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1. Enhanced genome assembly and a new official gene set for Tribolium castaneum

Author

Herndon, Nicolae, Shelton, Jennifer, Gerischer, Lizzy, Ioannidis, Panos, Ninova, Maria, Dönitz, Jürgen, Waterhouse, Robert M, Liang, Chun, Damm, Carsten, Siemanowski, Janna, Kitzmann, Peter, Ulrich, Julia, Dippel, Stefan, Oberhofer, Georg, Hu, Yonggang, Schwirz, Jonas, Schacht, Magdalena, Lehmann, Sabrina, Montino, Alice, Posnien, Nico, Gurska, Daniela, Horn, Thorsten, Seibert, Jan, Vargas Jentzsch, Iris M, Panfilio, Kristen A, Li, Jianwei, Wimmer, Ernst A, Stappert, Dominik, Roth, Siegfried, Schröder, Reinhard, Park, Yoonseong, Schoppmeier, Michael, Chung, Ho-Ryun, Klingler, Martin, Kittelmann, Sebastian, Friedrich, Markus, Chen, Rui, Altincicek, Boran, Vilcinskas, Andreas, Zdobnov, Evgeny, Griffiths-Jones, Sam, Ronshaugen, Matthew, Stanke, Mario, Brown, Sue J, and Bucher, Gregor

Subjects
Genetics, Human Genome, Biotechnology, Generic health relevance, Animals, Binding Sites, Computational Biology, Genes, Insect, Genome, Insect, Genomics, MicroRNAs, Molecular Sequence Annotation, Phylogeny, RNA Interference, Reproducibility of Results, Tribolium, Tribolium castaneum, Genome, Genome assembly Tcas5, 2, Reannotation, Gene prediction, Gene set OGS3, RefSeq genome, Gene annotation, microRNA, miRNA, Genome assembly Tcas5.2, Biological Sciences, Information and Computing Sciences, Medical and Health Sciences, Bioinformatics
Abstract

BACKGROUND:The red flour beetle Tribolium castaneum has emerged as an important model organism for the study of gene function in development and physiology, for ecological and evolutionary genomics, for pest control and a plethora of other topics. RNA interference (RNAi), transgenesis and genome editing are well established and the resources for genome-wide RNAi screening have become available in this model. All these techniques depend on a high quality genome assembly and precise gene models. However, the first version of the genome assembly was generated by Sanger sequencing, and with a small set of RNA sequence data limiting annotation quality. RESULTS:Here, we present an improved genome assembly (Tcas5.2) and an enhanced genome annotation resulting in a new official gene set (OGS3) for Tribolium castaneum, which significantly increase the quality of the genomic resources. By adding large-distance jumping library DNA sequencing to join scaffolds and fill small gaps, the gaps in the genome assembly were reduced and the N50 increased to 4753kbp. The precision of the gene models was enhanced by the use of a large body of RNA-Seq reads of different life history stages and tissue types, leading to the discovery of 1452 novel gene sequences. We also added new features such as alternative splicing, well defined UTRs and microRNA target predictions. For quality control, 399 gene models were evaluated by manual inspection. The current gene set was submitted to Genbank and accepted as a RefSeq genome by NCBI. CONCLUSIONS:The new genome assembly (Tcas5.2) and the official gene set (OGS3) provide enhanced genomic resources for genetic work in Tribolium castaneum. The much improved information on transcription start sites supports transgenic and gene editing approaches. Further, novel types of information such as splice variants and microRNA target genes open additional possibilities for analysis.

Published
2020

3. Additional file 2 of Screens in fly and beetle reveal vastly divergent gene sets required for developmental processes

Author

Hakeemi, Muhammad Salim, Ansari, Salim, Teuscher, Matthias, Wei��kopf, Matthias, Gro��mann, Daniela, Kessel, Tobias, D��nitz, J��rgen, Siemanowski, Janna, Wan, Xuebin, Schultheis, Dorothea, Frasch, Manfred, Roth, Siegfried, Schoppmeier, Michael, Klingler, Martin, and Bucher, Gregor

Subjects
animal structures, fungi
Abstract

Additional file 2: Figure S1. Diagram displaying the portion of genes known to be required for the processes in Drosophila, which were tested in Tribolium. Figures S2 and S3. Phylogenetic trees supporting our claim of absence of an ortholog in Drosophila.

Published
2022
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5. MOESM2 of Enhanced genome assembly and a new official gene set for Tribolium castaneum

Author

Herndon, Nicolae, Shelton, Jennifer, Gerischer, Lizzy, Ioannidis, Panos, Ninova, Maria, Dönitz, Jürgen, Waterhouse, Robert, Liang, Chun, Damm, Carsten, Siemanowski, Janna, Kitzmann, Peter, Ulrich, Julia, Dippel, Stefan, Oberhofer, Georg, Yonggang Hu, Schwirz, Jonas, Schacht, Magdalena, Lehmann, Sabrina, Montino, Alice, Posnien, Nico, Gurska, Daniela, Horn, Thorsten, Seibert, Jan, Jentzsch, Iris Vargas, Panfilio, Kristen, Jianwei Li, Wimmer, Ernst, Stappert, Dominik, Roth, Siegfried, Schröder, Reinhard, Yoonseong Park, Schoppmeier, Michael, Ho-Ryun Chung, Klingler, Martin, Kittelmann, Sebastian, Friedrich, Markus, Chen, Rui, Altincicek, Boran, Vilcinskas, Andreas, Zdobnov, Evgeny, Griffiths-Jones, Sam, Ronshaugen, Matthew, Stanke, Mario, Brown, Sue, and Bucher, Gregor

Subjects
ComputingMethodologies_PATTERNRECOGNITION
Abstract

Additional file 2. Details and scripts used for genome assembly and alignment free phylogenetic tree construction.

Published
2020
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6. Large portion of essential genes is missed by screening either fly or beetle indicating unexpected diversity of insect gene function

Author

Hakeemi, Muhammad Salim, primary, Ansari, Salim, additional, Teuscher, Matthias, additional, Weißkopf, Matthias, additional, Großmann, Daniela, additional, Kessel, Tobias, additional, Dönitz, Jürgen, additional, Siemanowski, Janna, additional, Wan, Xuebin, additional, Schultheis, Dorothea, additional, Frasch, Manfred, additional, Roth, Siegfried, additional, Schoppmeier, Michael, additional, Klingler, Martin, additional, and Bucher, Gregor, additional

Published
2021
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7. Suppressor of Hairless and Presenilin phenotypes imply involvement of canonical Notch-signalling in segmentation of the spider Cupiennius salei

Author

Schoppmeier, Michael and Damen, Wim G.M.

Subjects
Spiders -- Research, Spiders -- Genetic aspects, Developmental biology -- Research, Biological sciences
Abstract

Arthropods, vertebrates, and annelids all have a segmented body. Our recent discovery of involvement of Notch-signalling in spider segmentation revived the discussion on the origin of segmented body plans and suggests the sharing of a common genetic program in a common ancestor. Here, we analysed the spider homologues of the Suppressor of Hairless and Presenilin genes, which encode components of the canonical Notch-pathway, to further explore the role of Notch-signalling in spider segmentation. RNAi silencing of two spider Suppressor of Hairless homologues and the spider Presenilin homologue causes severe segmentation phenotypes. The most prominent defect is the consistent breakdown of segmentation after the formation of three (Suppressor of Hairless) or five (Presenilin) opisthosomal segments. These phenotypes indicate that Notch-signalling during spider segmentation likely involves the canonical pathway via Presenilin and Suppressor of Hairless. Furthermore, it implies that Notch-signalling influences both the formation and patterning of the spider segments: it is required for the specification of the posterior segments and for proper specification of the segment boundaries. We argue that alternative, partly redundant, pathways might act in the formation of the anterior segments that are not active in the posterior segments. This suggests that at least some differences exist in the specification of anterior and posterior segments of the spider, a finding that may be valid for most short germ arthropods. Our data provide additional evidence for the similarities of Notch-signalling in spider segmentation and vertebrate somitogenesis and strengthen our previous notion that the formation of the segments in arthropods and vertebrates might have shared a genetic program in a common ancestor. Keywords: Delta; Somitogenesis; Arthropod evolution; hairy; Drosophila

Published
2005

8. Enhanced genome assembly and a new official gene set for Tribolium castaneum

Author

Herndon, Nicolae, primary, Shelton, Jennifer, additional, Gerischer, Lizzy, additional, Ioannidis, Panos, additional, Ninova, Maria, additional, Dönitz, Jürgen, additional, Waterhouse, Robert M., additional, Liang, Chun, additional, Damm, Carsten, additional, Siemanowski, Janna, additional, Kitzmann, Peter, additional, Ulrich, Julia, additional, Dippel, Stefan, additional, Oberhofer, Georg, additional, Hu, Yonggang, additional, Schwirz, Jonas, additional, Schacht, Magdalena, additional, Lehmann, Sabrina, additional, Montino, Alice, additional, Posnien, Nico, additional, Gurska, Daniela, additional, Horn, Thorsten, additional, Seibert, Jan, additional, Jentzsch, Iris M. Vargas, additional, Panfilio, Kristen A., additional, Li, Jianwei, additional, Wimmer, Ernst A., additional, Stappert, Dominik, additional, Roth, Siegfried, additional, Schröder, Reinhard, additional, Park, Yoonseong, additional, Schoppmeier, Michael, additional, Chung, Ho-Ryun, additional, Klingler, Martin, additional, Kittelmann, Sebastian, additional, Friedrich, Markus, additional, Chen, Rui, additional, Altincicek, Boran, additional, Vilcinskas, Andreas, additional, Zdobnov, Evgeny, additional, Griffiths-Jones, Sam, additional, Ronshaugen, Matthew, additional, Stanke, Mario, additional, Brown, Sue J., additional, and Bucher, Gregor, additional

Published
2019
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10. Opposing effects of Notch-signaling in maintaining the proliferative state of follicle cells in the telotrophic ovary of the beetle Tribolium

Author

Bäumer Daniel, Ströhlein Nadi M, and Schoppmeier Michael

Subjects
Tribolium, Telotrophic oogenesis, Follicle cells, Axis formation, Notch-signaling, Zoology, QL1-991
Abstract

Abstract Introduction Establishment of distinct follicle cell fates at the early stages of Drosophila oogenesis is crucial for achieving proper morphology of individual egg chambers. In Drosophila oogenesis, Notch-signaling controls proliferation and differentiation of follicular cells, which eventually results in the polarization of the anterior-posterior axis of the oocyte. Here we analyzed the functions of Tribolium Notch-signaling factors during telotrophic oogenesis, which differs fundamentally from the polytrophic ovary of Drosophila. Results We found Notch-signaling to be required for maintaining the mitotic cycle of somatic follicle cells. Upon Delta RNAi, follicle cells enter endocycle prematurely, which affects egg-chamber formation and patterning. Interestingly, our results indicate that Delta RNAi phenotypes are not solely due to the premature termination of cell proliferation. Therefore, we monitored the terminal/stalk cell precursor lineage by molecular markers. We observed that upon Delta RNAi terminal and stalk cell populations were absent, suggesting that Notch-signaling is also required for the specification of follicle cell populations, including terminal and stalk precursor cells. Conclusions We demonstrate that with respect to mitotic cycle/endocycle switch Notch-signaling in Tribolium and Drosophila has opposing effects. While in Drosophila a Delta-signal brings about the follicle cells to leave mitosis, Notch-signaling in Triboliumis necessary to retain telotrophic egg-chambers in an “immature” state. In most instances, Notch-signaling is involved in maintaining undifferentiated (or preventing specialized) cell fates. Hence, the role of Notch in Tribolium may reflectthe ancestral function of Notch-signaling in insect oogenesis. The functions of Notch-signaling in patterning the follicle cell epithelium suggest that Tribolium oogenesis may - analogous to Drosophila - involve the stepwise determination of different follicle cell populations. Moreover, our results imply that Notch-signaling may contribute at least to some aspects of oocyte polarization and AP axis also in telotrophic oogenesis.

Published
2012
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11. Enhanced genome assembly and a new official gene set for Tribolium castaneum - from a draft to a reference genome

Author

Herndon, Nicolae, primary, Shelton, Jennifer, additional, Gerischer, Lizzy, additional, Ioannidis, Panos, additional, Ninova, Maria, additional, Dönitz, Jürgen, additional, Waterhouse, Robert M., additional, Liang, Chun, additional, Damm, Carsten, additional, Siemanowski, Janna, additional, Kitzmann, Peter, additional, Ulrich, Julia, additional, Dippel, Stefan, additional, Oberhofer, Georg, additional, Hu, Yonggang, additional, Schwirz, Jonas, additional, Schacht, Magdalena, additional, Lehmann, Sabrina, additional, Montino, Alice, additional, Posnien, Nico, additional, Gurska, Daniela, additional, Horn, Thorsten, additional, Seibert, Jan, additional, Jentzsch, Iris M. Vargas, additional, Panfilio, Kristen A., additional, Li, Jianwei, additional, Wimmer, Ernst A., additional, Stappert, Dominik, additional, Roth, Siegfried, additional, Schröder, Reinhard, additional, Park, Yoonseong, additional, Schoppmeier, Michael, additional, Klingler, Martin, additional, Chung, Ho-Ryun, additional, Kittelmann, Sebastian, additional, Friedrich, Markus, additional, Chen, Rui, additional, Altincicek, Boran, additional, Vilcinskas, Andreas, additional, Zdobnov, Evgeny, additional, Griffiths-Jones, Sam, additional, Ronshaugen, Matthew, additional, Stanke, Mario, additional, Brown, Sue J., additional, and Bucher, Gregor, additional

Published
2019
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12. Duplicated Hox genes in the spider Cupiennius salei

Author

Schoppmeier Michael, Schwager Evelyn E, Pechmann Matthias, and Damen Wim GM

Subjects
Zoology, QL1-991
Abstract

Abstract Background Hox genes are expressed in specific domains along the anterior posterior body axis and define the regional identity. In most animals these genes are organized in a single cluster in the genome and the order of the genes in the cluster is correlated with the anterior to posterior expression of the genes in the embryo. The conserved order of the various Hox gene orthologs in the cluster among most bilaterians implies that such a Hox cluster was present in their last common ancestor. Vertebrates are the only metazoans so far that have been shown to contain duplicated Hox clusters, while all other bilaterians seem to possess only a single cluster. Results We here show that at least three Hox genes of the spider Cupiennius salei are present as two copies in this spider. In addition to the previously described duplicated Ultrabithorax gene, we here present sequence and expression data of a second Deformed gene, and of two Sex comb reduced genes. In addition, we describe the sequence and expression of the Cupiennius proboscipedia gene. The spider Cupiennius salei is the first chelicerate for which orthologs of all ten classes of arthropod Hox genes have been described. The posterior expression boundary of all anterior Hox genes is at the tagma border of the prosoma and opisthosoma, while the posterior boundary of the posterior Hox genes is at the posterior end of the embryo. Conclusion The presence of at least three duplicated Hox genes points to a major duplication event in the lineage to this spider, perhaps even of the complete Hox cluster as has taken place in the lineage to the vertebrates. The combined data of all Cupiennius Hox genes reveal the existence of two distinct posterior expression boundaries that correspond to morphological tagmata boundaries.

Published
2007
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13. TC003132 is essential for the follicle stem cell lineage in telotrophic Tribolium oogenesis

Author

Teuscher, Matthias, Ströhlein, Nadi, Birkenbach, Markus, Schultheis, Dorothea, and Schoppmeier, Michael

Subjects
Tribolium, iBeetle, ddc:570, Research, large-scale RNAi screen, lcsh:Zoology, fungi, telotrophic oogenesis, Notch-signalling, lcsh:QL1-991, Naturwissenschaftliche Fakultät, follicle stem cells
Abstract

Background Stem cells are undifferentiated cells with a potential for self-renewal, which are essential to support normal development and homeostasis. To gain insight into the molecular mechanisms underlying adult stem cell biology and organ evolution, we use the telotrophic ovary of the beetle Tribolium. To this end, we participated in a large-scale RNAi screen in the red flour beetle Tribolium, which identified functions in embryonic and postembryonic development for more than half of the Tribolium genes. Results We identified TC003132 as candidate gene for the follicle stem cell linage in telotrophic Tribolium oogenesis. TC003132 belongs to the Casein Kinase 2 substrate family (CK2S), which in humans is associated with the proliferative activity of different cancers. Upon TC003132 RNAi, central pre-follicular cells are lost, which results in termination of oogenesis. Given that also Notch-signalling is required to promote the mitotic activity of central pre-follicular cells, we performed epistasis experiments with Notch and cut. In addition, we identified a putative follicle stem cell population by monitoring the mitotic pattern of wild type and TC003132 depleted follicle cells by EdU incorporations. In TC003132 RNAi these putative FSCs cease the expression of differentiation makers and are eventually lost. Conclusions TC003132 depleted pre-follicular cells neither react to mitosis or endocycle stimulating signals, suggesting that TC003132 provides competence for differentiation cues. This may resemble the situation in C. elegans were CK2 is required to maintain the balance between proliferation and differentiation in the germ line. Since the earliest effect of TC003132 RNAi is characterized by the loss of putative FSCs, we posit that TC003132 crucially contributes to the proliferation or maintenance of follicle stem cells in the telotrophic Tribolium ovary. Electronic supplementary material The online version of this article (doi:10.1186/s12983-017-0212-2) contains supplementary material, which is available to authorized users.

Published
2017

16. The iBeetle large-scale RNAi screen reveals gene functions for insect development and physiology

Author

Schmitt-Engel, Christian, Schultheis, Dorothea, Schwirz, Jonas, Ströhlein, Nadi, Troelenberg, Nicole, Majumdar, Upalparna, Dao, Van Anh, Grossmann, Daniela, Richter, Tobias, Tech, Maike, Dönitz, Jürgen, Gerischer, Lizzy, Theis, Mirko, Schild, Inga, Trauner, Jochen, Koniszewski, Nikolaus D. B., Küster, Elke, Kittelmann, Sebastian, Hu, Yonggang, Lehmann, Sabrina, Siemanowski, Janna, Ulrich, Julia, Panfilio, Kristen A., Schröder, Reinhard, Morgenstern, Burkhard, Stanke, Mario, Buchhholz, Frank, Frasch, Manfred, Roth, Siegfried, Wimmer, Ernst A., Schoppmeier, Michael, Klingler, Martin, and Bucher, Gregor

Subjects
Tribolium, animal structures, fungi, Metamorphosis, Biological, Pupa, Embryonic Development, High-Throughput Nucleotide Sequencing, Article, Coleoptera, Oogenesis, Larva, Animals, Insect Proteins, RNA Interference, insect development, physiology, iBeetle, large-scale RNAi screen
Abstract

Genetic screens are powerful tools to identify the genes required for a given biological process. However, for technical reasons, comprehensive screens have been restricted to very few model organisms. Therefore, although deep sequencing is revealing the genes of ever more insect species, the functional studies predominantly focus on candidate genes previously identified in Drosophila, which is biasing research towards conserved gene functions. RNAi screens in other organisms promise to reduce this bias. Here we present the results of the iBeetle screen, a large-scale, unbiased RNAi screen in the red flour beetle, Tribolium castaneum, which identifies gene functions in embryonic and postembryonic development, physiology and cell biology. The utility of Tribolium as a screening platform is demonstrated by the identification of genes involved in insect epithelial adhesion. This work transcends the restrictions of the candidate gene approach and opens fields of research not accessible in Drosophila., Unbiased screening for insect gene function has been largely restricted to Drosophila. Here, Schmitt-Engel et al. perform an unbiased large-scale RNAi screen in the red flour beetle Tribolium castaneum to identify putative gene functions.

Published
2015

17. The iBeetle large-scale RNAi screen reveals gene functions for insect development and physiology

Author

Schmitt-Engel, Christian, primary, Schultheis, Dorothea, additional, Schwirz, Jonas, additional, Ströhlein, Nadi, additional, Troelenberg, Nicole, additional, Majumdar, Upalparna, additional, Dao, Van Anh, additional, Grossmann, Daniela, additional, Richter, Tobias, additional, Tech, Maike, additional, Dönitz, Jürgen, additional, Gerischer, Lizzy, additional, Theis, Mirko, additional, Schild, Inga, additional, Trauner, Jochen, additional, Koniszewski, Nikolaus D. B., additional, Küster, Elke, additional, Kittelmann, Sebastian, additional, Hu, Yonggang, additional, Lehmann, Sabrina, additional, Siemanowski, Janna, additional, Ulrich, Julia, additional, Panfilio, Kristen A., additional, Schröder, Reinhard, additional, Morgenstern, Burkhard, additional, Stanke, Mario, additional, Buchhholz, Frank, additional, Frasch, Manfred, additional, Roth, Siegfried, additional, Wimmer, Ernst A., additional, Schoppmeier, Michael, additional, Klingler, Martin, additional, and Bucher, Gregor, additional

Published
2015
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18. Exploring systemic RNA interference in insects: a genome-wide survey for RNAi genes in Tribolium

Author

Tomoyasu, Yoshinori, Miller, Sherry C., Tomita, Shuichiro, Schoppmeier, Michael, Grossmann, Daniela, and Bucher, Gregor

Subjects
animal structures, fungi, SX 000
Abstract

Subject areas: Evolution, Genetics, Genome studies, Molecular biology Background: RNA interference (RNAi) is a highly conserved cellular mechanism. In some organisms, such as Caenorhabditis elegans, the RNAi response can be transmitted systemically. Some insects also exhibit a systemic RNAi response. However, Drosophila, the leading insect model organism, does not show a robust systemic RNAi response, necessitating another model system to study the molecular mechanism of systemic RNAi in insects. Results: We used Tribolium, which exhibits robust systemic RNAi, as an alternative model system. We have identified the core RNAi genes, as well as genes potentially involved in systemic RNAi, from the Tribolium genome. Both phylogenetic and functional analyses suggest that Tribolium has a somewhat larger inventory of core component genes than Drosophila, perhaps allowing a more sensitive response to double-stranded RNA (dsRNA). We also identified three Tribolium homologs of C. elegans sid-1, which encodes a possible dsRNA channel. However, detailed sequence analysis has revealed that these Tribolium homologs share more identity with another C. elegans gene, tag-130. We analyzed tag-130 mutants, and found that this gene does not have a function in systemic RNAi in C. elegans. Likewise, the Tribolium sid-like genes do not seem to be required for systemic RNAi. These results suggest that insect sid-1-like genes have a different function than dsRNA uptake. Moreover, Tribolium lacks homologs of several genes important for RNAi in C. elegans. Conclusion: Although both Tribolium and C. elegans show a robust systemic RNAi response, our genome-wide survey reveals significant differences between the RNAi mechanisms of these organisms. Thus, insects may use an alternative mechanism for the systemic RNAi response. Understanding this process would assist with rendering other insects amenable to systemic RNAi, and may influence pest control approaches. peerReviewed

Published
2008

20. Untersuchungen zu funktionell konservierten sowie divergenten Mechanismen des Segmentierungsprozesses der Arthropoden am Beispiel der Spinne Cupiennius salei

Author

Schoppmeier, Michael

Subjects
ddc:570
Abstract

Das Ziel der vorliegenden Arbeit war es, die molekularen Segmentierungsmechanismen der Spinne Cupiennius salei zu untersuchen, um so funktionell konservierte und divergente Aspekte der Arthropoden Segmentierung zu bestimmen und Aussagen über die Evolution des Segmentierungsprozesses zu ermöglichen. Hierbei wurden die Expressionsmuster verschiedener Cupiennius Paar-Regel und Gap Gen Homologe untersucht und funktionelle Analysen dieser Gene durchgeführt. Zudem wurde auch die Rolle der Notch-Signalkaskade während der Spinnen Segmentierung untersucht, um mögliche Gemeinsamkeiten mit dem Segmentierungsprozess der Vertebraten zu bestimmen. Die vorliegenden Ergebnisse zu den Paar-Regel und Gap Gen Homologen der Spinne lassen vermuten, dass die aus Drosophila bekannte Segmentierungsgenkaskade nicht vollständig konserviert ist. So konnte für die Cupiennius Krüppel Gene keine klassische Gap Funktion nachgewiesen werden. Im Fall des Paar-Regel Gen Homologs pairberry-3 lassen die Daten darauf schließen, dass die Segmente des Opisthosomas einzeln von der Wachstumszone abgespalten werden. Somit scheint zumindest für das Opisthosoma kein doppelsegmentaler Mechanismus vorzuliegen. Eine wichtige Rolle beim Segmentierungsprozess der Spinne übernimmt die Notch-Signalkaskade. Diese ist nicht nur an der Etablierung der Segmente sowie deren Grenzen beteiligt, sondern reguliert auch die dynamische Expression des Cupiennius Paar-Regel Gen Homologs hairy. Obwohl nicht ausgeschlossen werden kann, dass die Beteiligung der Notch-Signalkaskade an der Segmentierung der Spinne und der Vertebraten auf ein unabhängiges Rekrutierungsereignis zurückzuführen ist, liefern diese Ergebnisse doch einen starken Hinweis auf einen gemeinsamen Ursprung des Segmentierungsprozesses.

Published
2003

21. The genome of the model beetle and pest Tribolium castaneum.

Author

Richards, Stephen, Gibbs, Richard A, Weinstock, George M, Brown, Susan J, Denell, Robin, Beeman, Richard W, Gibbs, Richard, Bucher, Gregor, Friedrich, Markus, Grimmelikhuijzen, Cornelis J P, Klingler, Martin, Lorenzen, Marce, Roth, Siegfried, Schröder, Reinhard, Tautz, Diethard, Zdobnov, Evgeny M, Muzny, Donna, Attaway, Tony, Bell, Stephanie, Buhay, Christian J, Chandrabose, Mimi N, Chavez, Dean, Clerk-Blankenburg, Kerstin P, Cree, Andrew, Dao, Marvin, Davis, Clay, Chacko, Joseph, Dinh, Huyen, Dugan-Rocha, Shannon, Fowler, Gerald, Garner, Toni T, Garnes, Jeffrey, Gnirke, Andreas, Hawes, Alica, Hernandez, Judith, Hines, Sandra, Holder, Michael, Hume, Jennifer, Jhangiani, Shalini N, Joshi, Vandita, Khan, Ziad Mohid, Jackson, LaRonda, Kovar, Christie, Kowis, Andrea, Lee, Sandra, Lewis, Lora R, Margolis, Jon, Morgan, Margaret, Nazareth, Lynne V, Nguyen, Ngoc, Okwuonu, Geoffrey, Parker, David, Ruiz, San-Juana, Santibanez, Jireh, Savard, Joël, Scherer, Steven E, Schneider, Brian, Sodergren, Erica, Vattahil, Selina, Villasana, Donna, White, Courtney S, Wright, Rita, Park, Yoonseong, Lord, Jeff, Oppert, Brenda, Brown, Susan, Wang, Liangjiang, Weinstock, George, Liu, Yue, Worley, Kim, Elsik, Christine G, Reese, Justin T, Elhaik, Eran, Landan, Giddy, Graur, Dan, Arensburger, Peter, Atkinson, Peter, Beidler, Jim, Demuth, Jeffery P, Drury, Douglas W, Du, Yu-Zhou, Fujiwara, Haruhiko, Maselli, Vincenza, Osanai, Mizuko, Robertson, Hugh M, Tu, Zhijian, Wang, Jian-jun, Wang, Suzhi, Song, Henry, Zhang, Lan, Werner, Doreen, Stanke, Mario, Morgenstern, Burkhard, Solovyev, Victor, Kosarev, Peter, Brown, Garth, Chen, Hsiu-Chuan, Ermolaeva, Olga, Hlavina, Wratko, Kapustin, Yuri, Kiryutin, Boris, Kitts, Paul, Maglott, Donna, Pruitt, Kim, Sapojnikov, Victor, Souvorov, Alexandre, Mackey, Aaron J, Waterhouse, Robert M, Wyder, Stefan, Kriventseva, Evgenia V, Kadowaki, Tatsuhiko, Bork, Peer, Aranda, Manuel, Bao, Riyue, Beermann, Anke, Berns, Nicola, Bolognesi, Renata, Bonneton, François, Bopp, Daniel, Butts, Thomas, Chaumot, Arnaud, Denell, Robin E, Ferrier, David E K, Gordon, Cassondra M, Jindra, Marek, Lan, Que, Lattorff, H Michael G, Laudet, Vincent, von Levetsow, Cornelia, Liu, Zhenyi, Lutz, Rebekka, Lynch, Jeremy A, da Fonseca, Rodrigo Nunes, Posnien, Nico, Reuter, Rolf, Schinko, Johannes B, Schmitt, Christian, Schoppmeier, Michael, Shippy, Teresa D, Simonnet, Franck, Marques-Souza, Henrique, Tomoyasu, Yoshinori, Trauner, Jochen, Van der Zee, Maurijn, Vervoort, Michel, Wittkopp, Nadine, Wimmer, Ernst A, Yang, Xiaoyun, Jones, Andrew K, Sattelle, David B, Ebert, Paul R, Nelson, David, Scott, Jeffrey G, Muthukrishnan, Subbaratnam, Kramer, Karl J, Arakane, Yasuyuki, Zhu, Qingsong, Hogenkamp, David, Dixit, Radhika, Jiang, Haobo, Zou, Zhen, Marshall, Jeremy, Elpidina, Elena, Vinokurov, Konstantin, Oppert, Cris, Evans, Jay, Lu, Zhiqiang, Zhao, Picheng, Sumathipala, Niranji, Altincicek, Boran, Vilcinskas, Andreas, Williams, Michael, Hultmark, Dan, Hetru, Charles, Hauser, Frank, Cazzamali, Giuseppe, Williamson, Michael, Li, Bin, Tanaka, Yoshiaki, Predel, Reinhard, Neupert, Susanne, Schachtner, Joachim, Verleyen, Peter, Raible, Florian, Walden, Kimberly K O, Angeli, Sergio, Forêt, Sylvain, Schuetz, Stefan, Maleszka, Ryszard, Miller, Sherry C, Grossmann, Daniela, Richards, Stephen, Gibbs, Richard A, Weinstock, George M, Brown, Susan J, Denell, Robin, Beeman, Richard W, Gibbs, Richard, Bucher, Gregor, Friedrich, Markus, Grimmelikhuijzen, Cornelis J P, Klingler, Martin, Lorenzen, Marce, Roth, Siegfried, Schröder, Reinhard, Tautz, Diethard, Zdobnov, Evgeny M, Muzny, Donna, Attaway, Tony, Bell, Stephanie, Buhay, Christian J, Chandrabose, Mimi N, Chavez, Dean, Clerk-Blankenburg, Kerstin P, Cree, Andrew, Dao, Marvin, Davis, Clay, Chacko, Joseph, Dinh, Huyen, Dugan-Rocha, Shannon, Fowler, Gerald, Garner, Toni T, Garnes, Jeffrey, Gnirke, Andreas, Hawes, Alica, Hernandez, Judith, Hines, Sandra, Holder, Michael, Hume, Jennifer, Jhangiani, Shalini N, Joshi, Vandita, Khan, Ziad Mohid, Jackson, LaRonda, Kovar, Christie, Kowis, Andrea, Lee, Sandra, Lewis, Lora R, Margolis, Jon, Morgan, Margaret, Nazareth, Lynne V, Nguyen, Ngoc, Okwuonu, Geoffrey, Parker, David, Ruiz, San-Juana, Santibanez, Jireh, Savard, Joël, Scherer, Steven E, Schneider, Brian, Sodergren, Erica, Vattahil, Selina, Villasana, Donna, White, Courtney S, Wright, Rita, Park, Yoonseong, Lord, Jeff, Oppert, Brenda, Brown, Susan, Wang, Liangjiang, Weinstock, George, Liu, Yue, Worley, Kim, Elsik, Christine G, Reese, Justin T, Elhaik, Eran, Landan, Giddy, Graur, Dan, Arensburger, Peter, Atkinson, Peter, Beidler, Jim, Demuth, Jeffery P, Drury, Douglas W, Du, Yu-Zhou, Fujiwara, Haruhiko, Maselli, Vincenza, Osanai, Mizuko, Robertson, Hugh M, Tu, Zhijian, Wang, Jian-jun, Wang, Suzhi, Song, Henry, Zhang, Lan, Werner, Doreen, Stanke, Mario, Morgenstern, Burkhard, Solovyev, Victor, Kosarev, Peter, Brown, Garth, Chen, Hsiu-Chuan, Ermolaeva, Olga, Hlavina, Wratko, Kapustin, Yuri, Kiryutin, Boris, Kitts, Paul, Maglott, Donna, Pruitt, Kim, Sapojnikov, Victor, Souvorov, Alexandre, Mackey, Aaron J, Waterhouse, Robert M, Wyder, Stefan, Kriventseva, Evgenia V, Kadowaki, Tatsuhiko, Bork, Peer, Aranda, Manuel, Bao, Riyue, Beermann, Anke, Berns, Nicola, Bolognesi, Renata, Bonneton, François, Bopp, Daniel, Butts, Thomas, Chaumot, Arnaud, Denell, Robin E, Ferrier, David E K, Gordon, Cassondra M, Jindra, Marek, Lan, Que, Lattorff, H Michael G, Laudet, Vincent, von Levetsow, Cornelia, Liu, Zhenyi, Lutz, Rebekka, Lynch, Jeremy A, da Fonseca, Rodrigo Nunes, Posnien, Nico, Reuter, Rolf, Schinko, Johannes B, Schmitt, Christian, Schoppmeier, Michael, Shippy, Teresa D, Simonnet, Franck, Marques-Souza, Henrique, Tomoyasu, Yoshinori, Trauner, Jochen, Van der Zee, Maurijn, Vervoort, Michel, Wittkopp, Nadine, Wimmer, Ernst A, Yang, Xiaoyun, Jones, Andrew K, Sattelle, David B, Ebert, Paul R, Nelson, David, Scott, Jeffrey G, Muthukrishnan, Subbaratnam, Kramer, Karl J, Arakane, Yasuyuki, Zhu, Qingsong, Hogenkamp, David, Dixit, Radhika, Jiang, Haobo, Zou, Zhen, Marshall, Jeremy, Elpidina, Elena, Vinokurov, Konstantin, Oppert, Cris, Evans, Jay, Lu, Zhiqiang, Zhao, Picheng, Sumathipala, Niranji, Altincicek, Boran, Vilcinskas, Andreas, Williams, Michael, Hultmark, Dan, Hetru, Charles, Hauser, Frank, Cazzamali, Giuseppe, Williamson, Michael, Li, Bin, Tanaka, Yoshiaki, Predel, Reinhard, Neupert, Susanne, Schachtner, Joachim, Verleyen, Peter, Raible, Florian, Walden, Kimberly K O, Angeli, Sergio, Forêt, Sylvain, Schuetz, Stefan, Maleszka, Ryszard, Miller, Sherry C, and Grossmann, Daniela

Abstract

Tribolium castaneum is a representative of earth’s most numerous eukaryotic order, a powerful model organism for the study of generalized insect development, and also an important pest of stored agricultural products. We describe its genome sequence here. This omnivorous beetle has evolved an ability to interact with a diverse chemical environment as evidenced by large expansions in odorant and gustatory receptors, as well as p450 and other detoxification enzymes. Developmental patterns in Tribolium are more representative of other arthropods than those found in Drosophila, a fact represented in gene content and function. For one, Tribolium has retained more ancestral genes involved in cell-cell communication than Drosophila, and some are expressed in the growth zone crucial for axial elongation in short germ development. Systemic RNAi in T. castaneum appears to use mechanisms distinct from those found in C. elegans, but nevertheless offers similar power for the elucidation of gene function and identification of targets for selective insect control.

Published
2008

37. Expression of Pax group III genes suggests a single-segmental periodicity for opisthosomal segment patterning in the spiderCupiennius salei.

Author

Schoppmeier, Michael and Damen, Wim G. M.

Subjects
*INSECTS, *GENES, *ARTHROPODA, *ENTOMOLOGY, *HEREDITY, *MOLECULAR genetics
Abstract

Pair-rule patterning forms a key step for segmentation in insects. The expression patterns of pair-rule gene orthologs in representatives of other arthropod groups imply that these genes were segmentation genes in the last common ancestor of the various arthropod groups, but almost nothing is known about the underlying mechanism in noninsect arthropods. Here, we cloned and analyzed members of the Pax group III genes from the spiderCupiennius salei. Pax group III genes comprise genes like theDrosophilagenespaired,gooseberry, andgooseberry-neuro, as well as the vertebratePax 3andPax 7genes. We recovered three Pax group III genes from the spiderC. salei,Cs-pairberry-1,Cs-pairberry-2, andCs-pairberry-3, and show that the combined expression of the three spider genes mimics the patterns in insects, suggesting an ancestral role for Pax group III genes in segmentation, neurogenesis, and appendage formation in arthropods. One of the genes,pairberry-3, is expressed in a segmental periodicity before overt morphological segmentation is visible, suggesting a single segmental periodicity for opisthosomal segment pattering in the spider. Comparisons among arthropods suggest that the underlying mechanisms for pair-rule gene orthologs are more diverged than the ones for the segment-polarity genes. We argue that there may be a correlation between the lower variation in patterns of segment-polarity genes and the phylotypic stage. The segment-polarity genes are required to define the segment borders of the embryo at the germ-band stage, the arthropod phylotypic stage. Pair-rule gene orthologs act more upstream and may display more variation in their action. [ABSTRACT FROM AUTHOR]

Published
2005
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38. Gene Silencing via Embryonic RNAi in Spider Embryos.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American wandering spider, is a particularly useful laboratory model for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This in itself will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. The discovery of RNA interference (RNAi), in which double-stranded RNA (dsRNA) suppresses the translation of homologous mRNA, has had a huge impact on evolutionary developmental biology by enabling the analysis of loss-of-function phenotypes in organisms in which classical genetic analysis is laborious or not possible. This protocol describes the application of RNAi to embryos of the spider C. salei.

Published
2008
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39. Detection of Cell Proliferation in Spider Embryos Using BrdU Labeling.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American wandering spider, is particularly useful for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. This protocol describes the detection of proliferating cells in whole-mount Cupiennius embryos. When labeled nucleotides are introduced into mitotically dividing cells, these cells incorporate the labels into the newly synthesized DNA. Thus, only cells that have synthesized DNA after the addition of the label will be detected. This protocol uses 5-bromo-2'-deoxy-uridine (BrdU) as a label that is subsequently detected by immunocytochemistry. BrdU labeling is a relatively easy way to detect cells that have recently synthesized DNA. The main advantage of this technique is that the label accumulates over time and, by varying the incubation time before fixation, an increasingly cumulative picture of cell proliferation activity can be obtained.

Published
2008
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40. Collection and fixation of spider embryos.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American wandering spider, is a particularly useful laboratory model for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This in itself will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. This protocol describes the collection and fixation of embryos from C. salei. The fixed embryos can be stored at -20°C for prolonged periods and used for in situ hybridization, in studies of apoptosis using terminal deoxynucleotidyl-transferase-mediated dUTP-digoxigenin nick-end labeling (TUNEL), and for immunohistochemistry.

Published
2008
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41. Dissecting spider embryos for light microscopy.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American wandering spider, is a particularly useful laboratory model for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This in itself will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. Spider embryos can be studied as whole mounts under the dissection microscope. Alternatively, the embryos can be dissected and observed under the compound microscope. Preparing and dissecting spider embryos for compound microscopy is difficult due to the high amount of yolk, which makes the embryos very fragile. The following protocol describes how to make the necessary tools, then use them to obtain good preparations. Not all embryonic stages can be dissected and prepared; very young stages can only be examined as whole mounts.

Published
2008
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42. The American Wandering Spider Cupiennius salei.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei is a useful laboratory model for embryological and physiological studies. Its highly developed sensory organs also make it an excellent model for behavioral studies. Furthermore, Cupiennius has contributed greatly to the study of evolutionary developmental questions. This chelicerate arthropod is particularly useful for such studies because of its phylogenetic position and the availability of tools to study and manipulate its embryonic development.

Published
2008
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43. Whole-mount in situ hybridization of spider embryos.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American wandering spider, is a particularly useful laboratory model for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This in itself will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. This protocol describes the detection of transcripts in fixed C. salei embryos using whole-mount in situ hybridization.

Published
2008
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44. Detection of Cell Death in Spider Embryos Using TUNEL.

Author

Prpic NM, Schoppmeier M, and Damen WG

Abstract

INTRODUCTIONThe spider Cupiennius salei, commonly known as the American Wandering Spider, is a particularly useful laboratory model for embryological studies because of the availability of tools to study and manipulate its embryonic development. Cupiennius is used to study axis formation, segmentation, appendage development, neurogenesis, and silk production. These studies contribute to our understanding of the evolution of these processes, but they also help us to understand the origin and diversification of evolutionary novelties. Comparisons between spiders and insects can show the degree of conservation and divergence of developmental mechanisms during arthropod evolution. Any embryological feature conserved between spiders and insects is likely to represent an ancestral feature for arthropods. Comparative molecular embryological work in insects and spiders should eventually allow us to define a molecular archetype for the phylum Arthropoda. This in itself will be a necessary cornerstone for comparing the different metazoan phyla, including chordates. A feature of apoptosis (i.e., cell death) is the cleavage or fragmentation of DNA that occurs in dead or dying cells. This protocol describes the detection of fragmented DNA in whole-mount Cupiennius embryos. The 3'-OH ends of these DNA fragments can be labeled with the terminal deoxynucleotidyl-transferase-mediated dUTP-digoxigenin nick-end labeling (TUNEL) technique. This protocol uses a terminal deoxynucleotidyl transferase to add labeled dUTP to the fragmented DNA, and this label is then detected by immunocytochemistry. The TUNEL technique is a relatively easy way to obtain a reliable picture of the cell death pattern during normal and abnormal development.

Published
2008
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45. The genome of the model beetle and pest Tribolium castaneum.

Author

Richards S, Gibbs RA, Weinstock GM, Brown SJ, Denell R, Beeman RW, Gibbs R, Beeman RW, Brown SJ, Bucher G, Friedrich M, Grimmelikhuijzen CJ, Klingler M, Lorenzen M, Richards S, Roth S, Schröder R, Tautz D, Zdobnov EM, Muzny D, Gibbs RA, Weinstock GM, Attaway T, Bell S, Buhay CJ, Chandrabose MN, Chavez D, Clerk-Blankenburg KP, Cree A, Dao M, Davis C, Chacko J, Dinh H, Dugan-Rocha S, Fowler G, Garner TT, Garnes J, Gnirke A, Hawes A, Hernandez J, Hines S, Holder M, Hume J, Jhangiani SN, Joshi V, Khan ZM, Jackson L, Kovar C, Kowis A, Lee S, Lewis LR, Margolis J, Morgan M, Nazareth LV, Nguyen N, Okwuonu G, Parker D, Richards S, Ruiz SJ, Santibanez J, Savard J, Scherer SE, Schneider B, Sodergren E, Tautz D, Vattahil S, Villasana D, White CS, Wright R, Park Y, Beeman RW, Lord J, Oppert B, Lorenzen M, Brown S, Wang L, Savard J, Tautz D, Richards S, Weinstock G, Gibbs RA, Liu Y, Worley K, Weinstock G, Elsik CG, Reese JT, Elhaik E, Landan G, Graur D, Arensburger P, Atkinson P, Beeman RW, Beidler J, Brown SJ, Demuth JP, Drury DW, Du YZ, Fujiwara H, Lorenzen M, Maselli V, Osanai M, Park Y, Robertson HM, Tu Z, Wang JJ, Wang S, Richards S, Song H, Zhang L, Sodergren E, Werner D, Stanke M, Morgenstern B, Solovyev V, Kosarev P, Brown G, Chen HC, Ermolaeva O, Hlavina W, Kapustin Y, Kiryutin B, Kitts P, Maglott D, Pruitt K, Sapojnikov V, Souvorov A, Mackey AJ, Waterhouse RM, Wyder S, Zdobnov EM, Zdobnov EM, Wyder S, Kriventseva EV, Kadowaki T, Bork P, Aranda M, Bao R, Beermann A, Berns N, Bolognesi R, Bonneton F, Bopp D, Brown SJ, Bucher G, Butts T, Chaumot A, Denell RE, Ferrier DE, Friedrich M, Gordon CM, Jindra M, Klingler M, Lan Q, Lattorff HM, Laudet V, von Levetsow C, Liu Z, Lutz R, Lynch JA, da Fonseca RN, Posnien N, Reuter R, Roth S, Savard J, Schinko JB, Schmitt C, Schoppmeier M, Schröder R, Shippy TD, Simonnet F, Marques-Souza H, Tautz D, Tomoyasu Y, Trauner J, Van der Zee M, Vervoort M, Wittkopp N, Wimmer EA, Yang X, Jones AK, Sattelle DB, Ebert PR, Nelson D, Scott JG, Beeman RW, Muthukrishnan S, Kramer KJ, Arakane Y, Beeman RW, Zhu Q, Hogenkamp D, Dixit R, Oppert B, Jiang H, Zou Z, Marshall J, Elpidina E, Vinokurov K, Oppert C, Zou Z, Evans J, Lu Z, Zhao P, Sumathipala N, Altincicek B, Vilcinskas A, Williams M, Hultmark D, Hetru C, Jiang H, Grimmelikhuijzen CJ, Hauser F, Cazzamali G, Williamson M, Park Y, Li B, Tanaka Y, Predel R, Neupert S, Schachtner J, Verleyen P, Raible F, Bork P, Friedrich M, Walden KK, Robertson HM, Angeli S, Forêt S, Bucher G, Schuetz S, Maleszka R, Wimmer EA, Beeman RW, Lorenzen M, Tomoyasu Y, Miller SC, Grossmann D, and Bucher G

Subjects
Animals, Base Composition, Body Patterning genetics, Cytochrome P-450 Enzyme System genetics, DNA Transposable Elements genetics, Growth and Development genetics, Humans, Insecticides pharmacology, Neurotransmitter Agents genetics, Oogenesis genetics, Phylogeny, Proteome genetics, RNA Interference, Receptors, G-Protein-Coupled genetics, Receptors, Odorant genetics, Repetitive Sequences, Nucleic Acid genetics, Taste genetics, Telomere genetics, Tribolium classification, Tribolium embryology, Tribolium physiology, Vision, Ocular genetics, Genes, Insect genetics, Genome, Insect genetics, Tribolium genetics
Abstract

Tribolium castaneum is a member of the most species-rich eukaryotic order, a powerful model organism for the study of generalized insect development, and an important pest of stored agricultural products. We describe its genome sequence here. This omnivorous beetle has evolved the ability to interact with a diverse chemical environment, as shown by large expansions in odorant and gustatory receptors, as well as P450 and other detoxification enzymes. Development in Tribolium is more representative of other insects than is Drosophila, a fact reflected in gene content and function. For example, Tribolium has retained more ancestral genes involved in cell-cell communication than Drosophila, some being expressed in the growth zone crucial for axial elongation in short-germ development. Systemic RNA interference in T. castaneum functions differently from that in Caenorhabditis elegans, but nevertheless offers similar power for the elucidation of gene function and identification of targets for selective insect control.

Published
2008
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