1016/j.ydbio.2005.06.021 286 S.G.B. MacWhinnie et al. / Developmental Biology 285 (2005) 285–297 MP Biomedicals, Aurora, OH) that included 100 mg antibiotic/l (tetracycline or streptomycin). Larvae fed mini- mal dietary nutrients were switched at ecdysis to the fifth instar from the normal diet to a 3% non-nutritive agar block or a 3% agar block supplemented with one or two of the following as indicated, 7% sucrose or a 5.8% suspension of Fig. 1. Hemolymph titers of JH and ecdysteroid during the fourth and fifth larval instars, adapted from Riddiford (1994). Dashed line = JH titer in either of two isolates of casein (#1 = #C5679, #2 = #C6554, larvae fed continuously. Double-dotted line = JH titer in larvae removed Sigma-Aldrich, St. Louis, MO) (Jones et al., 1981). from food at ecdysis to the fifth instar (Nijhout and Williams, 1974b; The ages of animals are referenced relative to larval Cymborowski et al., 1982). ecdyses either in hours or days (ecdysis is designated as occurring on Day 0). Lights-off is designated as 00:00 AZT body epidermis to make pupal cuticle at the next molt, and (Arbitrary Zeitgeber Time, Pittendrigh, 1965). onset of wandering to find a pupation site (Riddiford, 1978; Larvae were treated with the JH mimic pyriproxifen Dominick and Truman, 1985). Later, a large ecdysteroid (Valent USA Corporation, Walnut Creek, CA). Ten micro- surge in the presence of JH causes the pupal molt (Fig. 1). If a liters of carrier alone or carrier plus pyriproxifen (1 Ag JH mimic is given at the onset of the small surge of pyriproxifen/Al cyclohexane) was applied topically along ecdysteroid, the larva will molt to a larval–pupal intermedi- the dorsal midline of the thorax at the stage indicated. ate showing a normal larval body with small pupal structures Images were taken on a Leica GZ6 stereo zoom formed by the imaginal primordia (Truman et al., 1974; microscope. Hatakoshi et al., 1988), indicating that the primordia had undergone pupal commitment prior to addition of the JH Analysis of broad expression by qRT-PCR mimic. When larvae are starved early in the instar for several days then fed, many molt to supernumerary larvae showing Total RNA was isolated using the SV total RNA isolation pupal cuticle at sites of the imaginal primordia and on the kit (Promega, Madison, WI) followed by cDNA synthesis wing discs (Nijhout and Williams, 1974b; Jones et al., 1980; with SuperScript II reverse transcriptase (Invitrogen, Carls- Cymborowski et al., 1982; Safranek and Williams, 1984). bad, CA) according to the manufacturer’s instructions using Starvation immediately after ecdysis causes the JH titer to an oligo d(T) primer and 3 Ag of RNA. Quantitative RT- remain high (Cymborowski et al., 1982)(Fig. 1). PCR (qRT-PCR) was done using the Brilliant SYBR Green Our recent study on the early formation of the eye qPCR kit and MX4000 multiplex quantitative PCR system imaginal disc in Manduca showed that the adult eye (Stratagene, La Jolla, CA). qRT-PCR conditions were primordium detaches from the overlying cuticle about 20 optimized for each primer set, and the product confirmed hours (h) after ecdysis to the fifth instar, and about 4 h later, by DNA sequencing. Each histogram shown is the average the cells begin to proliferate and fold inward to form the of nine samples (three independent experiments with each imaginal disc (Allee et al., submitted for publication). Long- cDNA sample amplified in triplicate). The insecticyanin lasting JH mimics given prior to the molt to the fifth instar gene (ins-a) was used as the normalizer. The overall level of had no effect on this development, suggesting that factors insecticyanin remained fairly constant despite the loss of other than the decline of JH in the early final instar are insecticyanin mRNA from the cells of the eye primordium responsible for the initiation of disc development. Here, we by 24 h after ecdysis in normal fed larvae because isolated show that feeding for a minimum of 9–12 h in the fifth tissue included flanking larval epidermal cells that maintain instar is necessary for the adult eye primordium to become high levels of insecticyanin expression (Allee et al., pupally committed and that commitment depends only on submitted for publication). The INS-a4 INS-a5 primer pair intake of sugar during this period. By contrast, the later was used to test for genomic DNA contamination, and no onset of proliferative growth to form the disc occurs only genomic DNA was detected in any cDNA sample when after feeding on a mixture of sugar and amino acids. using the SV total RNA isolation kit. Importantly, the other imaginal primordia have a similar insecticyanin, ins-a gene (Li and Riddiford, 1992) dependence on nutrient intake, indicating that a specific ACCESSION: X64714: signal may be coordinating their responses to nutrition. INS-a1 CAGAGGTTCCTAGTCTTCACCA INS-a2 GTCAGGGCCGGTAAGGCTGTAT Materials and methods Experimental animals and hormone treatments 609 base pair product from cDNA template and 4410 base pair product from genomic DNA template. Larvae of the tobacco hornworm, M. sexta (L.), were reared in individual containers at 26-C under a 17L:7D INS-a4: CACCCTGACAAGAAGGCCCACA photoperiod on an artificial diet (gypsy moth wheat germ diet, INS-a5: CCTAATGGCTGTAAATATGCCAATG S.G.B. MacWhinnie et al. / Developmental Biology 285 (2005) 285–297 287 256 base pair product from genomic DNA template and at room temperature 4 h in PBS with 15 Ag BrdU/ml. After no product from cDNA template. labeling, tissues were fixed overnight at 4-C with 3.7% Broad cDNA Z2-isoform (Zhou et al., 1998) ACCES- formaldehyde in PBS and then acid-treated to expose the SION AF032674: BrdU epitope as described (Champlin and Truman, 1998a). Tissues were then incubated sequentially at 4-C in the Z2F CTATGCGGCAAAGTACTGT following with extensive washes in PBS–0.3% TX between Z2R CCCTGGCCTCGACTTGTGGTAG each step: 2% normal donkey serum overnight; a 1:200 dilution of anti-BrdU monoclonal antibody (Becton-Dick- 165 base pair product from cDNA template.
Load more

Recommended publications
  • Juvenile Hormone Biosynthesis in the Cockroach, Diploptera
    Juvenile hormone biosynthesis in the cockroach, Diploptera punctata: the characterization of the biosynthetic pathway and the regulatory roles of allatostatins and NMDA receptor by Juan Huang A thesis submitted in conformity with the requirements for the degree of Doctor of Philosophy Department of Cell and Systems Biology University of Toronto © Copyright by Juan Huang (2015) Juvenile hormone biosynthesis in the cockroach, Diploptera punctata: the characterization of the biosynthetic pathway and the regulatory roles of allatostatins and NMDA receptor Juan Huang Doctor of Philosophy (2015), Department of Cell and Systems Biology, University of Toronto Abstract The juvenile hormones (JH) play essential roles in regulating growth, development, metamorphosis, ageing, caste differentiation and reproduction in insects. Diploptera punctata, the only truly viviparous cockroach is a well-known model system in the study of JH biosynthesis and its regulation. The physiology of this animal is characterized by very stable and high rates of JH biosynthesis and precise and predictable reproductive events that correlate well with rates of JH production. Many studies have been performed on D. punctata to determine the function of JH. However, the pathway of JH biosynthesis has not been identified. In addition, although many factors are known to regulate JH biosynthesis, the exact mechanisms remain unclear. The aim of my research was to elucidate the JH biosynthetic pathway in D. punctata and study the mechanisms by which allatostatin (AST) and N-methyl-D-aspartate (NMDA) receptor regulate JH production. I have (1) identified genes in the JH biosynthetic pathway, and determined their roles in JH biosynthesis; (2) investigated the mode of action of AST by determining the signaling pathway of AstR and the target of AST action; (3) determined the role of the NMDA receptor in JH biosynthesis using RNA interference and treatment with an NMDA receptor antagonist.
    [Show full text]
  • Histological and Ultrastructural Aspects of Larval Corpus Allatum Of
    Journal of Entomology and Zoology Studies 2018; 6(3): 864-872 E-ISSN: 2320-7078 P-ISSN: 2349-6800 Histological and ultrastructural aspects of larval JEZS 2018; 6(3): 864-872 © 2018 JEZS corpus allatum of Spodoptera littoralis (Boisd.) Received: 15-03-2018 Accepted: 16-04-2018 (Lepidoptera: Noctuidae) treated with Saleh TA diflubenzuron and chromafenozide Biological and Geological Sciences Department, Faculty of Education, Ain Shams University, Egypt Saleh TA, Ahmed KS, El-Bermawy SM, Ismail EH and Abdel-Gawad RM Ahmed KS Abstract Biological and Geological The present investigation was undertaken to follow the two insect growth regulators (IGRs), Sciences Department, diflubenzuron and chromafenozide, possible effects on the histology and ultrastructure aspects of corpus Faculty of Education, th allatum (CA) of 6 instar larvae of Spodoptera littoralis. Therefore, the LC50 (3 ppm of diflubenzuron Ain Shams University, Egypt th th and 0.1 ppm of chromafenozide) were applied to the 4 larval instar. The CA of 6 larval instar treated El-Bermawy SM with LC50 of diflubenzuron appeared with rounded shape and decreased size (265.625 µm width & Biological and Geological 331.25 µm length) and the capsular fibrous sheath (3.380 µm) also reduced. Contradictory, cellular Sciences Department, cortex was increased in size (71.875 µm), as well as glandular cell numbers were increased, and their Faculty of Education, nuclei were lost their spheroid shape. Disturbance in cytoplasmic organelles pushed glandular cell to Ain Shams University, Egypt switch off or to be inactive. Also, damage was pronounced in the CA of the LC50- chromafenozide treated larvae. The present work investigates the high potency and efficacy of the two IGRs towards S.
    [Show full text]
  • University PH.D
    8008772 BRADFIELD, JAMES YOUNG, IV ENDOCRINE CHARACTERIZATION OF ADULT DEVELOPMENT AND DIAPAUSE IN THE TOBACCO HORNWORM The Ohio State University PH.D. 1979 University Microfilms International300 N. Zeeb Road, Ann Arbor, M I 48106 18 Bedford Row, London WC1R 4EJ, England ENDOCRINE CHARACTERIZATION OF ADULT DEVELOPMENT AND DIAPAUSE IN THE TOBACCO HORNWORM DISSERTATION Presented in Partial Fulfillment of the Requirements for the Degree Doctor of Philosophy in the Graduate School of The Ohio State University By James Young Bradfield IV, B.A. ***** The Ohio State University 1979 Reading Committee: '■ Approved By William J. Collins David L. Denlinger — A ■ Adviser David J. Horn Department of Entomology VITA November 5, 1950 Born - Dallas, Texas 1973 B.A., The University of Texas at Austin 1975-1976 Teaching Associate, The Ohio State University, Columbus, Ohio. 1976-1979 Research Associate, The Ohio State University, Columbus, Ohio. PUBLICATIONS Denlinger, D. L., Campbell, J. J., and Bradfield, J. Y. 1979. Stimulatory effect of organic solvents on initiating development in diapausing pupae of the flesh fly Sarcophaqa crassipalpis and the tobacco hornworm Manduca sexta. Physiol. Entomol., in press. Streett, D. A., and Bradfield, J. Y. IV. 1978. Juvenile hormone activity in microsporidians spores. Proc. Xlth Ann. Cong. Invert. Path., pp. 199-200. FIELDS OF STUDY Major Field: Entomology Studies in endocrinology. Asst. Professor-David L. Denlinger. TABLE OF CONTENTS Page VITA .................................................. ii LIST OF TABLES .......................................... iv LIST OF FIGURES ........................................ v INTRODUCTION ............................................ 1 CHAPTER I. ENDOCRINE CONTROL OF INSECT DEVELOPMENT ........... 2 The Principal Endocrine Centers of Insect Development . 3 Endocrinology of Diapause ....................... 12 II. ENDOCRINE REQUIREMENTS FOR ADULT DEVELOPMENT IN THE TOBACCO HORNWORM ...............................
    [Show full text]
  • Evidence for the Existence of Juvenile Hormone in the Horseshoe Crab By
    Evidence for the existence of juvenile hormone in the horseshoe crab by Tracy M. Levin A Thesis Submitted to the Faculty of WORCESTER POLYTECHNIC INSTITUTE in partial fulfillment of the requirements for the Degree of Master of Science in Biotechnology APPROVED: Dr. Daniel G. Gibson Dr. Alexander A. DiIorio Dr. William D. Hobey 2 ABSTRACT Lipid-based hormones known as the juvenile hormones (JH) are ubiquitous among the arthropods, but their presence, functions, and sites of production in the horseshoe crab, Limulus polyphemus, remain unknown. Large size and lack of secondary sex characteristics in adult female horseshoe crabs may indicate continuous growth and molting throughout life, which is the outcome of high JH levels in insects and crustaceans. Here a study was undertaken to detect and localize lipid-based hormones in horseshoe crab hemolymph and tissue. Capillary electrophoresis and RP-HPLC analyses indicate the presence of a JH-like compound in subadult horseshoe crab hemolymph. The compound is present only in much lower amounts in the hemolymph of adult male and adult female horseshoe crabs. Identification of this compound was based on its similar retention time to standard JH, co-migration with added JH, and cross-reactivity with a polyclonal antibody to JH III. In addition, immunohistochemistry was used to localize the production site of this compound. Analysis of neural tissue, the assumed site of production, yielded no reactivity with labeled anti-JH III antiserum. In larval animals, however, reactivity was noted in yolk contained within the digestive tract. Since the larvae are lecithotrophic and feeding only on their yolk reserves, JH in the gut may be maternal, deposited in the egg before laying.
    [Show full text]
  • A New Look at the Nature of Insect Juvenile Hormone with Particular Reference to Studies Carried out in the Czech Republic
    POINT OF VIEW Eur. J. Entomol. 112(4): 567–590, 2015 doi: 10.14411/eje.2015.073 ISSN 1210-5759 (print), 1802-8829 (online) A new look at the nature of insect juvenile hormone with particular reference to studies carried out in the Czech Republic KAREL SLÁMA Biology Centre of Czech Academy of Sciences, Institute of Entomology, Drnovská 507, 161 00 Praha 6, Czech Republic; e-mail: [email protected] Key words. Insects, activation hormone (AH), juvenile hormone (JH), corpus cardiacum (CC), corpus allatum (CA), corpus allatum hormone (CAH), neurosecretory cells (NSC), prothoracic glands (PG), ecdysteroids (Ecd) Abstract. This article is a comprehensive summary of the 50-year history of physiological investigations in the Czech Republic into the mode of action of the corpus allatum hormone (CAH) in insects, which is commonly known as the juvenile hormone (JH). During this period 4000 synthetic JH- mimetic bioanalogues were tested. The sesquiterpenoid epoxy-homofarnesoate (JH-I), which is gener- ally thought to be the true JH of insects, is an excretory product of the male colleterial gland, not an insect hormone. There are two principal hormones produced by the insect neuroendocrine system: activation hormone (AH) produced by neurosecretory cells in the brain and JH secreted by the corpora allata. The prothoracic glands are a subordinated target of JH, not PTTH; they are not involved in the regulation of moulting in insects. The development of larval, pupal and adult structures depends primarily on inherited instructions encoded within the genome, not on high, medium or low concentrations of JH. At the level of epidermal cells, the responses to JH are always “all-or-none” with intermediate forms mosaic mixtures of cells of previous and future developmental stages.
    [Show full text]
  • Insect Metamorphosis
    SMITHSONIAN MISCELLANEOUS COLLECTIONS VOLUME 122, NUMBER 9 INSECT METAMORPHOSIS BY R. E. SNODGRASS Collaborator of the Smithsonian Institution and of the U. S. Department of Agriculture (Publication 4144) CITY OF WASHINGTON PUBLISHED BY THE SMITHSONIAN INSTITUTION APRIL 1, 1954 SMITHSONIAN MISCELLANEOUS COLLECTIONS VOLUME 122, NUMBER 9 INSECT METAMORPHOSIS BY R. E. SNODGRASS Collaborator of the Smithsonian Institution and of the U. S. Department of Agriculture ^<5« *z£>^ (Publication 4144) CITY OF WASHINGTON PUBLISHED BY THE SMITHSONIAN INSTITUTION APRIL 1, 1954 £#e Boti (§<xftimovt (pvtee BALTIMORE, MS., U. S. A. CONTENTS Page Introduction i I. Metamorphosis and classification : . 10 II. Hormones and metamorphosis 13 Secretory cells of the brain 14 The corpora cardiaca, or paracardiaca 14 The corpora allata 16 Pericardial glands 19 Ventral glands of the head 19 The prothoracic glands 20 The ring gland of cyclorrhaphous Diptera 21 The nature of hormonal action 23 III. Apterygota 24 IV. Plecoptera 26 V. Ephemeroptera 28 VI. Odonata 32 VII. Hemiptera 38 VIII. Thysanoptera 44 IX. Oligoneoptera, or typical Endopterygota : Neuroptera to Hymenop- tera 48 X. Larval heteromorphosis 61 Parasites with a planidial stage 62 Coleoptera 62 Neuroptera 66 Strepsiptera 66 Lepidoptera 70 Diptera 70 Hymenoptera 72 Parasites without a planidial stage 75 Diptera 75 Hymenoptera 77 XI. The pupal transformation 82 The epidermis 83 The appendages 86 The alimentary canal 87 The Malpighian tubules 93 The fat body 95 The oenocytes 96 The tracheal system 97 The dorsal blood vessel 98 The nervous system 99 The muscular system 101 XII. Muscle attachments and the nature of the pupa 107 References in INSECT METAMORPHOSIS By R.
    [Show full text]