Your search keyword '"Tohru Yano"' showing total 7 results

1. Molecular developmental mechanism in polypterid fish provides insight into the origin of vertebrate lungs

Author

Norifumi Tatsumi, Ritsuko Kobayashi, Masataka Okabe, Tohru Yano, Koji Fujimura, Norihiro Okada, and Masatsugu Noda

Subjects

0301 basic medicine, Fish Proteins, Male, Embryo, Nonmammalian, Chick Embryo, Article, Mesoderm, 03 medical and health sciences, stomatognathic system, biology.animal, medicine, Animals, Bichir, Enhancer, Coelacanth, Lung, Multidisciplinary, biology, Latimeria, Fishes, Vertebrate, Gene Expression Regulation, Developmental, Anatomy, respiratory system, biology.organism_classification, Biological Evolution, Polypterus senegalus, respiratory tract diseases, body regions, 030104 developmental biology, medicine.anatomical_structure, Enhancer Elements, Genetic, Evolutionary biology, Larva, Female, Chickens

Abstract

The lung is an important organ for air breathing in tetrapods and originated well before the terrestrialization of vertebrates. Therefore, to better understand lung evolution, we investigated lung development in the extant basal actinopterygian fish Senegal bichir (Polypterus senegalus). First, we histologically confirmed that lung development in this species is very similar to that of tetrapods. We also found that the mesenchymal expression patterns of three genes that are known to play important roles in early lung development in tetrapods (Fgf10, Tbx4 and Tbx5) were quite similar to those of tetrapods. Moreover, we found a Tbx4 core lung mesenchyme-specific enhancer (C-LME) in the genomes of bichir and coelacanth (Latimeria chalumnae) and experimentally confirmed that these were functional in tetrapods. These findings provide the first molecular evidence that the developmental program for lung was already established in the common ancestor of actinopterygians and sarcopterygians.

Published

2016

2. Evolutionary Changes in the Developmental Origin of Hatching Gland Cells in Basal Ray-Finned Fishes

Author

Masataka Okabe, Kaori Sano, Mari Kawaguchi, Shigeki Yasumasu, Tohru Yano, and Tatsuki Nagasawa

Subjects

0301 basic medicine, Fish Proteins, animal structures, Embryo, Nonmammalian, 03 medical and health sciences, Sturgeon, Animals, Bichir, Phylogeny, Neural Plate, biology, Hatching, Endoderm, Fishes, Gene Expression Regulation, Developmental, Metalloendopeptidases, Cell Differentiation, Anatomy, biology.organism_classification, Biological Evolution, Cell biology, Gastrulation, 030104 developmental biology, Hypoblast, Neurula, embryonic structures, Animal Science and Zoology, Anura, Neural plate, Polypterus, Transcription Factors

Abstract

Hatching gland cells (HGCs) originate from different germ layers between frogs and teleosts, although the hatching enzyme genes are orthologous. Teleostei HGCs differentiate in the mesoendodermal cells at the anterior end of the involved hypoblast layer (known as the polster) in late gastrula embryos. Conversely, frog HGCs differentiate in the epidermal cells at the neural plate border in early neurula embryos. To infer the transition in the developmental origin of HGCs, we studied two basal ray-finned fishes, bichir (Polypterus) and sturgeon. We observed expression patterns of their hatching enzyme (HE) and that of three transcription factors that are critical for HGC differentiation: KLF17 is common to both teleosts and frogs; whereas FoxA3 and Pax3 are specific to teleosts and frogs, respectively. We then inferred the transition in the developmental origin of HGCs. In sturgeon, the KLF17, FoxA3, and HE genes were expressed during the tailbud stage in the cell mass at the anterior region of the body axis, a region corresponding to the polster in teleost embryos. In contrast, the bichir was suggested to possess both teleost- and amphibian-type HGCs, i.e. the KLF17 and FoxA3 genes were expressed in the anterior cell mass corresponding to the polster, and the KLF17, Pax3 and HE genes were expressed in dorsal epidermal layer of the head. The change in developmental origin is thought to have occurred during the evolution of basal ray-finned fish, because bichir has two HGCs, while sturgeon only has the teleost-type.

Published

2016

3. The making of differences between fins and limbs

Author

Tohru Yano and Koji Tamura

Subjects

Histology, Mechanism (biology), Ecology (disciplines), Cell Biology, Biological evolution, Anatomy, Biology, body regions, Evolutionary biology, %22">Fish , Molecular Biology, Ecology, Evolution, Behavior and Systematics, Developmental Biology

Abstract

‘Evo-devo’, an interdisciplinary field based on developmental biology, includes studies on the evolutionary processes leading to organ morphologies and functions. One fascinating theme in evo-devo is how fish fins evolved into tetrapod limbs. Studies by many scientists, including geneticists, mathematical biologists, and paleontologists, have led to the idea that fins and limbs are homologous organs; now it is the job of developmental biologists to integrate these data into a reliable scenario for the mechanism of fin-to-limb evolution. Here, we describe the fin-to-limb transition based on key recent developmental studies from various research fields that describe mechanisms that may underlie the development of fins, limb-like fins, and limbs.

Published

2012

4. The autopod: Its formation during limb development

Author

Hitoshi Yokoyama, Koji Tamura, Sayuri Yonei-Tamura, Hiroyuki Ide, and Tohru Yano

Subjects

Regulation of gene expression, Retinoic acid, Cell Biology, Cartilage metabolism, Anatomy, Biology, Cell biology, body regions, chemistry.chemical_compound, chemistry, embryonic structures, Limb development, Homeobox, Ephrin, Hox gene, HOXA13, Developmental Biology

Abstract

The autopod, including the mesopodium and the acropodium, is the most distal part of the tetrapod limb, and developmental mechanisms of autopod formation serve as a model system of pattern formation during development. Cartilage rudiments of the autopod develop after proximal elements have differentiated. The autopod region is marked by a change in the expression of two homeobox genes: future autopod cells are first Hoxa11/Hoxa13-double-positive and then Hoxa13-single-positive. The change in expression of these Hox genes is controlled by upstream mechanisms, including the retinoic acid pathway, and the expression of Hoxa13 is connected to downstream mechanisms, including the autopod-specific cell surface property mediated by molecules, including cadherins and ephrins/Ephs, for cell-to-cell communication and recognition. Comparative analyses of the expression of Hox genes in fish fins and tetrapod limb buds support the notion on the origin of the autopod in vertebrates. This review will focus on the cellular and molecular regulation of the formation of the autopod during development and evolutionary developmental aspects of the origin of the autopod.

Published

2008

5. Trunk exoskeleton in teleosts is mesodermal in origin

Author

Masato Kinoshita, Takuya Kaneko, Hiroyuki Takeda, Toru Kawanishi, Tohru Yano, Hiroki Yoshihara, Yasuhiro Kamei, Keiji Inohaya, Koji Tamura, and Atsuko Shimada

Subjects

Mesoderm, Multidisciplinary, animal structures, biology, Oryzias, General Physics and Astronomy, Neural crest, Vertebrate, General Chemistry, Anatomy, Skeleton (computer programming), Trunk, Embryonic stem cell, General Biochemistry, Genetics and Molecular Biology, Article, Exoskeleton, medicine.anatomical_structure, biology.animal, embryonic structures, medicine, %22">Fish , Animals, human activities, Skeleton

Abstract

The vertebrate mineralized skeleton is known to have first emerged as an exoskeleton that extensively covered the fossil jawless fish. The evolutionary origin of this exoskeleton has long been attributed to the emergence of the neural crest, but experimental evaluation for this is still poor. Here we determine the embryonic origin of scales and fin rays of medaka (teleost trunk exoskeletons) by applying long-term cell labelling methods, and demonstrate that both tissues are mesodermal in origin. Neural crest cells, however, fail to contribute to these tissues. This result suggests that the trunk neural crest has no skeletogenic capability in fish, instead highlighting the dominant role of the mesoderm in the evolution of the trunk skeleton. This further implies that the role of the neural crest in skeletogenesis has been predominant in the cephalic region from the early stage of vertebrate evolution., Trunk exoskeleton elements of non-tetrapods such as scales and fin rays are believed to derive from the neural crest. Shimada and colleagues use long-term cell labelling methods to show that these elements are actually derived from the mesoderm.

Published

2012

6. Mechanism of pectoral fin outgrowth in zebrafish development

Author

Koji Tamura, Gembu Abe, Hitoshi Yokoyama, Tohru Yano, and Koichi Kawakami

Subjects

Apical ectodermal ridge, animal structures, Mesenchyme, Green Fluorescent Proteins, Morphogenesis, Biology, Models, Biological, Animals, Genetically Modified, Endoskeleton, Apolipoproteins E, Ectoderm, medicine, Limb development, Animals, Zebrafish, Molecular Biology, Cell Shape, DNA Primers, Appendage, Homeodomain Proteins, Base Sequence, Fish fin, Gene Expression Regulation, Developmental, Anatomy, Zebrafish Proteins, biology.organism_classification, Biological Evolution, Recombinant Proteins, body regions, Fibroblast Growth Factors, medicine.anatomical_structure, Animal Fins, human activities, Developmental Biology, Transcription Factors

Abstract

Fins and limbs, which are considered to be homologous paired vertebrate appendages, have obvious morphological differences that arise during development. One major difference in their development is that the AER (apical ectodermal ridge), which organizes fin/limb development, transitions into a different, elongated organizing structure in the fin bud, the AF (apical fold). Although the role of AER in limb development has been clarified in many studies, little is known about the role of AF in fin development. Here, we investigated AF-driven morphogenesis in the pectoral fin of zebrafish. After the AER-AF transition at ∼36 hours post-fertilization, the AF was identifiable distal to the circumferential blood vessel of the fin bud. Moreover, the AF was divisible into two regions: the proximal AF (pAF) and the distal AF (dAF). Removing the AF caused the AER and a new AF to re-form. Interestingly, repeatedly removing the AF led to excessive elongation of the fin mesenchyme, suggesting that prolonged exposure to AER signals results in elongation of mesenchyme region for endoskeleton. Removal of the dAF affected outgrowth of the pAF region, suggesting that dAF signals act on the pAF. We also found that the elongation of the AF was caused by morphological changes in ectodermal cells. Our results suggest that the timing of the AER-AF transition mediates the differences between fins and limbs, and that the acquisition of a mechanism to maintain the AER was a crucial evolutionary step in the development of tetrapod limbs.

Published

2012

7. 09-P097 Apical fold morphogenesis in zebrafish fin; differences from tetrapod limb development

Author

Tohru Yano, Koichi Kawakami, Gembu Abe, Hitoshi Yokoyama, and Koji Tamura

Subjects

Embryology, biology, embryonic structures, Morphogenesis, Limb development, Fold (geology), Anatomy, biology.organism_classification, Zebrafish, Developmental Biology

Published

2009