Search

Your search keyword '"Chihiro Furumizu"' showing total 25 results
Start Over Author "Chihiro Furumizu"
25 results on '"Chihiro Furumizu"'

1. The RGF/GLV/CLEL Family of Short Peptides Evolved Through Lineage-Specific Losses and Diversification and Yet Conserves Its Signaling Role Between Vascular Plants and Bryophytes

Author

Chihiro Furumizu and Shinichiro Sawa

Subjects
RGF/GLV/CLEL, signaling peptide, land plant evolution, 1KP project, Marchantia polymorpha, homology, Plant culture, SB1-1110
Abstract

Short secreted plant peptides act as key signaling molecules and control a plethora of developmental and physiological processes. The ROOT GROWTH FACTOR (RGF)/GOLVEN (GLV)/CLE-Like (CLEL) family of peptides was discovered to be involved in root development in Arabidopsis thaliana. In contrast to active research efforts, which have been revealing receptors and downstream signaling components, little attention has been paid to evolutionary processes that shaped the RGF signaling system as we know it in angiosperms today. As a first step toward understanding how RGF signaling emerged and evolved, this study aimed to elucidate the phylogenetic distribution and functional conservation of RGF-like sequences. Using publicly available, genome and transcriptome data, RGF-like sequences were searched in 27 liverworts, 22 mosses, 8 hornworts, 23 lycophytes, 23 ferns, 38 gymnosperms, and 8 angiosperms. This led to the identification of more than four hundreds of RGF-like sequences in all major extant land plant lineages except for hornworts. Sequence comparisons within and between taxonomic groups identified lineage-specific characters. Notably, one of the two major RGF subgroups, represented by A. thaliana RGF6/GLV1/CLEL6, was found only in vascular plants. This subgroup, therefore, likely emerged in a common ancestor of vascular plants after its divergence from bryophytes. In bryophytes, our results infer independent losses of RGF-like sequences in mosses and hornworts. On the other hand, a single, highly similar RGF-like sequence is conserved in liverworts, including Marchantia polymorpha, a genetically tractable model species. When constitutively expressed, the M. polymorpha RGF-like sequence (MpRGF) affected plant development and growth both in A. thaliana and M. polymorpha. This suggests that MpRGF can exert known RGF-like effects and that MpRGF is under transcriptional control so that its potent activities are precisely controlled. These data suggest that RGFs are conserved as signaling molecules in both vascular plants and bryophytes and that lineage-specific diversification has increased sequence variations of RGFs. All together, our findings form a basis for further studies into RGF peptides and their receptors, which will contribute to our understandings of how peptide signaling pathways evolve.

Published
2021
Full Text
View/download PDF

2. Active suppression of a leaf meristem orchestrates determinate leaf growth

Author

John Paul Alvarez, Chihiro Furumizu, Idan Efroni, Yuval Eshed, and John L Bowman

Subjects
meristem, leaf development, leaf evolution, Arabidopsis, Medicine, Science, Biology (General), QH301-705.5
Abstract

Leaves are flat determinate organs derived from indeterminate shoot apical meristems. The presence of a specific leaf meristem is debated, as anatomical features typical of meristems are not present in leaves. Here we demonstrate that multiple NGATHA (NGA) and CINCINNATA-class-TCP (CIN-TCP) transcription factors act redundantly, shortly after leaf initiation, to gradually restrict the activity of a leaf meristem in Arabidopsis thaliana to marginal and basal domains, and that their absence confers persistent marginal growth to leaves, cotyledons and floral organs. Following primordia initiation, the restriction of the broadly acting leaf meristem to the margins is mediated by the juxtaposition of adaxial and abaxial domains and maintained by WOX homeobox transcription factors, whereas other marginal elaboration genes are dispensable for its maintenance. This genetic framework parallels the morphogenetic program of shoot apical meristems and may represent a relic of an ancestral shoot system from which seed plant leaves evolved.

Published
2016
Full Text
View/download PDF

3. Antagonistic roles for KNOX1 and KNOX2 genes in patterning the land plant body plan following an ancient gene duplication.

Author

Chihiro Furumizu, John Paul Alvarez, Keiko Sakakibara, and John L Bowman

Subjects
Genetics, QH426-470
Abstract

Neofunctionalization following gene duplication is thought to be one of the key drivers in generating evolutionary novelty. A gene duplication in a common ancestor of land plants produced two classes of KNOTTED-like TALE homeobox genes, class I (KNOX1) and class II (KNOX2). KNOX1 genes are linked to tissue proliferation and maintenance of meristematic potentials of flowering plant and moss sporophytes, and modulation of KNOX1 activity is implicated in contributing to leaf shape diversity of flowering plants. While KNOX2 function has been shown to repress the gametophytic (haploid) developmental program during moss sporophyte (diploid) development, little is known about KNOX2 function in flowering plants, hindering syntheses regarding the relationship between two classes of KNOX genes in the context of land plant evolution. Arabidopsis plants harboring loss-of-function KNOX2 alleles exhibit impaired differentiation of all aerial organs and have highly complex leaves, phenocopying gain-of-function KNOX1 alleles. Conversely, gain-of-function KNOX2 alleles in conjunction with a presumptive heterodimeric BELL TALE homeobox partner suppressed SAM activity in Arabidopsis and reduced leaf complexity in the Arabidopsis relative Cardamine hirsuta, reminiscent of loss-of-function KNOX1 alleles. Little evidence was found indicative of epistasis or mutual repression between KNOX1 and KNOX2 genes. KNOX proteins heterodimerize with BELL TALE homeobox proteins to form functional complexes, and contrary to earlier reports based on in vitro and heterologous expression, we find high selectivity between KNOX and BELL partners in vivo. Thus, KNOX2 genes confer opposing activities rather than redundant roles with KNOX1 genes, and together they act to direct the development of all above-ground organs of the Arabidopsis sporophyte. We infer that following the KNOX1/KNOX2 gene duplication in an ancestor of land plants, neofunctionalization led to evolution of antagonistic biochemical activity thereby facilitating the evolution of more complex sporophyte transcriptional networks, providing plasticity for the morphological evolution of land plant body plans.

Published
2015
Full Text
View/download PDF

6. Control of Fusarium and nematodes by entomopathogenic fungi for organic production of Zingiber officinale

Author

Surendra K. Dara, Shinichiro Sawa, Ni Putu Ratna Ayu Krishanti, Aya Yanagawa, Safendrri Komara Ragamustari, Akifumi Sugiyama, Masaru Kobayashi, Chihiro Furumizu, Minoru Kubo, and Emiria Chrysanti

Subjects
Fusarium, Cordyceps, Horticulture, biology, Fusarium oxysporum, Meloidogyne incognita, Biological pest control, Molecular Medicine, Beauveria bassiana, Zingiber officinale, biology.organism_classification, Terra incognita
Abstract

Ginger (genus Zingiber) is widely used as a spice and a medicinal herb worldwide and is the major ingredient of traditional local drinks such as jamu in Southeast Asia. Because ginger is frequently consumed, there is an increasing interest in organic ginger production without the use of synthetic agrochemicals. Recent studies have reported that certain kinds of entomopathogenic fungi (EPF) can establish endophytic- or mycorrhiza-like relationships with plants, thereby promoting plant growth and health, in addition to their typical role in crop protection as biological control agents. In this study, we explored the possibility of non-entomopathogenic effects of EPF Beauveria bassiana and Cordyceps fumosorosea on ginger plants (Zingiber officinale) via antagonism with Fusarium oxysporum or the parasitic nematode Meloidogyne incognita. The two EPF negatively affected the growth of F. oxysporum and survival of M. incognita in vitro. The application of EPF did not have any negative effect on the growth of ginger plants. Soil chemical properties were not different between the plots with or without EPF application, while the diversity of soil bacteria was observed to increase on application of EPF. At least C. fumosorosea appeared to persist in soil during the period of ginger cultivation. Thus, these EPF are potentially useful tools for producing chemical-free ginger.

Published
2021

7. The sequenced genomes of nonflowering land plants reveal the innovative evolutionary history of peptide signaling

Author

Chihiro Furumizu, Reidunn B. Aalen, Marta Hammerstad, Renate M Alling, Mari Wildhagen, Anders K. Krabberød, and Shinichiro Sawa

Subjects
AcademicSubjects/SCI01280, ved/biology.organism_classification_rank.species, Peptide, Plant Science, Biology, Genome, Evolution, Molecular, Terrestrial plant, Phylogeny, Plant Proteins, Plant evolution, chemistry.chemical_classification, AcademicSubjects/SCI01270, Phylogenetic tree, ved/biology, AcademicSubjects/SCI02288, AcademicSubjects/SCI02287, fungi, AcademicSubjects/SCI02286, food and beverages, Cell Biology, Meristem, Plant biology, chemistry, Evolutionary biology, Perspective, Embryophyta, Signal transduction, Peptides, Genome, Plant, Signal Transduction
Abstract

An understanding of land plant evolution is a prerequisite for in-depth knowledge of plant biology. Here we extract and explore information hidden in the increasing number of sequenced plant genomes, from bryophytes to angiosperms, to elucidate a specific biological question—how peptide signaling evolved. To conquer land and cope with changing environmental conditions, plants have gone through transformations that must have required innovations in cell-to-cell communication. We discuss peptides mediating endogenous and exogenous changes by interaction with receptors activating intracellular molecular signaling. Signaling peptides were discovered in angiosperms and operate in tissues and organs such as flowers, seeds, vasculature, and 3D meristems that are not universally conserved across land plants. Nevertheless, orthologs of angiosperm peptides and receptors have been identified in nonangiosperms. These discoveries provoke questions regarding coevolution of ligands and their receptors, and whether de novo interactions in peptide signaling pathways may have contributed to generate novel traits in land plants. The answers to such questions will have profound implications for the understanding of the evolution of cell-to-cell communication and the wealth of diversified terrestrial plants. Under this perspective, we have generated, analyzed, and reviewed phylogenetic, genomic, structural, and functional data to elucidate the evolution of peptide signaling., The identification of orthologs of Arabidopsis signaling peptides and their receptors in nonflowering plants suggest their importance in cell-to-cell communication in all land plants.

Published
2021

8. Solanum lycopersicum CLASS-II KNOX genes regulate fruit anatomy via gibberellin-dependent and independent pathways

Author

Amit Shtern, Alexandra Keren-Keiserman, Jean-Philippe Mauxion, Chihiro Furumizu, John Paul Alvarez, Ziva Amsellem, Naama Gil, Etel Motenko, Sharon Alkalai-Tuvia, Elazar Fallik, Nathalie Gonzalez, and Alexander Goldshmidt

Subjects
Physiology, Plant Science
Abstract

The pericarp is the predominant tissue determining the structural characteristics of most fruits. However, the molecular and genetic mechanisms controlling pericarp development remain only partially understood. Previous studies have identified that CLASS-II KNOX genes regulate fruit size, shape, and maturation in Arabidopsis thaliana and Solanum lycopersicum. Here we characterized the roles of the S. lycopersicum CLASS-II KNOX (TKN-II) genes in pericarp development via a detailed histological, anatomical, and karyotypical analysis of TKN-II gene clade mRNA-knockdown (35S:amiR-TKN-II) fruits. We identify that 35S:amiR-TKN-II pericarps contain more cells around their equatorial perimeter and fewer cell layers than the control. In addition, the cell sizes but not the ploidy levels of these pericarps were dramatically reduced. Further, we demonstrate that fruit shape and pericarp layer number phenotypes of the 35S:amiR-TKN-II fruits can be overridden by the procera mutant, known to induce a constitutive response to the plant hormone gibberellin. However, neither the procera mutation nor exogenous gibberellin application can fully rescue the reduced pericarp width and cell size phenotype of 35S:amiR-TKN-II pericarps. Our findings establish that TKN-II genes regulate tomato fruit anatomy, acting via gibberellin to control fruit shape but utilizing a gibberellin-independent pathway to control the size of pericarp cells.

Published
2022

9. Solanum lycopersicum CLASS-II KNOXgenes regulate fruit anatomy via gibberellin-dependent and independent pathways

Author

Amit Shtern, Alexandra Keren-Keiserman, Jean-Philippe Mauxion, Chihiro Furumizu, John Paul Alvarez, Ziva Amsellem, Naama Gil, Etel Motenko, Sharon Alkalai-Tuvia, Elazar Fallik, Nathalie Gonzalez, and Alexander Goldshmidt

Abstract

The pericarp is the predominant tissue determining the structural characteristics of most fruits. However, the molecular and genetic mechanisms controlling pericarp development remain only partially understood. Previous studies have identified that CLASS-II KNOX genes regulate fruit size, shape, and maturation inArabidopsis thalianaandSolanum lycopersicum. Here we characterized the roles of theSolanum lycopersicumCLASS-II KNOX (TKN-II) genes in pericarp development via a detailed histological, anatomical, and karyotype analysis of theTKN-IIknockdown (35S:amiR-TKN-II) fruits. We identify that35S:amiR-TKN-IIpericarps contain more cells around their equatorial perimeter and fewer cell layers than the control. In addition, the cell sizes but not the ploidy levels of these pericarps were dramatically reduced.Further, we demonstrate that fruit shape and pericarp layer number phenotypes of the35S:amiR-TKN-IIfruits can be overridden by theproceramutant, known to induce a constitutive response to the plant hormone gibberellin. However, neither theproceramutation nor exogenous gibberellin application can fully rescue the reduced pericarp width and cell size phenotype of35S:amiR-TKN-IIpericarps. Our findings establish that TKN-II genes regulate tomato fruit anatomy, acting via gibberellin to control fruit shape but utilizing a gibberellin-independent pathway to control the size of pericarp cells.HighlightTomatoCLASS-II KNOXgenes regulate fruit and pericarp anatomy via GA-dependent and independent pathways.

Published
2022

10. CLASS-II KNOX genes coordinate spatial and temporal ripening in tomato

Author

Alexandra Keren-Keiserman, Amit Shtern, Matan Levy, Daniel Chalupowicz, Chihiro Furumizu, John Paul Alvarez, Ziva Amsalem, Tzahi Arazi, Sharon Alkalai-Tuvia, Idan Efroni, Naomi Ori, John L Bowman, Elazar Fallik, and Alexander Goldshmidt

Subjects
Solanum lycopersicum, Physiology, Gene Expression Regulation, Plant, Fruit, Genetics, Arabidopsis, Plant Science, Focus Issue on Evolution of Plant Structure and Function, Ethylenes, Plant Proteins, Transcription Factors
Abstract

Fruits can be divided into dry and fleshy types. Dry fruits mature through senescence and fleshy fruits through ripening. Previous studies have indicated that partially common molecular networks could govern fruit maturation in these different fruit types. However, the nature of such networks remains obscure. CLASS-II KNOX genes were shown to regulate the senescence of the Arabidopsis (Arabidopsis thaliana) dry fruits, the siliques, but their roles in fleshy-fruit development are unknown. Here, we investigated the roles of the tomato (Solanum lycopersicum) CLASS-II KNOX (TKN-II) genes in fleshy fruit ripening using knockout alleles of individual genes and an artificial microRNA line (35S:amiR-TKN-II) simultaneously targeting all genes. 35S:amiR-TKN-II plants, as well as a subset of tkn-II single and double mutants, have smaller fruits. Strikingly, the 35S:amiR-TKN-II and tknII3 tknII7/+ fruits showed early ripening of the locular domain while their pericarp ripening was stalled. Further examination of the ripening marker-gene RIPENING INHIBITOR (RIN) expression and 35S:amiR-TKN-II rin-1 mutant fruits suggested that TKN-II genes arrest RIN activity at the locular domain and promote it in the pericarp. These findings imply that CLASS-II KNOX genes redundantly coordinate maturation in both dry and fleshy fruits. In tomato, these genes also control spatial patterns of fruit ripening, utilizing differential regulation of RIN activity at different fruit domains.

Published
2022

12. Database mining of plant peptide homologues

Author

Chihiro Furumizu, Baolong Zhang, Shinichiro Sawa, and Na Yuan

Subjects
0106 biological sciences, Signal peptide, Short Communication, Plant Immunity, Peptide, Plant Science, Computational biology, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Disease management (agriculture), 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, biology, Host (biology), Effector, Phytosulfokine, fungi, food and beverages, biology.organism_classification, chemistry, Agronomy and Crop Science, Bacteria, 010606 plant biology & botany, Biotechnology
Abstract

In plant-pathogen interactions, pathogens employ secreted molecules, known as effectors to overcome physical barriers, modulate plant immunity, and facilitate colonization. Among these diverse effectors, some are found to mimic the plant peptides, to target host's peptide receptors, and intervene in the peptide-regulated defense pathways and/or plant development. To better understand how pathogens have co-evolved with their plant hosts in order to improve disease management, we explored the presence of plant peptide mimics in microbes by bioinformatic analysis. In total, 36 novel peptide mimics belong to five plant peptide families were detected in bacterial and fungal kingdoms. Among them, phytosulfokine homologues were widely distributed in 22 phytopathogens and one bacterium, thereby constituted the largest proportion of the identified mimics. The putative functional peptide region is well conserved between plant and microbes, while the existence of a putative signal peptide varies between species. Our findings will increase understanding of plant-pathogen interactions, and provide new ideas for future studies of pathogenic mechanisms and disease management.

Published
2021

13. CLASS-II KNOX genes coordinate spatial and temporal patterns of the tomato ripening

Author

John P. Alvarez, Idan Efroni, Amit Shtern, Chihiro Furumizu, Ziva Amsellem, Daniel Chalupowicz, Sharon Tuvia-Alkalai, Tzahi Arazi, Elazar Fallik, Alexandra Keren-Keiserman, and Alexander Goldshmidt

Subjects
Senescence, Gene knockdown, chemistry.chemical_compound, Ethylene, chemistry, Arabidopsis, Ripening, Silique, Biology, biology.organism_classification, Gene, Phenotype, Cell biology
Abstract

Ripening is a complex developmental change of a mature organ, the fruit. In plants like a tomato, it involves softening, pigmentation, and biosynthesis of metabolites beneficial for the human diet. Examination of the transcriptional changes towards ripening suggests that redundant uncharacterized factors may be involved in the coordination of the ripening switch. Previous studies have demonstrated that Arabidopsis CLASS-II KNOX genes play a significant role in controlling the maturation of siliques and their transition to senescence. Here we examined the combined role of all four tomato CLASS-II KNOX genes in the maturation and ripening of fleshy fruits using an artificial microRNA targeting them simultaneously. As expected, the knockdown plants (35S::amiR-TKN-CL-II) exhibited leaves with increased complexity, reminiscent of the leaf phenotype of plants overexpressing CLASS-I KNOX, which antagonize CLASS-II KNOX gene functions. The fruits of 35S::amiR-TKN-CL-II plants were notably smaller than the control. While their internal gel/placenta tissue softened and accumulated the typical pigmentation, the pericarp color break took place ten days later than control, and eventually, it turned yellow instead of red.Additionally, the pericarp of 35S::amiR-TKN-CL-II fruits remained significantly firmer than control even after three weeks of shelf storage. Strikingly, the 35S::amiR-TKN-CL-II fruits showed early ethylene release and respiration peak, but these were correlated only with liquefaction and pigmentation of the internal tissues. Our findings suggest that CLASS-II KNOX genes are required to coordinate the spatial and temporal patterns of tomato fruit ripening.One sentence summaryTomato CLASS-II KNOX genes play antagonistic roles in the regulation of ripening at the internal fruit domains and pericarp.

Published
2021

14. Control of Fusarium and nematodes by entomopathogenic fungi for organic production of Zingiber officinale

Author

Aya, Yanagawa, Ni Putu Ratna Ayu, Krishanti, Akifumi, Sugiyama, Emiria, Chrysanti, Safendrri Komara, Ragamustari, Minoru, Kubo, Chihiro, Furumizu, Shinichiro, Sawa, Surendra K, Dara, and Masaru, Kobayashi

Subjects
Plants, Medicinal, Fusarium, Nematoda, Animals, Beauveria, Ginger
Abstract

Ginger (genus Zingiber) is widely used as a spice and a medicinal herb worldwide and is the major ingredient of traditional local drinks such as jamu in Southeast Asia. Because ginger is frequently consumed, there is an increasing interest in organic ginger production without the use of synthetic agrochemicals. Recent studies have reported that certain kinds of entomopathogenic fungi (EPF) can establish endophytic- or mycorrhiza-like relationships with plants, thereby promoting plant growth and health, in addition to their typical role in crop protection as biological control agents. In this study, we explored the possibility of non-entomopathogenic effects of EPF Beauveria bassiana and Cordyceps fumosorosea on ginger plants (Zingiber officinale) via antagonism with Fusarium oxysporum or the parasitic nematode Meloidogyne incognita. The two EPF negatively affected the growth of F. oxysporum and survival of M. incognita in vitro. The application of EPF did not have any negative effect on the growth of ginger plants. Soil chemical properties were not different between the plots with or without EPF application, while the diversity of soil bacteria was observed to increase on application of EPF. At least C. fumosorosea appeared to persist in soil during the period of ginger cultivation. Thus, these EPF are potentially useful tools for producing chemical-free ginger.

Published
2021

15. Insight into early diversification of leucine-rich repeat receptor-like kinases provided by the sequenced moss and hornwort genomes

Author

Shinichiro Sawa and Chihiro Furumizu

Subjects
0106 biological sciences, 0301 basic medicine, Subfamily, Lineage (evolution), Anthocerotophyta, Plant Science, Biology, 01 natural sciences, Genome, Hornwort, Evolution, Molecular, 03 medical and health sciences, Protein Domains, Phylogenetics, Genetics, Sphagnopsida, Gene family, Computer Simulation, Amino Acid Sequence, Phylogeny, Plant Proteins, Phylogenetic tree, Sequence Homology, Amino Acid, fungi, Genetic Variation, General Medicine, Genomics, biology.organism_classification, Multicellular organism, 030104 developmental biology, Evolutionary biology, Agronomy and Crop Science, Protein Kinases, Genome, Plant, 010606 plant biology & botany, Signal Transduction
Abstract

Identification of the subfamily X leucine-rich repeat receptor-like kinases in the recently sequenced moss and hornwort genomes points to their diversification into distinct groups during early evolution of land plants. Signal transduction mediated through receptor-ligand interactions plays key roles in controlling developmental and physiological processes of multicellular organisms, and plants employ diverse receptors in signaling. Leucine-rich repeat receptor-like kinases (LRR-RLKs) represent one of the largest receptor classes in plants and are structurally classified into subfamilies. LRR-RLKs of the subfamily X are unique in the variety of their signaling roles; they include receptors for steroid or peptide hormones as well as negative regulators of signaling through binding to other LRR-RLKs, raising a question as to how they diversified. However, our understanding of diversification processes of LRR-RLKs has been hindered by the paucity of genomic data in non-seed plants and limited taxa sampling in previous phylogenetic analyses. Here we analyzed the phylogeny of LRR-RLK X sequences collected from all major land plant lineages and show that this subfamily diversified into six major clades before the divergence between bryophytes and vascular plants. Notably, we have identified homologues of the brassinosteroid receptor, BRASSINOSTEROID INSENSITIVE 1 (BRI1), in the genomes of Sphagnum mosses, hornworts, and ferns, contrary to earlier reports that postulate the origin of BRI1-like LRR-RLKs in the seed plant lineage. The phylogenetic distribution of major clades illustrates that the current receptor repertoire was shaped through lineage-specific gene family expansion and independent gene losses, highlighting dynamic changes in the evolution of LRR-RLKs.

Published
2020

16. The Sequenced Genomes of Non-Flowering Land Plants Reveal the (R)Evolutionary History of Peptide Signaling

Author

Reidunn B. Aalen, Anders K. Krabberød, Marta Hammerstad, Renate M Alling, Mari Wildhagen, Shinichiro Sawa, and Chihiro Furumizu

Subjects
Plant evolution, chemistry.chemical_classification, Phylogenetic tree, ved/biology, fungi, ved/biology.organism_classification_rank.species, food and beverages, Peptide, Meristem, Biology, Genome, chemistry, Evolutionary biology, Terrestrial plant, Signal transduction, Receptor
Abstract

An understanding of land plant evolution is a prerequisite for in-depth knowledge of plant biology. Here we extract and explore information hidden in the increasing number of sequenced plant genomes, from bryophytes to angiosperms, to elucidate a specific biological question – how peptide signaling evolved. To conquer land and cope with changing environmental conditions, plants have gone through transformations that must have required a revolution in cell-to-cell communication. We discuss peptides mediating endogenous and exogenous changes by interaction with receptors activating intracellular molecular signaling. Signaling peptides were discovered in angiosperms and operate in tissues and organs like flowers, seeds, vasculature, and 3D meristems that are not universally conserved across land plants. Nevertheless, orthologues of angiosperm peptides and receptors have been identified in non-flowering plants. These discoveries provoke questions regarding the co-evolution of ligands and their receptors, and whetherde novointeractions in peptide signaling pathways may have contributed to generate novel traits in land plants. The answers to such questions will have profound implications for the understanding of evolution of cell-to-cell communication and the wealth of diversified terrestrial plants. Under this perspective we have generated, analyzed and reviewed phylogenetic, genomic, structural, and functional data to elucidate the evolution of peptide signaling.

Published
2020

17. 3D Body Evolution: Adding a New Dimension to Colonize the Land

Author

John L. Bowman, Chihiro Furumizu, Yuki Hirakawa, and Shinichiro Sawa

Subjects
0301 basic medicine, biology, fungi, food and beverages, biology.organism_classification, Physcomitrella patens, General Biochemistry, Genetics and Molecular Biology, Bryopsida, 03 medical and health sciences, Multicellular organism, 030104 developmental biology, Evolutionary biology, General Agricultural and Biological Sciences, Function (biology)
Abstract

Complex multicellular plant bodies evolved in both generations of land plants. A new study demonstrates that CLAVATA3-like peptides function via conserved receptors in Physcomitrella patens as key molecules for morphological innovation of 3D growth in land plants.

Published
2018

18. Evolution in the Cycles of Life

Author

Keiko Sakakibara, John L. Bowman, Chihiro Furumizu, and Tom Dierschke

Subjects
0301 basic medicine, Bryophyta, Haploidy, Biology, Phaeophyta, Magnoliopsida, 03 medical and health sciences, Meiosis, Chlorophyta, Genetics, medicine, Gene, Phylogeny, Homeodomain Proteins, fungi, Fungi, Eukaryota, Plants, Biological Evolution, Diploidy, Multicellular organism, 030104 developmental biology, medicine.anatomical_structure, Rhodophyta, Alternation of generations, Gamete, Homeobox, Ploidy, Function (biology)
Abstract

The life cycles of eukaryotes alternate between haploid and diploid phases, which are initiated by meiosis and gamete fusion, respectively. In both ascomycete and basidiomycete fungi and chlorophyte algae, the haploid-to-diploid transition is regulated by a pair of paralogous homeodomain protein encoding genes. That a common genetic program controls the haploid-to-diploid transition in phylogenetically disparate eukaryotic lineages suggests this may be the ancestral function for homeodomain proteins. Multicellularity has evolved independently in many eukaryotic lineages in either one or both phases of the life cycle. Organisms, such as land plants, exhibiting a life cycle whereby multicellular bodies develop in both the haploid and diploid phases are often referred to as possessing an alternation of generations. We review recent progress on understanding the genetic basis for the land plant alternation of generations and highlight the roles that homeodomain-encoding genes may have played in the evolution of complex multicellularity in this lineage.

Published
2016

19. Evolution of the Class IV HD-Zip Gene Family in Streptophytes

Author

Keiko Sakakibara, John L. Bowman, Chihiro Furumizu, Sandra K. Floyd, Dennis W. Stevenson, and Christopher S Zalewski

Subjects
gene family evolution, 0106 biological sciences, Most recent common ancestor, Arabidopsis, Regulatory Sequences, Nucleic Acid, Biology, 01 natural sciences, Evolution, Molecular, 03 medical and health sciences, Gene Expression Regulation, Plant, Phylogenetics, Gene duplication, Genetics, Gene family, Codon, Molecular Biology, Gene, Phylogeny, Discoveries, transcription factor, Ecology, Evolution, Behavior and Systematics, Plant Proteins, 030304 developmental biology, Homeodomain Proteins, Plant evolution, Leucine Zippers, 0303 health sciences, Base Sequence, Phylogenetic tree, Arabidopsis Proteins, fungi, gene duplication, food and beverages, Regulatory sequence, Multigene Family, Mutation, homeodomain leucine zipper, Embryophyta, Streptophyta, Transcription Factors, 010606 plant biology & botany
Abstract

Class IV homeodomain leucine zipper (C4HDZ) genes are plant-specific transcription factors that, based on phenotypes in Arabidopsis thaliana, play an important role in epidermal development. In this study, we sampled all major extant lineages and their closest algal relatives for C4HDZ homologs and phylogenetic analyses result in a gene tree that mirrors land plant evolution with evidence for gene duplications in many lineages, but minimal evidence for gene losses. Our analysis suggests an ancestral C4HDZ gene originated in an algal ancestor of land plants and a single ancestral gene was present in the last common ancestor of land plants. Independent gene duplications are evident within several lineages including mosses, lycophytes, euphyllophytes, seed plants, and, most notably, angiosperms. In recently evolved angiosperm paralogs, we find evidence of pseudogenization via mutations in both coding and regulatory sequences. The increasing complexity of the C4HDZ gene family through the diversification of land plants correlates to increasing complexity in epidermal characters.

Published
2013

21. Active suppression of a leaf meristem orchestrates determinate leaf growth

Author

Yuval Eshed, Chihiro Furumizu, John P. Alvarez, John L. Bowman, and Idan Efroni

Subjects
0106 biological sciences, 0301 basic medicine, leaf evolution, Arabidopsis, Plant Biology, 01 natural sciences, Gene Expression Regulation, Plant, Arabidopsis thaliana, Protein Isoforms, Biology (General), General Neuroscience, food and beverages, Gene Expression Regulation, Developmental, General Medicine, Biological Evolution, Genomics and Evolutionary Biology, Shoot, Seeds, Medicine, Plant Shoots, leaf development, Signal Transduction, Research Article, Plant stem cell, QH301-705.5, Science, Meristem, Plant Development, Biology, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Botany, Primordium, Homeodomain Proteins, General Immunology and Microbiology, Arabidopsis Proteins, fungi, 15. Life on land, biology.organism_classification, Sympodial, Plant Leaves, 030104 developmental biology, A. thaliana, Homeobox, Transcriptome, 010606 plant biology & botany, Transcription Factors
Abstract

Leaves are flat determinate organs derived from indeterminate shoot apical meristems. The presence of a specific leaf meristem is debated, as anatomical features typical of meristems are not present in leaves. Here we demonstrate that multiple NGATHA (NGA) and CINCINNATA-class-TCP (CIN-TCP) transcription factors act redundantly, shortly after leaf initiation, to gradually restrict the activity of a leaf meristem in Arabidopsis thaliana to marginal and basal domains, and that their absence confers persistent marginal growth to leaves, cotyledons and floral organs. Following primordia initiation, the restriction of the broadly acting leaf meristem to the margins is mediated by the juxtaposition of adaxial and abaxial domains and maintained by WOX homeobox transcription factors, whereas other marginal elaboration genes are dispensable for its maintenance. This genetic framework parallels the morphogenetic program of shoot apical meristems and may represent a relic of an ancestral shoot system from which seed plant leaves evolved. DOI: http://dx.doi.org/10.7554/eLife.15023.001

Published
2016

22. A novel mutation inKNOPFuncovers the role of α-glucosidase I during post-embryonic development inArabidopsis thaliana

Author

Chihiro Furumizu and Yoshibumi Komeda

Subjects
KNOPF/GLUCOSIDASE 1, Untranslated region, α-Glucosidase I, Arabidopsis thaliana, Cell, Epidermal development, Arabidopsis, Biophysics, medicine.disease_cause, Plant Roots, Biochemistry, Plant Epidermis, N-glycan processing, Polysaccharides, Structural Biology, Genetics, medicine, Allele, Cell Shape, Molecular Biology, Alleles, Body Patterning, Mutation, biology, alpha-Glucosidases, Cell Biology, biology.organism_classification, Multicellular organism, medicine.anatomical_structure
Abstract

N-glycosylation is a common protein modification. Joining of polypeptide and carbohydrate elements into hybrid molecules provides an opportunity to fine-tune protein properties. However, the role of N-glycosylation on the development of multicellular organisms remains elusive. Here we report a hypomorphic allele of KNOPF/GLUCOSIDASE 1, which allows us to describe the effects of impaired α-glucosidase I on post-embryonic development of plants for the first time. This knf-101 mutation alters cell shape but does not affect cell arrangements, except for the patterning of specialized epidermal cells, delineating the significance of N-glycan processing during epidermal development in Arabidopsis.

Published
2008

23. Antagonistic roles for KNOX1 and KNOX2 genes in patterning the land plant body plan following an ancient gene duplication

Author

Keiko Sakakibara, Chihiro Furumizu, John P. Alvarez, and John L. Bowman

Subjects
Cancer Research, lcsh:QH426-470, Arabidopsis, Haploidy, Evolution, Molecular, Gene interaction, Gene Expression Regulation, Plant, Gene Duplication, Gene duplication, Genetics, Arabidopsis thaliana, Molecular Biology, Gene, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Plant Proteins, Homeodomain Proteins, Plant evolution, Life Cycle Stages, biology, fungi, food and beverages, biology.organism_classification, Diploidy, Plant Leaves, lcsh:Genetics, Phenotype, Cardamine, Homeobox, Neofunctionalization, Research Article
Abstract

Neofunctionalization following gene duplication is thought to be one of the key drivers in generating evolutionary novelty. A gene duplication in a common ancestor of land plants produced two classes of KNOTTED-like TALE homeobox genes, class I (KNOX1) and class II (KNOX2). KNOX1 genes are linked to tissue proliferation and maintenance of meristematic potentials of flowering plant and moss sporophytes, and modulation of KNOX1 activity is implicated in contributing to leaf shape diversity of flowering plants. While KNOX2 function has been shown to repress the gametophytic (haploid) developmental program during moss sporophyte (diploid) development, little is known about KNOX2 function in flowering plants, hindering syntheses regarding the relationship between two classes of KNOX genes in the context of land plant evolution. Arabidopsis plants harboring loss-of-function KNOX2 alleles exhibit impaired differentiation of all aerial organs and have highly complex leaves, phenocopying gain-of-function KNOX1 alleles. Conversely, gain-of-function KNOX2 alleles in conjunction with a presumptive heterodimeric BELL TALE homeobox partner suppressed SAM activity in Arabidopsis and reduced leaf complexity in the Arabidopsis relative Cardamine hirsuta, reminiscent of loss-of-function KNOX1 alleles. Little evidence was found indicative of epistasis or mutual repression between KNOX1 and KNOX2 genes. KNOX proteins heterodimerize with BELL TALE homeobox proteins to form functional complexes, and contrary to earlier reports based on in vitro and heterologous expression, we find high selectivity between KNOX and BELL partners in vivo. Thus, KNOX2 genes confer opposing activities rather than redundant roles with KNOX1 genes, and together they act to direct the development of all above-ground organs of the Arabidopsis sporophyte. We infer that following the KNOX1/KNOX2 gene duplication in an ancestor of land plants, neofunctionalization led to evolution of antagonistic biochemical activity thereby facilitating the evolution of more complex sporophyte transcriptional networks, providing plasticity for the morphological evolution of land plant body plans., Author Summary Eukaryotes alternate between haploid (1n) and diploid (2n) stages during their life cycles, and often seen are remarkable differences in morphology and physiology between them. Land plants are multicellular in both generations, in contrast to their presumed ancestral green algae that develop multicellularity only in the haploid stage. TALE class homeodomain transcriptional factors play a key role in the activation of diploid development in diverse lineages of eukaryotes. A gene duplication event within this family in an ancestor of land plants had profound implications for land plant evolution. We show that the two subclasses resulting from the gene duplication event act to pattern, in a complementary manner, most above ground organs of the diploid stage of the flowering plant Arabidopsis. Their opposing activities sculpt the shape of leaves from entire to pinnate and control the architecture of the plant body, and thus providing plasticity for evolutionary tinkering. These results form a foundation for understanding how these genes have been co-opted from an ancestral role of regulating diploid gene expression in a zygote to directing sporophyte land plant body architecture and provide insight into the evolution of various forms of life cycles.

Published
2015

24. Characterization of EMU, the Arabidopsis homolog of the yeast THO complex member HPR1

Author

Yoshibumi Komeda, Hirokazu Tsukaya, and Chihiro Furumizu

Subjects
Genetics, Saccharomyces cerevisiae Proteins, THO complex, Arabidopsis Proteins, RNA Splicing, Mutant, fungi, Arabidopsis, RNA, Nuclear Proteins, Receptors, Cell Surface, Saccharomyces cerevisiae, Biology, Protein Serine-Threonine Kinases, biology.organism_classification, Article, Messenger RNP, RNA splicing, Gene expression, RNA, Messenger, Molecular Biology, Gene
Abstract

Diverse and precise control is essential for eukaryotic gene expression. This is accomplished through the recruitment of a myriad of proteins to a nascent messenger RNA (mRNA) to mediate modifications, such as capping, splicing, 3′-end processing, and export. Despite being important for every cell, however, the mechanism by which the formation of diverse messenger ribonucleoprotein (mRNP) particles contributes to maintaining intricate systems in the multicellular organism remains incompletely defined. We identified and characterized a mutant gene named erecta mRNA under-expressed (emu) that leads to the defective mRNA accumulation of ERECTA, a developmental regulator in the model plant Arabidopsis thaliana. EMU encodes a protein homologous to a component of the THO complex that is required for the generation of functional mRNPs. Further analysis suggested that EMU is genetically associated with SERRATE, HYPONASTIC LEAVES1, and ARGONAUTE1, which are required for proper RNA maturation or action. Furthermore, mutations in another THO-related gene led to embryonic lethality. These findings support the presence and importance of the THO-related complex in plants as well as yeast and vertebrates.

Published
2010

25. The Arabidopsis OBERON1 and OBERON2 genes encode plant homeodomain finger proteins and are required for apical meristem maintenance

Author

Yoshibumi Komeda, Satoshi Tabata, Ryusuke Yokoyama, Shusei Sato, Tomohiko Kato, Mitsuhiro Suzuki, Tetsuya Kurata, Chihiro Furumizu, and Shunsuke Saiga

Subjects
Plant stem cell, Cellular differentiation, Mutant, Meristem, Molecular Sequence Data, Arabidopsis, Biology, Plant Roots, Gene Expression Regulation, Plant, Amino Acid Sequence, Molecular Biology, Genetics, Homeodomain Proteins, Arabidopsis Proteins, Stem Cells, fungi, food and beverages, Plant cell, biology.organism_classification, ABC model of flower development, PHD finger, Mutation, Developmental Biology, Signal Transduction
Abstract

Maintenance of the stem cell population located at the apical meristems is essential for repetitive organ initiation during the development of higher plants. Here, we have characterized the roles of OBERON1 ( OBE1 ) and its paralog OBERON2 ( OBE2 ), which encode plant homeodomain finger proteins, in the maintenance and/or establishment of the meristems in Arabidopsis . Although the obe1 and obe2 single mutants were indistinguishable from wild-type plants, the obe1 obe2 double mutant displayed premature termination of the shoot meristem, suggesting that OBE1 and OBE2 function redundantly. Further analyses revealed that OBE1 and OBE2 allow the plant cells to acquire meristematic activity via the WUSCHEL - CLAVATA pathway, which is required for the maintenance of the stem cell population, and they function parallel to the SHOOT MERISTEMLESS gene, which is required for preventing cell differentiation in the shoot meristem. In addition, obe1 obe2 mutants failed to establish the root apical meristem, lacking both the initial cells and the quiescent center. In situ hybridization revealed that expression of PLETHORA and SCARECROW , which are required for stem cell specification and maintenance in the root meristem, was lost from obe1 obe2 mutant embryos. Taken together, these data suggest that the OBE1 and OBE2 genes are functionally redundant and crucial for the maintenance and/or establishment of both the shoot and root meristems.

Published
2008

Catalog

Books, media, physical & digital resources
See catalog results