Your search keyword '"Hiroki Gotoh"' showing total 130 results

1. The draft genome sequence of the Japanese rhinoceros beetle Trypoxylus dichotomus septentrionalis towards an understanding of horn formation

Author

Shinichi Morita, Tomoko F. Shibata, Tomoaki Nishiyama, Yuuki Kobayashi, Katsushi Yamaguchi, Kouhei Toga, Takahiro Ohde, Hiroki Gotoh, Takaaki Kojima, Jesse N. Weber, Marco Salvemini, Takahiro Bino, Mutsuki Mase, Moe Nakata, Tomoko Mori, Shogo Mori, Richard Cornette, Kazuki Sakura, Laura C. Lavine, Douglas J. Emlen, Teruyuki Niimi, and Shuji Shigenobu

Subjects

Medicine, Science

Abstract

Abstract The Japanese rhinoceros beetle Trypoxylus dichotomus is a giant beetle with distinctive exaggerated horns present on the head and prothoracic regions of the male. T. dichotomus has been used as a research model in various fields such as evolutionary developmental biology, ecology, ethology, biomimetics, and drug discovery. In this study, de novo assembly of 615 Mb, representing 80% of the genome estimated by flow cytometry, was obtained using the 10 × Chromium platform. The scaffold N50 length of the genome assembly was 8.02 Mb, with repetitive elements predicted to comprise 49.5% of the assembly. In total, 23,987 protein-coding genes were predicted in the genome. In addition, de novo assembly of the mitochondrial genome yielded a contig of 20,217 bp. We also analyzed the transcriptome by generating 16 RNA-seq libraries from a variety of tissues of both sexes and developmental stages, which allowed us to identify 13 co-expressed gene modules. We focused on the genes related to horn formation and obtained new insights into the evolution of the gene repertoire and sexual dimorphism as exemplified by the sex-specific splicing pattern of the doublesex gene. This genomic information will be an excellent resource for further functional and evolutionary analyses, including the evolutionary origin and genetic regulation of beetle horns and the molecular mechanisms underlying sexual dimorphism.

Published

2023

2. Adhesion and shrinkage transform the rounded pupal horn into an angular adult horn in Japanese rhinoceros beetle.

Author

Keisuke Matsuda, Haruhiko Adachi, Hiroki Gotoh, Yasuhiro Inoue, and Shigeru Kondo

Abstract

Clarifying the mechanisms underlying shape alterations during insect metamorphosis is important for understanding exoskeletal morphogenesis. The large horn of the Japanese rhinoceros beetle Trypoxylus dichotomus is the result of drastic metamorphosis, wherein it appears as a rounded shape during pupation and then undergoes remodeling into an angular adult shape. However, the mechanical mechanismsunderlying this remodeling process remain unknown. In this study, we investigated the remodeling mechanisms of the Japanese rhinoceros beetle horn by developing a physical simulation. We identified three factors contributing to remodeling by biological experiments - ventral adhesion, uneven shrinkage, and volume reduction - which were demonstrated to be crucial for transformation using a physical simulation. Furthermore, we corroborated our findings by applying the simulation to the mandibular remodeling of stag beetles. These results indicated that physical simulation applies to pupal remodeling in other beetles, and the morphogenic mechanism could explain various exoskeletal shapes. [ABSTRACT FROM AUTHOR]

Published

2024

3. Evolutionary transition of doublesex regulation from sex-specific splicing to male-specific transcription in termites

Author

Satoshi Miyazaki, Kokuto Fujiwara, Keima Kai, Yudai Masuoka, Hiroki Gotoh, Teruyuki Niimi, Yoshinobu Hayashi, Shuji Shigenobu, and Kiyoto Maekawa

Subjects

Medicine, Science

Abstract

Abstract The sex determination gene doublesex (dsx) encodes a transcription factor with two domains, oligomerization domain 1 (OD1) and OD2, and is present throughout insects. Sex-specific Dsx splicing isoforms regulate the transcription of target genes and trigger sex differentiation in all Holometabola examined to date. However, in some hemimetabolous insects, dsx is not spliced sexually and its sequence is less conserved. Here, to elucidate evolutionary changes in dsx in domain organisation and regulation in termites, we searched genome and/or transcriptome databases for the dsx OD1 and OD2 in seven termite species and their sister group (Cryptocercus woodroaches). Molecular phylogenetic and synteny analyses identified OD1 sequences of termites and C. punctulatus that clustered with dsx of Holometabola and regarded them as dsx orthologues. The Cryptocercus dsx orthologue containing OD2 was spliced sexually, as previously shown in other insects. However, OD2 was not found in all termite dsx orthologues. These orthologues were encoded by a single exon in three termites for which genome information is available; they were not alternatively spliced but transcribed in a male-specific manner in two examined species. Evolution of dsx regulation from sex-specific splicing to male-specific transcription may have occurred at an early stage of social evolution in termites.

Published

2021

4. Publisher Correction: Evolutionary transition of doublesex regulation from sex-specific splicing to male-specific transcription in termites

Author

Satoshi Miyazaki, Kokuto Fujiwara, Keima Kai, Yudai Masuoka, Hiroki Gotoh, Teruyuki Niimi, Yoshinobu Hayashi, Shuji Shigenobu, and Kiyoto Maekawa

Subjects

Medicine, Science

Published

2021

5. Computational analyses decipher the primordial folding coding the 3D structure of the beetle horn

Author

Keisuke Matsuda, Hiroki Gotoh, Haruhiko Adachi, Yasuhiro Inoue, and Shigeru Kondo

Subjects

Medicine, Science

Abstract

Abstract The beetle horn primordium is a complex and compactly folded epithelial sheet located beneath the larval cuticle. Only by unfolding the primordium can the complete 3D shape of the horn appear, suggesting that the morphology of beetle horns is encoded in the primordial folding pattern. To decipher the folding pattern, we developed a method to manipulate the primordial local folding on a computer and clarified the contribution of the folding of each primordium region to transformation. We found that the three major morphological changes (branching of distal tips, proximodistal elongation, and angular change) were caused by the folding of different regions, and that the folding mechanism also differs according to the region. The computational methods we used are applicable to the morphological study of other exoskeletal animals.

Published

2021

6. Structure and development of the complex helmet of treehoppers (Insecta: Hemiptera: Membracidae)

Author

Haruhiko Adachi, Keisuke Matsuda, Kenji Nishida, Paul Hanson, Shigeru Kondo, and Hiroki Gotoh

Subjects

Morphogenesis, 3D structure, Treehopper, Membracidae, Pronotum, Micro-CT, Zoology, QL1-991

Abstract

Abstract Some insects possess complex three-dimensional (3D) structures that develop under the old cuticle prior to the last imaginal molt. Adult treehoppers (Insecta: Hemiptera: Auchenorrhyncha: Membracidae) have one such complex 3D structure, known as a helmet, on their dorsal side. The adult helmet likely forms inside the nymphal pronotum during the final instar nymphal stage. Previous morphological studies have reported that the adult helmet is a large, bi-layered, plywood-like structure, whereas the nymphal pronotum is a monolayer, sheath-like structure. The adult helmet is much larger than nymphal helmet. Thus, the emergence of the adult helmet involves two structural transitions: a transition from a monolayer, sheath-like pronotum to a bi-layer, plywood-like helmet, and a transition in size from small to large. However, when, how, and in what order these transitions occur within the nymphal cuticle is largely unknown. To determine how adult helmet development occurs under the nymphal cuticle, in the present study we describe the morphology of the final adult helmet and investigate developmental trajectories of the helmet during the final instar nymphal stage. We used micro-CT, scanning electron microscope and paraffin sections for morphological observations, and used Antianthe expansa as a model species. We found that the structural transition (from monolayer, sheath-like structure to bi-layer, roof-like structure) occurs through the formation of a “miniature” of the adult helmet during the middle stage of development and that subsequently, extensive folding and furrows form, which account for the increase in size. We suggest that the making of a “miniature” is the key developmental step for the formation of various 3D structures of treehopper helmets.

Published

2020

7. A novel imaging method for correlating 2D light microscopic data and 3D volume data based on block-face imaging

Author

Yuki Tajika, Tohru Murakami, Keiya Iijima, Hiroki Gotoh, Maiko Takahashi-Ikezawa, Hitoshi Ueno, Yuhei Yoshimoto, and Hiroshi Yorifuji

Subjects

Medicine, Science

Abstract

Abstract We have developed an imaging method designated as correlative light microscopy and block-face imaging (CoMBI), which contributes to improve the reliability of morphological analyses. This method can collect both the frozen sections and serial block-face images in a single specimen. The frozen section can be used for conventional light microscopic analysis to obtain 2-dimensional (2D) anatomical and molecular information, while serial block-face images can be used as 3-dimensional (3D) volume data for anatomical analysis. Thus, the sections maintain positional information in the specimen, and allows the correlation of 2D microscopic data and 3D volume data in a single specimen. The subjects can vary in size and type, and can cover most specimens encountered in biology. In addition, the required system for our method is characterized by cost-effectiveness. Here, we demonstrated the utility of CoMBI using specimens ranging in size from several millimeters to several centimeters, i.e., mouse embryos, human brainstem samples, and stag beetle larvae, and present successful correlation between the 2D light microscopic images and 3D volume data in a single specimen.

Published

2017

8. Evolution of horn length and lifting strength in the Japanese rhinoceros beetleTrypoxylus dichotomus

Author

Jesse N. Weber, Wataru Kojima, Romain Boisseau, Teruyuki Niimi, Shinichi Morita, Shuji Shigenobu, Hiroki Gotoh, Kunio Araya, Chung-Ping Lin, Camille Thomas-Bulle, Cerisse E. Allen, Wenfei Tong, Laura Corley Lavine, Brook O. Swanson, and Douglas J. Emlen

Abstract

Rhinoceros beetle (Trypoxylus dichotomus) males have pitchfork-shaped head horns, which they use to pry rival males from the trunks of trees. In the largest males these horns can be three times the length of horns in the two closest sister species. Because this weapon functions as a lever, longer horns should lift with less force than shorter horns (the ‘paradox of the weakening combatant’) unless other elements of the weapon system (e.g., input lever length, muscle mass) evolve to compensate. We used next-generation sequencing approaches to consolidate 23 sample locations into 8 genetically distinguishable populations, reconstructing their historical relationships and providing a comprehensive picture of the evolution of this horn lever system. We show that head horns likely increased in length independently in the Northern and Southern lineages. In both instances this resulted in weaker lifting forces, but this mechanical disadvantage was later ameliorated, to some extent and in some locations, by subsequent reductions to horn length, changes in muscle size, or by an increase in input lever length (head height). Our results reveal an exciting geographic mosaic of differences in weapon size, weapon force, and in the extent and nature of mechanical compensation. Reconstructing the evolution of this weapon system offers critical insights towards meaningfully linking mating system dynamics, selection patterns, and diversity in sexually selected traits.

Published

2023

9. Mechanical models affecting beetle horn remodeling

Author

Keisuke Matsuda, Haruhiko Adachi, Hiroki Gotoh, Yasuhiro Inoue, and Shigeru Kondo

Abstract

Clarifying the mechanisms of shape alteration by insect metamorphosis is important for comprehending exoskeletal morphogenesis. The large horn of the Japanese rhinoceros beetleTrypoxylus dichotomusis the result of drastic metamorphosis, wherein it appears as a rounded shape via pupation and then undergoes remodeling into an angular adult shape. However, the mechanical mechanisms of this remodeling process remain unknown. In this study, we investigated the remodeling mechanisms of the Japanese rhinoceros beetle horn by developing a physical simulation. We identified three factors contributing to remodeling by biological experiments—ventral adhesion, uneven shrinkage, and volume reduction—which were demonstrated to be crucial to the transformation by a physical simulation. We also corroborated our findings by applying the simulation to the stag beetle’s mandibular remodeling. These results indicate that the physical simulation is applicable to pupal remodeling in other beetles, and the morphogenic mechanisms could explain various exoskeletal shapes.Significance statementThe metamorphosis in insects is a mysterious process. By metamorphosis, insects sometimes change their shape dramatically. The head horn of the Japanese rhinoceros beetle is one of the most famous examples of metamorphosis. In larva-to-pupa molting, the horn appears suddenly, caused by the “furrow formation and unfolding” mechanism. The unfolding process makes the pupal horn rounded. However, pupa-to-adult molting transforms the rounded shape into an angular shape. In this paper, we investigated the mechanisms of the transformation. We extracted factors contributing to it through observations and experiments and developed a physical simulation. It could reproduce the adult shape from the pupal shape and could be a general model for the pupa-adult transformation of beetles.

Published

2023

10. Evolution of Horn Length and Lifting Strength in the Japanese Rhinoceros Beetle Trypoxylus dichotomus

Author

Jesse N. Weber, Wataru Kojima, Romain Boisseau, Teruyuki Niimi, Shinichi Morita, Shuji Shigenobu, Hiroki Gotoh, Kunio Araya, Chung-Ping Lin, Camille Thomas-Bulle, Cerisse E. Allen, Wenfei Tong, Laura Corley Lavine, Brook O. Swanson, and Douglas Emlen

Published

2023

11. Rhinoceros beetle horn development reveals deep parallels with dung beetles.

Author

Takahiro Ohde, Shinichi Morita, Shuji Shigenobu, Junko Morita, Takeshi Mizutani, Hiroki Gotoh, Robert A Zinna, Moe Nakata, Yuta Ito, Kenshi Wada, Yasuhiro Kitano, Karen Yuzaki, Kouhei Toga, Mutsuki Mase, Koji Kadota, Jema Rushe, Laura Corley Lavine, Douglas J Emlen, and Teruyuki Niimi

Subjects

Genetics, QH426-470

Abstract

Beetle horns are attractive models for studying the evolution of novel traits, as they display diverse shapes, sizes, and numbers among closely related species within the family Scarabaeidae. Horns radiated prolifically and independently in two distant subfamilies of scarabs, the dung beetles (Scarabaeinae), and the rhinoceros beetles (Dynastinae). However, current knowledge of the mechanisms underlying horn diversification remains limited to a single genus of dung beetles, Onthophagus. Here we unveil 11 horn formation genes in a rhinoceros beetle, Trypoxylus dichotomus. These 11 genes are mostly categorized as larval head- and appendage-patterning genes that also are involved in Onthophagus horn formation, suggesting the same suite of genes was recruited in each lineage during horn evolution. Although our RNAi analyses reveal interesting differences in the functions of a few of these genes, the overwhelming conclusion is that both head and thoracic horns develop similarly in Trypoxylus and Onthophagus, originating in the same developmental regions and deploying similar portions of appendage patterning networks during their growth. Our findings highlight deep parallels in the development of rhinoceros and dung beetle horns, suggesting either that both horn types arose in the common ancestor of all scarabs, a surprising reconstruction of horn evolution that would mean the majority of scarab species (~35,000) actively repress horn growth, or that parallel origins of these extravagant structures resulted from repeated co-option of the same underlying developmental processes.

Published

2018

12. Evaluation of Body Size Indicators for Morphological Analyses in Two Sister Species of Genus Dorcus (Coleoptera, Lucanidae)

Author

Itsuki Ohtsu, Yasuhiko Chikami, Taichi Umino, and Hiroki Gotoh

Subjects

Coleoptera, Insect Science, Animals, stag beetle, static allometry, General Medicine, body size, weaponed beetle, morphometry

Abstract

The relationship between trait and body size, i.e., the scaling relationship or static allometry, is an essential concept for investigating trait size. However, usage of an inappropriate body size indicator can lead to misinterpretation of morphology. In this study, we examined several possible body size indicators in two closely related stag beetle species, Dorcus rectus and Dorcus amamianus. We raised animals in captivity and used pupal weight as a measure of true, or overall body size, and then evaluated six adult morphological traits to test whether these traits could be reliably used as body size indicators in static scaling relationship comparisons. We analyzed two comparisons, between sexes in same species and between species in same sex. We showed that the most appropriate body size indicators differ depending on the comparisons. Our results indicated that the scaling relationship of focal traits could be over- or under-estimated depending on which body size indicators are used.

Published

2022

13. Epithelial folding determines the final shape of beetle horns

Author

Laura Corley Lavine, Haruhiko Adachi, Keisuke Matsuda, and Hiroki Gotoh

Subjects

0303 health sciences, Mechanism (biology), Horn (anatomy), Gene Expression Regulation, Developmental, Epithelial folding, Ornaments, Biology, Biological Evolution, Epithelium, Coleoptera, 03 medical and health sciences, 0302 clinical medicine, Species Specificity, Evolutionary biology, Sexual selection, Genetics, Animals, 030217 neurology & neurosurgery, Body Patterning, Horns, 030304 developmental biology, Developmental Biology

Abstract

The elaborate ornaments and weapons of sexual selection, such as the vast array of horns observed in scarab beetles, are some of the most striking outcomes of evolution. How these novel traits have arisen, develop, and respond to condition is governed by a complex suite of interactions that require coordination between the environment, whole-animal signals, cell-cell signals, and within-cell signals. Endocrine factors, developmental patterning genes, and sex-specific gene expression have been shown to regulate beetle horn size, shape, and location, yet no overarching mechanism of horn shape has been described. Recent advances in microscopy and computational analyses combined with a functional genetic approach have revealed that patterning genes combined with intricate epithelial folding and movement are responsible for the final shape of a beetle head horn.

Published

2021

14. Publisher Correction: Evolutionary transition of doublesex regulation from sex-specific splicing to male-specific transcription in termites

Author

Kokuto Fujiwara, Satoshi Miyazaki, Teruyuki Niimi, Shuji Shigenobu, Kiyoto Maekawa, Hiroki Gotoh, Yudai Masuoka, Keima Kai, and Yoshinobu Hayashi

Subjects

Male, RNA Splicing, Science, Doublesex, Isoptera, Biology, Sex Factors, Animals, Protein Isoforms, RNA-Seq, Genetics, Multidisciplinary, Binding Sites, Evolutionary transitions, Sex specific, Publisher Correction, Biological Evolution, Gene Expression Regulation, RNA splicing, Insect Proteins, Medicine, Female, Transcription (software), Transcription Factors

Abstract

The sex determination gene doublesex (dsx) encodes a transcription factor with two domains, oligomerization domain 1 (OD1) and OD2, and is present throughout insects. Sex-specific Dsx splicing isoforms regulate the transcription of target genes and trigger sex differentiation in all Holometabola examined to date. However, in some hemimetabolous insects, dsx is not spliced sexually and its sequence is less conserved. Here, to elucidate evolutionary changes in dsx in domain organisation and regulation in termites, we searched genome and/or transcriptome databases for the dsx OD1 and OD2 in seven termite species and their sister group (Cryptocercus woodroaches). Molecular phylogenetic and synteny analyses identified OD1 sequences of termites and C. punctulatus that clustered with dsx of Holometabola and regarded them as dsx orthologues. The Cryptocercus dsx orthologue containing OD2 was spliced sexually, as previously shown in other insects. However, OD2 was not found in all termite dsx orthologues. These orthologues were encoded by a single exon in three termites for which genome information is available; they were not alternatively spliced but transcribed in a male-specific manner in two examined species. Evolution of dsx regulation from sex-specific splicing to male-specific transcription may have occurred at an early stage of social evolution in termites.

Published

2021

15. Structure and development of the complex helmet of treehoppers (Insecta: Hemiptera: Membracidae)

Author

Kenji Nishida, Shigeru Kondo, Paul C. Hanson, Keisuke Matsuda, Haruhiko Adachi, and Hiroki Gotoh

Subjects

0106 biological sciences, 0301 basic medicine, Micro-CT, Middle stage, Pronotum, Zoology, 3D structure, 010603 evolutionary biology, 01 natural sciences, Auchenorrhyncha, 03 medical and health sciences, Paraffin section, lcsh:Zoology, Morphogenesis, Structural transition, lcsh:QL1-991, Treehopper, Cuticle (hair), biology, biology.organism_classification, Hemiptera, 030104 developmental biology, Instar, Animal Science and Zoology, Membracidae, Research Article

Abstract

Some insects possess complex three-dimensional (3D) structures that develop under the old cuticle prior to the last imaginal molt. Adult treehoppers (Insecta: Hemiptera: Auchenorrhyncha: Membracidae) have one such complex 3D structure, known as a helmet, on their dorsal side. The adult helmet likely forms inside the nymphal pronotum during the final instar nymphal stage.Previous morphological studies have reported that the adult helmet is a large, bi-layered, plywood-like structure, whereas the nymphal pronotum is a monolayer, sheath-like structure. The adult helmet is much larger than nymphal helmet. Thus, the emergence of the adult helmet involves two structural transitions: a transition from a monolayer, sheath-like pronotum to a bi-layer, plywood-like helmet, and a transition in size from small to large. However, when, how, and in what order these transitions occur within the nymphal cuticle is largely unknown.To determine how adult helmet development occurs under the nymphal cuticle, in the present study we describe the morphology of the final adult helmet and investigate developmental trajectories of the helmet during the final instar nymphal stage. We used micro-CT, scanning electron microscope and paraffin sections for morphological observations, and used Antianthe expansa as a model species.We found that the structural transition (from monolayer, sheath-like structure to bi-layer, roof-like structure) occurs through the formation of a “miniature” of the adult helmet during the middle stage of development and that subsequently, extensive folding and furrows form, which account for the increase in size. We suggest that the making of a “miniature” is the key developmental step for the formation of various 3D structures of treehopper helmets.

Published

2020

16. Genomic and transcriptomic analyses of the subterranean termite Reticulitermes speratus : Gene duplication facilitates social evolution

Author

Shuji Shigenobu, Yoshinobu Hayashi, Dai Watanabe, Gaku Tokuda, Masaru Y. Hojo, Kouhei Toga, Ryota Saiki, Hajime Yaguchi, Yudai Masuoka, Ryutaro Suzuki, Shogo Suzuki, Moe Kimura, Masatoshi Matsunami, Yasuhiro Sugime, Kohei Oguchi, Teruyuki Niimi, Hiroki Gotoh, Masaru K. Hojo, Satoshi Miyazaki, Atsushi Toyoda, Toru Miura, and Kiyoto Maekawa

Subjects

Multidisciplinary

Abstract

Significance Gene duplication is a major source of evolutionary innovation and is associated with the increases in biological complexity and adaptive radiation. Termites are model social organisms characterized by a sophisticated caste system. We analyzed the genome of the Japanese subterranean termite, an ecologically and economically important insect acting as a destructive pest. The analyses revealed the significance of gene duplication in social evolution. Gene duplication associated with caste-biased gene expression was prevalent in the termite genome. Many of the duplicated genes were related to social functions, such as chemical communication, social immunity, and defense, and they were often expressed in caste-specific organs. We propose that gene duplication facilitates social evolution through regulatory diversification leading to caste-biased expression and functional specialization.

Published

2022

17. The draft genome sequence of Japanese rhinoceros beetle Trypoxylus dichotomus

Author

Shinichi Morita, Tomoko F. Shibata, Tomoaki Nishiyama, Yuuki Kobayashi, Katsushi Yamaguchi, Kouhei Toga, Takahiro Ohde, Hiroki Gotoh, Takaaki Kojima, Jesse Weber, Marco Salvemini, Takahiro Bino, Mutsuki Mase, Moe Nakata, Tomoko Mori, Shogo Mori, Richard Cornette, Kazuki Sakura, Laura C. Lavine, Douglas J. Emlen, Teruyuki Niimi, and Shuji Shigenobu

Abstract

Beetles are the largest insect order and one of the most successful animal groups in terms of number of species. The Japanese rhinoceros beetle Trypoxylus dichotomus (Coleoptera, Scarabaeidae, Dynastini) is a giant beetle with distinctive exaggerated horns present on the head and prothoracic regions of the male. T. dichotomus has been used as research model in various fields such as evolutionary developmental biology, ecology, ethology, biomimetics, and drug discovery. In this study, de novo assembly of 615 Mb, representing 80% of the genome estimated by flow cytometry, was obtained using the 10x Chromium platform. The scaffold N50 length of the genome assembly was 8.02 Mb, with repetitive elements predicted to comprise 49.5% of the assembly. In total, 23,987 protein-coding genes were predicted in the genome. In addition, de novo assembly of the mitochondrial genome yielded a contig of 20,217 bp. We also analyzed the transcriptome by generating 16 RNA-seq libraries from a variety of tissues of both sexes and developmental stages, which allowed us to identify 13 co-expressed gene modules. The detailed genomic and transcriptomic information of T. dichotomus is the most comprehensive among those reported for any species of Dynastinae. This genomic information will be an excellent resource for further functional and evolutionary analyses, including the evolutionary origin and genetic regulation of beetle horns and the molecular mechanisms underlying sexual dimorphism.

Published

2022

18. Genomic and transcriptomic analyses of the subterranean termite

Author

Shuji, Shigenobu, Yoshinobu, Hayashi, Dai, Watanabe, Gaku, Tokuda, Masaru Y, Hojo, Kouhei, Toga, Ryota, Saiki, Hajime, Yaguchi, Yudai, Masuoka, Ryutaro, Suzuki, Shogo, Suzuki, Moe, Kimura, Masatoshi, Matsunami, Yasuhiro, Sugime, Kohei, Oguchi, Teruyuki, Niimi, Hiroki, Gotoh, Masaru K, Hojo, Satoshi, Miyazaki, Atsushi, Toyoda, Toru, Miura, and Kiyoto, Maekawa

Subjects

Evolution, social insect, Gene Expression Profiling, gene duplication, Gene Expression, Genomics, Isoptera, Biological Sciences, Biological Evolution, Social Evolution, caste system, Animals, Cellulases, Insect Proteins, Female, Transcriptome, termite

Abstract

Significance Gene duplication is a major source of evolutionary innovation and is associated with the increases in biological complexity and adaptive radiation. Termites are model social organisms characterized by a sophisticated caste system. We analyzed the genome of the Japanese subterranean termite, an ecologically and economically important insect acting as a destructive pest. The analyses revealed the significance of gene duplication in social evolution. Gene duplication associated with caste-biased gene expression was prevalent in the termite genome. Many of the duplicated genes were related to social functions, such as chemical communication, social immunity, and defense, and they were often expressed in caste-specific organs. We propose that gene duplication facilitates social evolution through regulatory diversification leading to caste-biased expression and functional specialization., Termites are model social organisms characterized by a polyphenic caste system. Subterranean termites (Rhinotermitidae) are ecologically and economically important species, including acting as destructive pests. Rhinotermitidae occupies an important evolutionary position within the clade representing a transitional taxon between the higher (Termitidae) and lower (other families) termites. Here, we report the genome, transcriptome, and methylome of the Japanese subterranean termite Reticulitermes speratus. Our analyses highlight the significance of gene duplication in social evolution in this termite. Gene duplication associated with caste-biased gene expression was prevalent in the R. speratus genome. The duplicated genes comprised diverse categories related to social functions, including lipocalins (chemical communication), cellulases (wood digestion and social interaction), lysozymes (social immunity), geranylgeranyl diphosphate synthase (social defense), and a novel class of termite lineage–specific genes with unknown functions. Paralogous genes were often observed in tandem in the genome, but their expression patterns were highly variable, exhibiting caste biases. Some of the assayed duplicated genes were expressed in caste-specific organs, such as the accessory glands of the queen ovary and the frontal glands of soldier heads. We propose that gene duplication facilitates social evolution through regulatory diversification, leading to caste-biased expression and subfunctionalization and/or neofunctionalization conferring caste-specialized functions.

Published

2021

19. Recent advances in understanding horn formation in the Japanese rhinoceros beetle Trypoxylus dichotomus using next-generation sequencing technology

Author

Shinichi Morita, Kazuki Sakura, Hiroki Gotoh, Douglas J Emlen, and Teruyuki Niimi

Subjects

Coleoptera, Sex Characteristics, Technology, Japan, Insect Science, Animals, High-Throughput Nucleotide Sequencing, Ecology, Evolution, Behavior and Systematics, Perissodactyla

Abstract

The exaggerated horns of beetles are attractive models for studying the origin of novel traits and morphological evolution. Closely related species often differ profoundly in the size, number, and shape of their horns, and in the body region from which they extend. In addition, beetle horns exhibit exquisite nutrition-dependent phenotypic plasticity, leading to disproportionate growth of the horns in the largest, best-condition individuals and much smaller - even stunted - horn sizes in poor-condition individuals. These exciting phenomena in beetle horns have recently been revealed at the molecular level with the advent of next-generation sequencing. This section reviews the latest research on a horned beetle, the Japanese rhinoceros beetle Trypoxylus dichotomus, whose genome was recently sequenced.

Published

2021

20. Evolutionary transition of doublesex regulation from sex-specific splicing to male-specific transcription in termites

Author

Teruyuki Niimi, Hiroki Gotoh, Yoshinobu Hayashi, Shuji Shigenobu, Kiyoto Maekawa, Keima Kai, Yudai Masuoka, Kokuto Fujiwara, and Satoshi Miyazaki

Subjects

Social evolution, Multidisciplinary, biology, Science, Doublesex, biology.organism_classification, Genome, Article, Exon, Evolutionary biology, RNA splicing, Cryptocercus, Medicine, Evolutionary developmental biology, Entomology, Transcription factor, Gene, Synteny

Abstract

The sex determination gene doublesex (dsx) encodes a transcription factor with two domains, oligomerization domain 1 (OD1) and OD2, and is present throughout insects. Sex-specific Dsx splicing isoforms regulate the transcription of target genes and trigger sex differentiation in all Holometabola examined to date. However, in some hemimetabolous insects, dsx is not spliced sexually and its sequence is less conserved. Here, to elucidate evolutionary changes in dsx in domain organisation and regulation in termites, we searched genome and/or transcriptome databases for the dsx OD1 and OD2 in seven termite species and their sister group (Cryptocercus woodroaches). Molecular phylogenetic and synteny analyses identified OD1 sequences of termites and C. punctulatus that clustered with dsx of Holometabola and regarded them as dsx orthologues. The Cryptocercus dsx orthologue containing OD2 was spliced sexually, as previously shown in other insects. However, OD2 was not found in all termite dsx orthologues. These orthologues were encoded by a single exon in three termites for which genome information is available; they were not alternatively spliced but transcribed in a male-specific manner in two examined species. Evolution of dsx regulation from sex-specific splicing to male-specific transcription may have occurred at an early stage of social evolution in termites.

Published

2021

21. Genomic and transcriptomic analyses of the subterranean termite Reticulitermes speratus: gene duplication facilitates social evolution

Author

Moe Kimura, Kohei Oguchi, Hajime Yaguchi, Kiyoto Maekawa, Atsushi Toyoda, Satoshi Miyazaki, Hiroki Gotoh, Yasuhiro Sugime, Yudai Masuoka, Ryutaro Suzuki, Ryota Saiki, Gaku Tokuda, Shogo Suzuki, Masaru K. Hojo, Masatoshi Matsunami, Teruyuki Niimi, Dai Watanabe, Yoshinobu Hayashi, Shuji Shigenobu, Masaru Y Hojo, Kouhei Toga, and Toru Miura

Subjects

Evolutionary biology, Gene duplication, Subfunctionalization, Neofunctionalization, Genomics, Biology, Social evolution, biology.organism_classification, Gene, Rhinotermitidae, Genome

Abstract

SummaryTermites are model social organisms characterized by a polyphenic caste system. Subterranean termites (Rhinotermitidae) are ecologically and economically important species, including acting as destructive pests. Rhinotermitidae occupies an important evolutionary position within the clade representing an intermediate taxon between the higher (Termitidae) and lower (other families) termites. Here, we report the genome, transcriptome and methylome of the Japanese subterranean termite Reticulitermes speratus. The analyses highlight the significance of gene duplication in social evolution in this termite. Gene duplication associated with caste-biased gene expression is prevalent in the R. speratus genome. Such duplicated genes encompass diverse categories related to social functions, including lipocalins (chemical communication), cellulases (wood digestion and social interaction), lysozymes (social immunity), geranylgeranyl diphosphate synthase (social defense) and a novel class of termite lineage-specific genes with unknown functions. Paralogous genes were often observed in tandem in the genome, but the expression patterns were highly variable, exhibiting caste biases. Some duplicated genes assayed were expressed in caste-specific organs, such as the accessory glands of the queen ovary and frontal glands in soldier heads. We propose that gene duplication facilitates social evolution through regulatory diversification leading to caste-biased expression and subfunctionalization and/or neofunctionalization that confers caste-specialized functions.Significance StatementTermites are model social organisms characterized by a sophisticated caste system, where distinct castes arise from the same genome. Our genomics data of Japanese subterranean termite provides insights into the evolution of the social system, highlighting the significance of gene duplication. Gene duplication associated with caste-biased gene expression is prevalent in the termite genome. Many of the duplicated genes were related to social functions, such as chemical communication, social immunity and defense, and they often expressed in caste-specific organs. We propose that gene duplication facilitates social evolution through regulatory diversification leading to caste-biased expression and functional specialization. In addition, since subterranean termites are ecologically and economically important species including destructive pests in the world, our genomics data serves as a foundation for these studies.

Published

2021

22. Dimorphic sperm formation by Sex-lethal

Author

Hiroki Gotoh, Hiroyuki Oshima, Hiroki Sakai, Teruyuki Niimi, Toshinobu Yaginuma, Takaaki Daimon, Ken Sahara, and Kodai Yuri

Subjects

0106 biological sciences, 0301 basic medicine, Male, endocrine system, sex determination, Moths, 010603 evolutionary biology, 01 natural sciences, Oogenesis, apyrene sperm, Germline, 03 medical and health sciences, Spermatheca, Bombyx mori, Drosophilidae, Melanogaster, Animals, Drosophila Proteins, Spermatogenesis, reproductive and urinary physiology, sperm polymorphism, Multidisciplinary, biology, urogenital system, fungi, RNA-Binding Proteins, Sex-lethal, Biological Sciences, Sex Determination Processes, biology.organism_classification, Bombyx, Sperm, Spermatozoa, Cell biology, 030104 developmental biology, Drosophila melanogaster, Fertility, Female, Butterflies, Developmental Biology

Abstract

Significance Sperm exhibit dramatic evolutionarily divergent morphologies in almost all taxa. Some sexually reproductive species show polymorphisms in the sperm produced by single males. Here, we focused on Sex-lethal (Sxl), which is the master sex-determination gene in Drosophila melanogaster, and investigated its function in the lepidopteran insect Bombyx mori. Our genetic analyses revealed that Sxl is essential for the formation of anucleate nonfertile parasperm. It is not expected that Sxl would be involved in sperm polymorphisms. Yet, whereas many morphological observations and ecological surveys have been conducted on sperm polymorphisms, this paper identifies the gene involved in sperm polymorphisms. Moreover, we clearly demonstrate that parasperm of B. mori is necessary for sperm migration in female organs., Sex is determined by diverse mechanisms and master sex-determination genes are highly divergent, even among closely related species. Therefore, it is possible that homologs of master sex-determination genes might have alternative functions in different species. Herein, we focused on Sex-lethal (Sxl), which is the master sex-determination gene in Drosophila melanogaster and is necessary for female germline development. It has been widely shown that the sex-determination function of Sxl in Drosophilidae species is not conserved in other insects of different orders. We investigated the function of Sxl in the lepidopteran insect Bombyx mori. In lepidopteran insects (moths and butterflies), spermatogenesis results in two different types of sperm: nucleated fertile eupyrene sperm and anucleate nonfertile parasperm, also known as apyrene sperm. Genetic analyses using Sxl mutants revealed that the gene is indispensable for proper morphogenesis of apyrene sperm. Similarly, our analyses using Sxl mutants clearly demonstrate that apyrene sperm are necessary for eupyrene sperm migration from the bursa copulatrix to the spermatheca. Therefore, apyrene sperm is necessary for successful fertilization of eupyrene sperm in B. mori. Although Sxl is essential for oogenesis in D. melanogaster, it also plays important roles in spermatogenesis in B. mori. Therefore, the ancestral function of Sxl might be related to germline development.

Published

2019

23. Establishment of transgenic lines for jumpstarter method using a composite transposon vector in the ladybird beetle, Harmonia axyridis.

Author

Hisashi Kuwayama, Hiroki Gotoh, Yusuke Konishi, Hideto Nishikawa, Toshinobu Yaginuma, and Teruyuki Niimi

Subjects

Medicine, Science

Abstract

In this post-genomic era, genome-wide functional analysis is indispensable. The recent development of RNA interference techniques has enabled researchers to easily analyze gene function even in non-model organisms. On the other hand, little progress has been made in the identification and functional analyses of cis-regulatory elements in non-model organisms. In order to develop experimental platform for identification and analyses of cis-regulatory elements in a non-model organism, in this case, the ladybird beetle, Harmonia axyridis, we established transgenic transposon-tagged lines using a novel composite vector. This vector enables the generation of two types of insertion products (jumpstarter and mutator). The jumpstarter portion carries a transposase gene, while the mutator segment carries a reporter gene for detecting enhancers. The full-composite element is flanked by functional termini (required for movement); however, the mutator region has an extra terminus making it possible for the mutator to remobilize on its own, thus leaving an immobile jumpstarter element behind. Each insertion type is stable on its own, but once crossed, jumpstarters can remobilize mutators. After crossing a jumpstarter and mutator line, all tested G2 females gave rise to at least one new insertion line in the next generation. This jumping rate is equivalent to the P-element-mediated jumpstarter method in Drosophila. These established transgenic lines will offer us the ideal experimental materials for the effective screening and identification of enhancers in this species. In addition, this jumpstarter method has the potential to be as effective in other non-model insect species and thus applicable to any organism.

Published

2014

24. Developmental link between sex and nutrition; doublesex regulates sex-specific mandible growth via juvenile hormone signaling in stag beetles.

Author

Hiroki Gotoh, Hitoshi Miyakawa, Asano Ishikawa, Yuki Ishikawa, Yasuhiro Sugime, Douglas J Emlen, Laura C Lavine, and Toru Miura

Subjects

Genetics, QH426-470

Abstract

Sexual dimorphisms in trait expression are widespread among animals and are especially pronounced in ornaments and weapons of sexual selection, which can attain exaggerated sizes. Expression of exaggerated traits is usually male-specific and nutrition sensitive. Consequently, the developmental mechanisms generating sexually dimorphic growth and nutrition-dependent phenotypic plasticity are each likely to regulate the expression of extreme structures. Yet we know little about how either of these mechanisms work, much less how they might interact with each other. We investigated the developmental mechanisms of sex-specific mandible growth in the stag beetle Cyclommatus metallifer, focusing on doublesex gene function and its interaction with juvenile hormone (JH) signaling. doublesex genes encode transcription factors that orchestrate male and female specific trait development, and JH acts as a mediator between nutrition and mandible growth. We found that the Cmdsx gene regulates sex differentiation in the stag beetle. Knockdown of Cmdsx by RNA-interference in both males and females produced intersex phenotypes, indicating a role for Cmdsx in sex-specific trait growth. By combining knockdown of Cmdsx with JH treatment, we showed that female-specific splice variants of Cmdsx contribute to the insensitivity of female mandibles to JH: knockdown of Cmdsx reversed this pattern, so that mandibles in knockdown females were stimulated to grow by JH treatment. In contrast, mandibles in knockdown males retained some sensitivity to JH, though mandibles in these individuals did not attain the full sizes of wild type males. We suggest that moderate JH sensitivity of mandibular cells may be the default developmental state for both sexes, with sex-specific Dsx protein decreasing sensitivity in females, and increasing it in males. This study is the first to demonstrate a causal link between the sex determination and JH signaling pathways, which clearly interact to determine the developmental fates and final sizes of nutrition-dependent secondary-sexual characters.

Published

2014

25. Sexual dimorphism and heightened conditional expression in a sexually selected weapon in the Asian rhinoceros beetle

Author

Hiroki Gotoh, Laura Corley Lavine, Robert A. Zinna, Ian Dworkin, Teruyuki Niimi, Annika Johns, and Douglas J. Emlen

Subjects

Male, 0301 basic medicine, Sex Characteristics, Sequence Analysis, RNA, Horn (anatomy), Physiological condition, Animal Structures, Rhinoceros, Biology, Coleoptera, Sexual dimorphism, Sexual Behavior, Animal, 03 medical and health sciences, 030104 developmental biology, Mate choice, Evolutionary biology, Sexual selection, Genetics, Trait, Animals, Female, Transcriptome, Gene, Ecology, Evolution, Behavior and Systematics

Abstract

Among the most dramatic examples of sexual selection are the weapons used in battles between rival males over access to females. As with ornaments of female choice, the most "exaggerated" sexually selected weapons vary from male to male more widely than other body parts (hypervariability), and their growth tends to be more sensitive to nutritional state or physiological condition compared with growth of other body parts ("heightened" conditional expression). Here, we use RNAseq analysis to build on recent work exploring these mechanisms in the exaggerated weapons of beetles, by examining patterns of differential gene expression in exaggerated (head and thorax horns) and non-exaggerated (wings, genitalia) traits in the Asian rhinoceros beetle, Trypoxylus dichotomus. Our results suggest that sexually dimorphic expression of weaponry involves large-scale changes in gene expression, relative to other traits, while nutrition-driven changes in gene expression in these same weapons are less pronounced. However, although fewer genes overall were differentially expressed in high- vs. low-nutrition individuals, the number of differentially expressed genes varied predictably according to a trait's degree of condition dependence (head horn > thorax horn > wings > genitalia). Finally, we observed a high degree of similarity in direction of effects (vectors) for subsets of differentially expressed genes across both sexually dimorphic and nutritionally responsive growth. Our results are consistent with a common set of mechanisms governing sexual size dimorphism and condition dependence.

Published

2018

26. Evolutionary transition of doublesex regulation in termites and cockroaches: from sex-specific splicing to male-specific transcription

Author

Shuji Shigenobu, Hiroki Gotoh, Kokuto Fujiwara, Satoshi Miyazaki, Teruyuki Niimi, Yudai Masuoka, Keima Kai, Kiyoto Maekawa, and Yoshinobu Hayashi

Subjects

Gene isoform, Genetics, Exon, Transcription (biology), RNA splicing, Doublesex, Biology, Genome, Transcription factor, Gene

Abstract

The sex determination gene doublesex (dsx), which encodes a transcription factor with two domains: oligomerisation domain 1 (OD1) and OD2, is conserved among insects. The sex-specific Dsx splicing isoforms regulate the transcription of target genes and trigger sex differentiation in all holometabolous insects examined to date. However, in some hemimetabolous insects, dsx is less conserved and not spliced sexually. Here, to elucidate evolutionary changes in dsx in the gene structure and its regulatory manner in termites, we searched genome and/or transcriptome databases for the OD1 and OD2 of dsx in six termite species and their sister group (woodroach). Molecular phylogenetic analysis identified OD1 sequences of termites and a woodroach clustered with dsx of holometabolous insects and regarded them as dsx orthologues. In the woodroach, a dsx orthologue containing OD2 was spliced sexually, as previously shown in other insects. However, OD2 were not found in all termite dsx orthologues. These orthologues were encoded by only a single exon in three termites with genome information; they were not alternatively spliced, but transcribed in a male-specific manner in two species examined. Evolution of dsx regulation from sex-specific splicing to male-specific transcription might be occurred at the early stage of social evolution in termites.

Published

2021

27. Computational analyses decipher the primordial folding coding the 3D structure of the beetle horn

Author

Hiroki Gotoh, Keisuke Matsuda, Shigeru Kondo, Yasuhiro Inoue, and Haruhiko Adachi

Subjects

Multidisciplinary, Body Patterning, Science, fungi, Biophysics, X-Ray Microtomography, Biology, Models, Biological, Article, Computational biology and bioinformatics, Coleoptera, Imaging, Three-Dimensional, Animal Shells, Evolutionary biology, Developmental biology, Image Processing, Computer-Assisted, Animals, Medicine, Computer Simulation, Primordium, Algorithms, Horns

Abstract

The beetle horn primordium is a complex and compactly folded epithelial sheet located beneath the larval cuticle. Only by unfolding the primordium the complete 3D shape of the horn appears, suggesting that the morphology of beetle horns is coded in the primordial folding pattern. To decipher the folding pattern, we have developed a method to manipulate the primordial local folding, reproduced it on a computer, and clarified the contribution of the folding of each primordium region to transformation. We found that the three major morphological changes (branching of distal tips, proximodistal elongation, and angular change) were caused by the folding of different regions, and that the folding mechanism was also different depending on the region. The computational methods we used are applicable to the morphological study of other exoskeletal animals.

Published

2020

28. Genetical control of 2D pattern and depth of the primordial furrow that prefigures 3D shape of the rhinoceros beetle horn

Author

Teruyuki Niimi, Keisuke Matsuda, Hiroki Gotoh, Haruhiko Adachi, and Shigeru Kondo

Subjects

0301 basic medicine, animal structures, lcsh:Medicine, Rhinoceros, Epithelial folding, Biology, Article, 03 medical and health sciences, 0302 clinical medicine, Imaging, Three-Dimensional, Developmental biology, Genetics, Animals, Primordium, lcsh:Science, Multidisciplinary, Receptors, Notch, Horn (anatomy), lcsh:R, Cell biology, Coleoptera, 030104 developmental biology, embryonic structures, lcsh:Q, RNA Interference, 030217 neurology & neurosurgery

Abstract

The head horn of the Asian rhinoceros beetle develops as an extensively folded primordium before unfurling into its final 3D shape at the pupal molt. The information of the final 3D structure of the beetle horn is prefigured in the folding pattern of the developing primordium. However, the developmental mechanism underlying epithelial folding of the primordium is unknown. In this study, we addressed this gap in our understanding of the developmental patterning of the 3D horn shape of beetles by focusing on the formation of furrows at the surface of the primordium that become the bifurcated 3D shape of the horn. By gene knockdown analysis via RNAi, we found that knockdown of the gene Notch disturbed overall horn primordial furrow depth without affecting the 2D furrow pattern. In contrast, knockdown of CyclinE altered 2D horn primordial furrow pattern without affecting furrow depth. Our results show how the depth and 2D pattern of primordial surface furrows are regulated at least partially independently during beetle horn development, and how both can alter the final 3D shape of the horn.

Published

2020

29. Genetical control of 2D pattern and depth of the primordial furrow that codes 3D shape of the rhinoceros beetle horn

Author

Haruhiko Adachi, Hiroki Gotoh, Teruyuki Niimi, Shigeru Kondo, and Keisuke Matsuda

Subjects

Horn (anatomy), Rhinoceros, Epithelial folding, Primordium, Living cell, Biology, Cell biology

Abstract

The head horn of the Asian rhinoceros beetle develops as extensively folded primordia before unfurling into its final 3D shape at the pupal molt. The information of the final 3D structure of the beetle horn is encoded in the folding pattern of the developing primordia. However, the developmental mechanism underlying epithelial folding of the primordia is unknown. In this study, we addressed this gap in our understanding of the developmental patterning of the 3D horn shape of beetles by focusing on the formation of surficial furrows that become the bifurcated 3D shape of the horn. By gene knockdown screening via RNAi, we found that knockdown of the geneNotchdisturbed overall horn primordia furrow depth without affecting 2D furrow pattern. In contrast, knockdown ofCyclinEaltered 2D horn primordia furrow pattern without affecting furrow depth. From these results, depth and 2D pattern of primordial surficial furrow are likely to be regulated independently during the development and both of change can alter the final 3D shape.Author SummaryIn insects, some large structure is made under the old exoskeleton before the molting. Long horn of rhino-beetle is one of extreme cases. The beetle horn is compactly packed as furrowed primordia under the larval exoskeleton. At molting, the primordia is extended to form its final 3D horn shape as blowing up furrows like a balloon. This transformation from primordia to final horn does not required any living cell activities. Thus, characteristics of furrows of primordia actually determine the final 3D shape. However, molecular mechanisms and genetic basis of furrow formation is not well understood not only in beetle horn but also in any other insects. In this study, by using beetle horn as a model, we addressed what kind of genetic factors are contributed to primordial furrow formation. By gene knockdown screening, we found that knockdown of the geneNotchdisturbed primordial furrow depth without affecting 2D furrow pattern. In contrast, knockdown ofCyclinEaltered 2D furrow pattern without affecting furrow depth. In both case, final horn shapes were disturbed. From these results, we concluded that both of the depth and 2D pattern of primordial furrow can contribute final shape, but their development is controlled independently.

Published

2020

30. Method for estimating the area expansion rate distribution of epithelial cell sheets in three-dimensional morphogenesis

Author

Kentaro MORIKAWA, Shinichi MORITA, Kazuki SAKURA, Hiroki GOTOH, Teruyuki NIIMI, and Yasuhiro INOUE

Published

2022

31. Anisotropy of cell division and epithelial sheet bending via apical constriction shape the complex folding pattern of beetle horn primordia

Author

Haruhiko Adachi, Teruyuki Niimi, Yasuhiro Inoue, Keisuke Matsuda, Shigeru Kondo, and Hiroki Gotoh

Subjects

0301 basic medicine, Embryology, animal structures, Morphology (linguistics), Cell division, Biology, Gene Knockout Techniques, 03 medical and health sciences, Morphogenesis, Animals, Primordium, Cuticle (hair), Sex Characteristics, Horn (anatomy), fungi, Pupa, food and beverages, Cell Differentiation, Apical constriction, Biological Evolution, Cell biology, Coleoptera, Folding (chemistry), 030104 developmental biology, Stalk, embryonic structures, Anisotropy, Insect Proteins, Cell Division, Developmental Biology

Abstract

Insects can dramatically change their outer morphology at molting. To prepare for this drastic transformation, insects generate new external organs as folded primordia under the old cuticle. At molting, these folded primordia are physically extended to form their final outer shape in a very short time. Beetle horns are a typical example. Horn primordia are derived from a flat head epithelial sheet, on which deep furrows are densely added to construct the complex folded structure. Because the 3D structure of the pupa horn is coded in the complex furrow pattern, it is indispensable to know how and where the furrows are set. Here, we studied the mechanism of furrow formation using dachsous (ds) gene knocked down beetles that have shorter and fatter adult horns. The global shape of the beetle horn primordia is mushroom like, with dense local furrows across its surface. Knockdown of ds by RNAi changed the global shape of the primordia, causing the stalk region become apparently thicker. The direction of cell division is biased in wildtype horns to make the stalk shape thin and tall. However, in ds knocked down beetles, it became random, resulting in the short and thick stalk shape. On the other hand, a fine and dense local furrow was not significantly affected by the ds knockdown. In developing wildtype horn primordia, we observed that, before the local furrow is formed, the apical constriction signal emerged at the position of the future furrow, suggesting the pre-pattern for the fine furrow pattern. According to the results, we propose that development of complex horn primordia can be roughly divided to two distinct processes, 1) development of global primordia shape by anisotropic cell division, and 2) local furrow formation via actin-myosin dependent apical constriction of specific cells.

Published

2018

32. The Fat-Dachsous signaling pathway regulates growth of horns in Trypoxylus dichotomus, but does not affect horn allometry

Author

Laura Corley Lavine, Teruyuki Niimi, Mark D. Lavine, Hiroki Gotoh, James A. Hust, Amy M. Worthington, and Robert A. Zinna

Subjects

Male, 0301 basic medicine, Appendage, Sex Characteristics, Gene knockdown, biology, Physiology, Horn (anatomy), Rhinoceros, Cadherins, Cell biology, Coleoptera, Sexual dimorphism, 03 medical and health sciences, Insulin receptor, 030104 developmental biology, Gene Knockdown Techniques, Insect Science, biology.protein, Animals, Allometry, Signal transduction, Signal Transduction

Abstract

Males of the Asian rhinoceros beetle, Trypoxylus dichotomus, possess exaggerated head and thoracic horns that scale dramatically out of proportion to body size. While studies of insulin signaling suggest that this pathway regulates nutrition-dependent growth including exaggerated horns, what regulates disproportionate growth has yet to be identified. The Fat signaling pathway is a potential candidate for regulating disproportionate growth of sexually-selected traits, a hypothesis we advanced in a previous paper (Gotoh et al., 2015). To investigate the role of Fat signaling in the growth and scaling of the sexually dimorphic, condition-dependent traits of the in the Asian rhinoceros beetle T. dichotomus, we used RNA interference to knock down expression of fat and its co-receptor dachsous. Knockdown of fat, and to a lesser degree dachsous, caused shortening and widening of appendages, including the head and thoracic horns. However, scaling of horns to body size was not affected. Our results show that Fat signaling regulates horn growth in T. dichotomus as it does in appendage growth in other insects. However, we provide evidence that Fat signaling does not mediate the disproportionate, positive allometric growth of horns in T. dichotomus.

Published

2018

33. Juvenile hormone regulates extreme mandible growth in male stag beetles.

Author

Hiroki Gotoh, Richard Cornette, Shigeyuki Koshikawa, Yasukazu Okada, Laura Corley Lavine, Douglas J Emlen, and Toru Miura

Subjects

Medicine, Science

Abstract

The morphological diversity of insects is one of the most striking phenomena in biology. Evolutionary modifications to the relative sizes of body parts, including the evolution of traits with exaggerated proportions, are responsible for a vast range of body forms. Remarkable examples of an insect trait with exaggerated proportions are the mandibular weapons of stag beetles. Male stag beetles possess extremely enlarged mandibles which they use in combat with rival males over females. As with other sexually selected traits, stag beetle mandibles vary widely in size among males, and this variable growth results from differential larval nutrition. However, the mechanisms responsible for coupling nutrition with growth of stag beetle mandibles (or indeed any insect structure) remain largely unknown. Here, we demonstrate that during the development of male stag beetles (Cyclommatus metallifer), juvenile hormone (JH) titers are correlated with the extreme growth of an exaggerated weapon of sexual selection. We then investigate the putative role of JH in the development of the nutritionally-dependent, phenotypically plastic mandibles, by increasing hemolymph titers of JH with application of the JH analog fenoxycarb during larval and prepupal developmental periods. Increased JH signaling during the early prepupal period increased the proportional size of body parts, and this was especially pronounced in male mandibles, enhancing the exaggerated size of this trait. The direction of this response is consistent with the measured JH titers during this same period. Combined, our results support a role for JH in the nutrition-dependent regulation of extreme mandible growth in this species. In addition, they illuminate mechanisms underlying the evolution of trait proportion, the most salient feature of the evolutionary diversification of the insects.

Published

2011

34. The function of appendage patterning genes in mandible development of the sexually dimorphic stag beetle

Author

Laura Corley Lavine, Hiroki Gotoh, Asano Ishikawa, Yuki Ishikawa, Toru Miura, Hitoshi Miyakawa, Robert A. Zinna, Douglas J. Emlen, and Yasuhiro Sugime

Subjects

Male, 0106 biological sciences, 0301 basic medicine, Stag beetle, media_common.quotation_subject, Dachshund, Morphogenesis, Mandible, Insect, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Animals, Molecular Biology, Body Patterning, media_common, Appendage, Sex Characteristics, biology, Mandible (insect mouthpart), Cell Biology, Anatomy, Sex Determination Processes, biology.organism_classification, Biological Evolution, Arthropod mouthparts, Coleoptera, ErbB Receptors, Sexual dimorphism, 030104 developmental biology, Evolutionary biology, Insect Proteins, Female, Developmental Biology

Abstract

One of the defining features of the evolutionary success of insects is the morphological diversification of their appendages, especially mouthparts. Although most insects share a common mouthpart ground plan, there is remarkable diversity in the relative size and shapes of these appendages among different insect lineages. One of the most prominent examples of mouthpart modification can be found in the enlargement of mandibles in stag beetles (Coleoptera, Insecta). In order to understand the proximate mechanisms of mouthpart modification, we investigated the function of appendage-patterning genes in mandibular enlargement during extreme growth of the sexually dimorphic mandibles of the stag beetle Cyclommatus metallifer. Based on knowledge from Drosophila and Tribolium studies, we focused on seven appendage patterning genes (Distal-less (Dll), aristaless (al), dachshund (dac), homothorax (hth), Epidermal growth factor receptor (Egfr), escargot (esg), and Keren (Krn). In order to characterize the developmental function of these genes, we performed functional analyses by using RNA interference (RNAi). Importantly, we found that RNAi knockdown of dac resulted in a significant mandible size reduction in males but not in female mandibles. In addition to reducing the size of mandibles, dac knockdown also resulted in a loss of the serrate teeth structures on the mandibles of males and females. We found that al and hth play a significant role during morphogenesis of the large male-specific inner mandibular tooth. On the other hand, knockdown of the distal selector gene Dll did not affect mandible development, supporting the hypothesis that mandibles likely do not contain the distal-most region of the ancestral appendage and therefore co-option of Dll expression is unlikely to be involved in mandible enlargement in stag beetles. In addition to mandible development, we explored possible roles of these genes in controlling the divergent antennal morphology of Coleoptera.

Published

2017

35. The Insulin Signaling Substrate Chico and the Ecdysone Response Element Broad Both Regulate Growth of the Head Horns in the Asian Rhinoceros Beetle, Trypoxylus dichotomus

Author

Hiroki Gotoh, Laura Corley Lavine, Abigail Hayes, and Mark D. Lavine

Subjects

0106 biological sciences, 0301 basic medicine, Male, Candidate gene, Ecdysone, Response element, Plant Science, Biology, Response Elements, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Tensin, Animals, Insulin, Gene knockdown, Horn (anatomy), Cell biology, Coleoptera, Insulin receptor, 030104 developmental biology, chemistry, biology.protein, Insect Proteins, Animal Science and Zoology, Signal transduction, Head, Signal Transduction

Abstract

Males of the Asian rhinoceros beetle, Trypoxylus dichotomus, possess exaggerated head and thoracic horns that scale dramatically out of proportion to body size. While RNAi-mediated knockdowns of the insulin receptor suggest that the insulin signaling pathway regulates nutrition-dependent growth including exaggerated horns, the genes that regulate disproportionate growth have yet to be identified. We used RNAi-mediated knockdown of several genes to investigate their potential role in growth and scaling of the sexually dimorphic, exaggerated head horns of T. dichotomus. Knockdown of the insulin signaling substrate chico and the ecdysone response element broad caused significant decreases in head horn length, while having no or minimal effects on other structures such as elytra and tibiae. However, scaling of horns to body size was not affected by either knockdown. In addition, knockdown of phosphatase and tensin homolog, a negative regulator of the insulin signaling pathway, had no significant effects on any trait. Our results do not identify any candidate genes that may specifically mediate the allometric aspect of horn growth, but they do confirm the insulin signaling pathway as a mediator of conditional trait expression, and importantly implicate the ecdysone signaling pathway, possibly in conjunction with insulin signaling, as an additional mediator of horn growth.

Published

2019

36. Termite soldier mandibles are elongated by dachshund under hormonal and Hox gene controls

Author

Shuji Shigenobu, Kohei Oguchi, Yoshinobu Hayashi, Hiroki Gotoh, Toru Miura, Shigeyuki Koshikawa, Yasuhiro Sugime, and Masatoshi Matsunami

Subjects

0106 biological sciences, 0303 health sciences, Gene knockdown, biology, Dachshund, Morphogenesis, 010603 evolutionary biology, 01 natural sciences, Cell biology, 03 medical and health sciences, Insulin receptor, Downregulation and upregulation, RNA interference, Juvenile hormone, biology.protein, Hox gene, Molecular Biology, 030304 developmental biology, Developmental Biology

Abstract

In social insects, interactions among colony members trigger caste differentiation with morphological modifications. In termite soldier differentiation, the mandible size considerably increases through two moltings (via the presoldier stage) under the control of juvenile hormone (JH). Regulatory genes are predicted to provide patterning information that induces the mandible-specific cell proliferation. To identify factors responsible for the mandibular enlargement, expression analyses of 18 candidate genes were carried out in the termite Hodotermopsis sjostedti. Among those, dachshund (dac), which identifies the intermediate domain along the proximodistal appendage axis, showed mandible-specific upregulation prior to the molt into presoldiers, which can explain the pattern of cell proliferation for the mandibular elongation. Knockdown of dac by RNAi reduced the mandibular length and distorted its morphology. Furthermore, the epistatic relationships among Methoprene tolerant, Insulin receptor, Deformed (Dfd) and dac were revealed by combined RNAi and qRT-PCR analyses, suggesting that dac is regulated by Dfd, downstream of the JH and insulin signaling pathways. Thus, caste-specific morphogenesis is controlled by interactions between the factors that provide spatial information and physiological status.

Published

2019

37. Mechanisms regulating phenotypic plasticity in wing polyphenic insects

Author

Abigail Hayes, Hiroki Gotoh, Xinda Lin, Mark D. Lavine, and Laura Corley Lavine

Subjects

Phenotypic plasticity, animal structures, Wing, Small ovary, Polyphenism, Evolutionary biology, media_common.quotation_subject, Large ovary, Morphology (biology), Insect, Biology, Phenotype, media_common

Abstract

Wing polyphenisms are found in a diversity of insect species. These insects are characterized by their ability to produce multiple, discrete, alternate morphologies based on environmental signals received during development from a single genotype. Individuals within a species that exhibit wing polyphenism have varying degrees of flight capability based on their wing morphology. This classic example of a life history trade-off between migration (the winged morph) and reproduction (the short-winged morph) is predicated on the prediction that the long wing form is at a reproductive disadvantage compared to the short wing form. Many species of aphids, brown planthoppers, and crickets exhibit this remarkable ability to assess environmental cues before producing either a long wing, small ovary female or a short wing, large ovary female. Data from studies of environmental factors such as nutrition, density, injury, photoperiod, temperature, interactions with other species, and pesticides are discussed. A comprehensive review of endocrine and cell signalling evidence is synthesized and compared. The goal of this review is to synthesize the environmental, endocrine, and cell signalling information on these insects to determine what the next steps are for research in this area. Developmental phenotypic plasticity is vital for the success of a species and we explore the mechanisms for how species respond to environmental stimuli from the gene to the phenotype.

Published

2019

38. The activin signaling transcription factor Smox is an essential regulator of appendage size during regeneration after autotomy in the crayfish

Author

Hiroshi Miyanishi, Laura Corley Lavine, Junpei Shinji, Mark D. Lavine, and Hiroki Gotoh

Subjects

0106 biological sciences, 0301 basic medicine, animal structures, Astacoidea, Biology, 010603 evolutionary biology, 01 natural sciences, 03 medical and health sciences, Transcription (biology), RNA interference, Animals, Regeneration, Cloning, Molecular, Transcription factor, Ecology, Evolution, Behavior and Systematics, Gene knockdown, Regeneration (biology), Extremities, Activin receptor, Smad Proteins, Receptor-Regulated, Cell biology, 030104 developmental biology, Gene Knockdown Techniques, Signal transduction, Developmental Biology, Transforming growth factor

Abstract

Members of the phylum Arthropoda, comprising over 80% of total animal species, have evolved regenerative abilities, but little is known about the molecular mechanisms mediating this process. Transforming growth factor β (TGF-β) signaling mediates a diverse set of essential processes in animals and is a good candidate pathway for regulation of regeneration in arthropods. In this study we investigated the role of activin signaling, a TGF-β superfamily pathway, in limb regeneration in the crayfish. We identified and cloned a downstream transcription factor in the activin pathway, Smox, and characterized its function with regard to other elements of the activin signaling pathway. Gene knockdown of Smox by RNAi induced regeneration of complete but smaller pereopods after autotomy. This indicates that activin signaling via Smox functions in regulation of pereopod growth and size. The expression levels of both Smox and the activin receptor babo were closely correlated with molting. The expression level of Smox increased when babo was knocked down by RNAi, indicating that Smox and babo transcription are linked. Our study suggests that the Babo-Smox system in activin signaling is conserved in decapods, and supports an evolutionary conservation of this aspect of molecular signaling during regeneration between protostomes and deuterostomes.

Published

2018

39. Appendage regeneration after autotomy is mediated by Baboon in the crayfish Procambarus fallax f. virginalis Martin, Dorn, Kawai, Heiden and Scholtz, 2010 (Decapoda: Astacoidea: Cambaridae)

Author

Toyoji Kaneko, Hiroshi Miyanishi, Hiroki Gotoh, and Junpei Shinji

Subjects

0106 biological sciences, 0301 basic medicine, Appendage, Marmorkrebs, Decapoda, Zoology, Anatomy, Aquatic Science, Biology, biology.organism_classification, Crayfish, 010603 evolutionary biology, 01 natural sciences, Crustacean, Cambaridae, 03 medical and health sciences, 030104 developmental biology, Procambarus fallax, Autotomy

Abstract

Autotomy is an adaptive response in which animals escape from predators by shedding their own appendages. It is made possible by the presence of an efficient mechanism for regeneration. Decapod crustaceans frequently exhibit excellent abilities to regenerate complete pereopods in just a few molts following autotomy. The molecular basis of regeneration pereopods in decapods remains unclear. We identified the primary structure of Baboon (Babo), a type I TGF-β superfamily receptor involved in the activin pathway, in the crayfish, Procambarus fallax f. virginalis Martin, Dorn, Kawai, Heiden and Scholtz, 2010. Molecular cloning revealed that babo possesses three splice variants. The expression levels of the functional babo transcript did not show increases during regeneration. RNA interference (RNAi) targeting a common region of the babo sequence, however, caused a reduction in regenerated pereopod lengths. No loss or reduction in a specific article was observed. Instead, the regenerated legs were smaller but retained the morphology and proportions of regenerated legs from control animals. Babo thus appears to control the growth, but not the pattern, of legs during the regeneration process in decapod crustaceans.

Published

2016

40. Endocrine Control of Exaggerated Trait Growth in Rhinoceros Beetles

Author

Teruyuki Niimi, Adam G. Dolezal, Aurora Kraus, Hiroki Gotoh, Laura Corley Lavine, Robert A. Zinna, Douglas J. Emlen, and Colin S. Brent

Subjects

Male, 0301 basic medicine, medicine.medical_specialty, Phenylcarbamates, Zoology, Context (language use), Rhinoceros, Plant Science, Biology, 03 medical and health sciences, chemistry.chemical_compound, Hemolymph, Internal medicine, medicine, Animals, Fenoxycarb, Sex Characteristics, Mandible (insect mouthpart), Pupa, Coleoptera, Juvenile Hormones, Sexual dimorphism, Phenotype, 030104 developmental biology, Endocrinology, chemistry, Larva, Juvenile hormone, Instar, Female, Animal Science and Zoology, Caste determination

Abstract

Juvenile hormone (JH) is a key insect growth regulator frequently involved in modulating phenotypically plastic traits such as caste determination in eusocial species, wing polymorphisms in aphids, and mandible size in stag beetles. The jaw morphology of stag beetles is sexually-dimorphic and condition-dependent; males have larger jaws than females and those developing under optimum conditions are larger in overall body size and have disproportionately larger jaws than males raised under poor conditions. We have previously shown that large males have higher JH titers than small males during development, and ectopic application of fenoxycarb (JH analog) to small males can induce mandibular growth similar to that of larger males. What remains unknown is whether JH regulates condition-dependent trait growth in other insects with extreme sexually selected structures. In this study, we tested the hypothesis that JH mediates the condition-dependent expression of the elaborate horns of the Asian rhinoceros beetle, Trypoxylus dichotomus. The sexually dimorphic head horn of this beetle is sensitive to nutritional state during larval development. Like stag beetles, male rhinoceros beetles receiving copious food produce disproportionately large horns for their body size compared with males under restricted diets. We show that JH titers are correlated with body size during the late feeding and early prepupal periods, but this correlation disappears by the late prepupal period, the period of maximum horn growth. While ectopic application of fenoxycarb during the third larval instar significantly delayed pupation, it had no effect on adult horn size relative to body size. Fenoxycarb application to late prepupae also had at most a marginal effect on relative horn size. We discuss our results in context of other endocrine signals of condition-dependent trait exaggeration and suggest that different beetle lineages may have co-opted different physiological signaling mechanisms to achieve heightened nutrient-sensitive weapon growth.

Published

2016

41. Rhinoceros beetle horn development reveals deep parallels with dung beetles

Author

Shuji Shigenobu, Kouhei Toga, Mutsuki Mase, Junko Morita, Teruyuki Niimi, Yasuhiro Kitano, Laura Corley Lavine, Robert A. Zinna, Hiroki Gotoh, Koji Kadota, Jema Rushe, Takeshi Mizutani, Karen Yuzaki, Takahiro Ohde, Shinichi Morita, Moe Nakata, Yuta Ito, Kenshi Wada, and Douglas J. Emlen

Subjects

0301 basic medicine, Cancer Research, Life Cycles, Biochemistry, RNA interference, Larvae, Beetles, Genus, Medicine and Health Sciences, Genetics (clinical), Dynastinae, Dung beetle, Horns, Appendage, Dung Beetles, Drosophila Melanogaster, Eukaryota, Gene Expression Regulation, Developmental, Animal Models, Thorax, Biological Evolution, Insects, Nucleic acids, Coleoptera, Phenotype, Genetic interference, Experimental Organism Systems, Larva, Epigenetics, Drosophila, Anatomy, Research Article, lcsh:QH426-470, Arthropoda, Zoology, Rhinoceros, Biology, Research and Analysis Methods, 03 medical and health sciences, Model Organisms, Species Specificity, Genetics, Animals, Scarabaeinae, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Horn (anatomy), Organisms, Biology and Life Sciences, biology.organism_classification, Invertebrates, lcsh:Genetics, 030104 developmental biology, Onthophagus, Animal Studies, RNA, Gene expression, Developmental Biology

Abstract

Beetle horns are attractive models for studying the evolution of novel traits, as they display diverse shapes, sizes, and numbers among closely related species within the family Scarabaeidae. Horns radiated prolifically and independently in two distant subfamilies of scarabs, the dung beetles (Scarabaeinae), and the rhinoceros beetles (Dynastinae). However, current knowledge of the mechanisms underlying horn diversification remains limited to a single genus of dung beetles, Onthophagus. Here we unveil 11 horn formation genes in a rhinoceros beetle, Trypoxylus dichotomus. These 11 genes are mostly categorized as larval head- and appendage-patterning genes that also are involved in Onthophagus horn formation, suggesting the same suite of genes was recruited in each lineage during horn evolution. Although our RNAi analyses reveal interesting differences in the functions of a few of these genes, the overwhelming conclusion is that both head and thoracic horns develop similarly in Trypoxylus and Onthophagus, originating in the same developmental regions and deploying similar portions of appendage patterning networks during their growth. Our findings highlight deep parallels in the development of rhinoceros and dung beetle horns, suggesting either that both horn types arose in the common ancestor of all scarabs, a surprising reconstruction of horn evolution that would mean the majority of scarab species (~35,000) actively repress horn growth, or that parallel origins of these extravagant structures resulted from repeated co-option of the same underlying developmental processes., Author summary Goliath and Hercules beetles include some of the largest insects known, and the horns they wield are spectacular. These ‘rhinoceros’ beetles form a subfamily within the Scarabaeidae, a clade containing ~35,000 primarily hornless species. The other subfamily of horned scarabs, dung beetles, is distantly related and their horns are considered a separate origin and parallel radiation. We characterize horn development in a rhinoceros beetle and show that the details are surprisingly similar to the horns of dung beetles. Our results reveal exciting parallels at the level of underlying developmental mechanism. The superficial similarity of these two types of beetle horns mirrors an even deeper similarity in the pathways and genes responsible for their construction.

Published

2018

42. Termite soldier mandibles are elongated by

Author

Yasuhiro, Sugime, Kohei, Oguchi, Hiroki, Gotoh, Yoshinobu, Hayashi, Masatoshi, Matsunami, Shuji, Shigenobu, Shigeyuki, Koshikawa, and Toru, Miura

Subjects

Homeodomain Proteins, Behavior, Animal, Gene Expression Profiling, Genes, Homeobox, Gene Expression Regulation, Developmental, Nuclear Proteins, Epistasis, Genetic, Isoptera, Mandible, Molting, Juvenile Hormones, Morphogenesis, Animals, Insect Proteins, Insulin, RNA Interference, Body Patterning, Signal Transduction

Abstract

In social insects, interactions among colony members trigger caste differentiation with morphological modifications. In termite soldier differentiation, the mandible size considerably increases through two moltings (via the presoldier stage) under the control of juvenile hormone (JH). Regulatory genes are predicted to provide patterning information that induces the mandible-specific cell proliferation. To identify factors responsible for the mandibular enlargement, expression analyses of 18 candidate genes were carried out in the termite

Published

2018

43. Functional mechanics of beetle mandibles: Honest signaling in a sexually selected system

Author

Hiroki Gotoh, William Wilde, Laura Corley Lavine, Maria R. Mills, Rahmi S. Nemri, Emily A. Carlson, and Brook O. Swanson

Subjects

Male, 0106 biological sciences, 0301 basic medicine, Cyclommatus metallifer, Physiology, Stag beetle, Zoology, Mandible, Biology, Muscle mass, 010603 evolutionary biology, 01 natural sciences, Bite Force, 03 medical and health sciences, Functional morphology, Genetics, Animals, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Sex Characteristics, Wing, Mandible (insect mouthpart), Anatomy, biology.organism_classification, Coleoptera, Bite force quotient, 030104 developmental biology, Female, Animal Science and Zoology, Allometry

Abstract

Male stag beetles possess colossal mandibles, which they wield in combat to obtain access to females. As with many other sexually selected weapons, males with longer mandibles win more fights. However, variation in the functional morphology of these structures, used in male-male combat, is less well understood. In this study, mandible bite force, gape, structural strength, and potential tradeoffs are examined across a wide size range for one species of stag beetle, Cyclommatus metallifer. We found that not only does male mandible size demonstrate steep positive allometry, but the shape, relative bite force, relative gape, and safety factor of the mandibles also change with male size. Allometry in these functionally important mandibular traits suggests that larger males with larger mandibles should be better fighters, and that the mandibles can be considered an honest signal of male fighting ability. However, negative allometry in mandible structural safety factor, wing size, and flight muscle mass suggest significant costs and a possible limit on the size of the mandibles. J. Exp. Zool. 325A:3-12, 2016. © 2015 Wiley Periodicals, Inc.

Published

2015

44. The Fat/Hippo signaling pathway links within-disc morphogen patterning to whole-animal signals during phenotypically plastic growth in insects

Author

Douglas J. Emlen, James A. Hust, Toru Miura, Teruyuki Niimi, Laura Corley Lavine, and Hiroki Gotoh

Subjects

Hippo signaling pathway, Phenotypic plasticity, Polyphenism, Evolutionary biology, Ecology, Hippo signaling, fungi, Juvenile hormone, Trait, Biology, Phenotype, Developmental Biology, Morphogen

Abstract

Background Insects exhibit a diversity of environmentally sensitive phenotypes that allow them to be an extraordinarily successful group. For example, mandible size in male stag beetles is exquisitely sensitive to the larval nutritional environment and is a reliable signal of male condition. Results To date, studies of how such phenotypically plastic traits develop have focused on two types of mechanistic processes. Local, tissue-specific genetic mechanisms specify the shape and approximate final size of structures, whereas whole-animal hormonal signaling mechanisms modulate trait growth in response to environmental circumstance, including the body size and nutritional state of each individual. Hormones such as juvenile hormone, ecdysteroids, and/or ligands of the insulin-signaling pathway specify whether traits grow and regulate how much growth occurs across a diversity of insect groups. What remains to be shown is how the local, tissue-specific developmental genetic pathways interact with these whole animal hormonal signaling pathways during development to yield phenotypically plastic patterns of trait growth. Conclusions Because the Fat/Hippo signaling pathway coordinates trait growth and development through its interactions with morphogens and hormonal pathways, we propose that Fat/Hippo signaling is a missing mechanistic link coordinating environmentally sensitive trait development in insects. Developmental Dynamics 244:1039-1045, 2015. © 2015 Wiley Periodicals, Inc.

Published

2015

45. High juvenile hormone titre and abdominal activation of JH signalling may induce reproduction of termite neotenics

Author

Kiyoto Maekawa, Hiroki Gotoh, Ryota Saiki, Kouhei Toga, and Toru Miura

Subjects

medicine.medical_specialty, biology, Zoology, Vitellogenin, Endocrinology, Polyphenism, RNA interference, Insect Science, Internal medicine, Juvenile hormone, Gene expression, Genetics, medicine, biology.protein, Juvenile, Nymph, Molecular Biology, Neoteny

Abstract

Termite castes are a key example of polyphenism, in which reproductive division of labour is clearly seen in colonies. The reproductive castes in termites include primary and neotenic reproductives; primary reproductives found a new colony whereas neotenics succeed them in the reproductive role when the primary reproductives die or become senescent. Neotenics usually differentiate from nymphs or workers by developing functional gonads while retaining juvenile characteristics; however, the developmental mechanism during neotenic differentiation remains poorly understood. Juvenile hormone (JH) mediates a number of aspects of developmental regulation in caste differentiation in termites. In the present study we quantified JH titres in neotenic reproductives of Reticulitermes speratus, and compared these with other developmental stages. In addition, expression changes in JH signalling gene homologues (Methoprene-tolerant [Met], Kruppel-homolog1, Broad-Complex) in the head, thorax and abdomen were investigated during neotenic differentiation. Finally, we examined the function of Met in reproduction of neotenics by RNA interference (RNAi). Our results showed that the JH titres of neotenics were significantly higher than those of nymphs and workers. JH signalling genes were highly expressed in neotenic abdomens, compared with those in workers and nymphs. Met RNAi resulted in the inhibition of vitellogenin gene expression in newly moulted neotenics. These results suggest that the fertility of neotenics might be controlled by a large increase of JH titres and body-part-specific activation of JH signalling pathways.

Published

2015

46. Recent advances in understanding the mechanisms of sexually dimorphic plasticity: insights from beetle weapons and future directions

Author

Robert A. Zinna, Hiroki Gotoh, Takaaki Kojima, and Teruyuki Niimi

Subjects

0301 basic medicine, Male, Sex Characteristics, Sexual differentiation, Doublesex, Biology, Adaptation, Physiological, Article, Sexual dimorphism, Coleoptera, 03 medical and health sciences, 030104 developmental biology, Molecular level, Evolutionary biology, Insect Science, Animals, Female, Ecology, Evolution, Behavior and Systematics, Organism, Omics technologies, Sex characteristics

Abstract

Many traits that are sexually dimorphic, appearing either differently or uniquely in one sex, are also sensitive to an organism's condition. This phenomenon seems to have evolved to limit genetic conflict between traits that are under different selective pressures in each sex. Recent work has shed light on the molecular and developmental mechanisms that govern this condition sensitive growth, and this work has now expanded to encompass both sexual dimorphism as well as conditionally plastic growth, as it seems the two phenomena are linked on a molecular level. In all cases studied the gene doublesex, a conserved regulator of sex differentiation, controls both sexual dimorphism as well as the condition-dependent plastic responses common to these traits. However, the advent of next-generation -omics technologies has allowed researchers to decipher the common and diverged mechanisms of sexually dimorphic plasticity and expand investigations beyond the foundation laid by studies utilizing beetle weapons.

Published

2017

47. Complex furrows in a 2D epithelial sheet code the 3D structure of a beetle horn

Author

Shigeru Kondo, Yuki Tajika, Hiroki Gotoh, Yasuhiro Inoue, Takamichi Sushida, Hitoshi Aonuma, Masakazu Akiyama, Keisuke Matsuda, and Teruyuki Niimi

Subjects

0301 basic medicine, media_common.quotation_subject, Morphogenesis, lcsh:Medicine, Biology, Article, 03 medical and health sciences, Animals, Primordium, Computer Simulation, Metamorphosis, lcsh:Science, Cell shape, Process (anatomy), media_common, Multidisciplinary, Horn (anatomy), lcsh:R, Metamorphosis, Biological, Cell migration, Epithelial Cells, Anatomy, Cell biology, Biomechanical Phenomena, Coleoptera, 030104 developmental biology, lcsh:Q, Horn structure

Abstract

The external organs of holometabolous insects are generated through two consecutive processes: the development of imaginal primordia and their subsequent transformation into the adult structures. During the latter process, many different phenomena at the cellular level (e.g. cell shape changes, cell migration, folding and unfolding of epithelial sheets) contribute to the drastic changes observed in size and shape. Because of this complexity, the logic behind the formation of the 3D structure of adult external organs remains largely unknown. In this report, we investigated the metamorphosis of the horn in the Japanese rhinoceros beetle Trypoxylus dichotomus. The horn primordia is essentially a 2D epithelial cell sheet with dense furrows. We experimentally unfolded these furrows using three different methods and found that the furrow pattern solely determines the 3D horn structure, indicating that horn formation in beetles occurs by two distinct processes: formation of the furrows and subsequently unfolding them. We postulate that this developmental simplicity offers an inherent advantage to understanding the principles that guide 3D morphogenesis in insects.

Published

2017

48. A novel imaging method for correlating 2D light microscopic data and 3D volume data based on block-face imaging

Author

Hitoshi Ueno, Keiya Iijima, Hiroki Gotoh, Tohru Murakami, Yuhei Yoshimoto, Hiroshi Yorifuji, Maiko Takahashi-Ikezawa, and Yuki Tajika

Subjects

0301 basic medicine, Data Analysis, Pathology, medicine.medical_specialty, Science, Fluorescent Antibody Technique, Image processing, Article, 03 medical and health sciences, Mice, 0302 clinical medicine, Imaging, Three-Dimensional, Microscopy, medicine, Single specimen, Block face, Image Processing, Computer-Assisted, Animals, Humans, Frozen section procedure, Multidisciplinary, Histocytochemistry, Embryo, Mammalian, Molecular Imaging, 030104 developmental biology, Medicine, Molecular imaging, 030217 neurology & neurosurgery, Biomedical engineering, Volume (compression), Brain Stem

Abstract

We have developed an imaging method designated as correlative light microscopy and block-face imaging (CoMBI), which contributes to improve the reliability of morphological analyses. This method can collect both the frozen sections and serial block-face images in a single specimen. The frozen section can be used for conventional light microscopic analysis to obtain 2-dimensional (2D) anatomical and molecular information, while serial block-face images can be used as 3-dimensional (3D) volume data for anatomical analysis. Thus, the sections maintain positional information in the specimen, and allows the correlation of 2D microscopic data and 3D volume data in a single specimen. The subjects can vary in size and type, and can cover most specimens encountered in biology. In addition, the required system for our method is characterized by cost-effectiveness. Here, we demonstrated the utility of CoMBI using specimens ranging in size from several millimeters to several centimeters, i.e., mouse embryos, human brainstem samples, and stag beetle larvae, and present successful correlation between the 2D light microscopic images and 3D volume data in a single specimen.

Published

2017

49. Identification of an alternative knockdown resistance (kdr)-like mutation, M918L, and a novel mutation, V1010A, in theThrips tabacivoltage-gated sodium channel gene

Author

Douglas B. Walsh, Meixiang Wu, Timothy D. Waters, Hiroki Gotoh, and Laura Corley Lavine

Subjects

Genetics, Mutation, Pyrethroid, Thrips, biology, Point mutation, Knockdown resistance, General Medicine, biology.organism_classification, medicine.disease_cause, chemistry.chemical_compound, chemistry, Valine, Insect Science, parasitic diseases, medicine, PEST analysis, Agronomy and Crop Science, Gene

Abstract

BACKGROUND Knockdown resistance (kdr) has been identified as a main mechanism against pyrethroid insecticides in many arthropod pests including in the onion thrips, Thrips tabaci. To characterize and identify pyrethroid-resistance in onion thrips in Washington state, we conducted insecticide bioassays and sequenced a region of the voltage gated sodium channel gene from several different T. tabaci populations. RESULTS Field collected Thrips tabaci were found to have large variations in resistance to the pyrethroid insecticide lambda-cyhalothrin. We identified two single nucleotide substitutions in our analysis of a partial sequence of the T. tabaci voltage-gated sodium channel gene. One mutation resulted in the non-synonymous substitution of methionine with leucine (M918L), which is well known to be responsible for super knockdown resistance in some pest species. Another non-synonymous substitution, a valine (GTT) to alanine (GCT) replacement at amino acid 1010 (V1010A) was identified in our study and was associated with lambda-cyhalothrin resistance. CONCLUSION We have characterized a known kdr mutation and identified a novel mutation in the voltage-gated sodium channel gene of Thrips tabaci associated with resistance to lambda-cyhalothrin. This gene region and these mutations are expected to be useful in the development of a diagnostic test to detect kdr resistance in many onion thrips populations. © 2013 Society of Chemical Industry

Published

2013

50. Effect of Juvenoids on Predator-Induced Polyphenism in the Water Flea,Daphnia pulex

Author

Naoki Sugimoto, Hiroki Gotoh, Toru Miura, and Hitoshi Miyakawa

Subjects

Larva, biology, Physiology, Ecology, media_common.quotation_subject, Zoology, Insect, biology.organism_classification, Daphnia pulex, chemistry.chemical_compound, Polyphenism, chemistry, Kairomone, Juvenile hormone, Genetics, Animal Science and Zoology, Fenoxycarb, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Hormone, media_common

Abstract

In Daphnia pulex, juveniles form "neckteeth" a defensive structure on their heads, in response to predatory kairomones released by Chaoborus larvae. This phenomenon provides a model experimental system for the study of developmental mechanisms and evolutionary processes in predator-induced polyphenisms. Although it is thought that kairomone signals are sensed and converted into physiological signals resulting in morphological changes, little is known about the endocrine and physiological mechanisms of this process. Juvenile hormones and related chemicals, that is, juvenoids, are key hormones responsible for various physiological events in insects, including polyphenisms. In some crustaceans, methyl farnesoate (MF) is known to act as a juvenoid. In order to investigate the functions of juvenoids in defense morph formation, we treated daphnids with MF as well as JHIII (Juvenile Hormone III, an insect juvenoid) and fenoxycarb (a synthetic juvenile hormone analog) during their developmental stages. Strikingly, in the first-instar juveniles, all examined juvenoids stimulated the formation of neckteeth only in the presence of kairomones, not by themselves. This juvenoid effect on the neckteeth formation might be due to disturbance of the JH pathway. Juvenoid treatments reduced tail-spine length, whereas predatory kairomones are known to elongate tail spine. These results suggest that other physiological factors are responsible for the tail-spine elongation.

Published

2013