Your search keyword '"Girish Beedessee"' showing total 6 results

1. Integrated omics unveil the secondary metabolic landscape of a basal dinoflagellate

Author

Koki Nishitsuji, Shinichi Yamasaki, Noriyuki Satoh, Takaaki Kubota, Eiichi Shoguchi, Kanako Hisata, Girish Beedessee, Ross F. Waller, Asuka Arimoto, Jun'ichi Kobayashi, Beedessee, Girish [0000-0003-4397-7471], and Apollo - University of Cambridge Repository

Subjects

Physiology, Duplication, Metabolite, Iso-Seq, Secondary Metabolism, Plant Science, Computational biology, Genome, General Biochemistry, Genetics and Molecular Biology, chemistry.chemical_compound, Amphidinium, Structural Biology, Harmful algal blooms, RNA Isoforms, Secondary metabolism, lcsh:QH301-705.5, Genome size, Ecology, Evolution, Behavior and Systematics, biology, Alternative splicing, Dinoflagellate, Cell Biology, Polyketide synthases, biology.organism_classification, RNA, Algal, Dinoflagellates, MicroRNAs, lcsh:Biology (General), chemistry, Dinoflagellida, General Agricultural and Biological Sciences, Genome, Protozoan, Function (biology), RNA, Protozoan, Developmental Biology, Biotechnology, Research Article

Abstract

Background Some dinoflagellates cause harmful algal blooms, releasing toxic secondary metabolites, to the detriment of marine ecosystems and human health. Our understanding of dinoflagellate toxin biosynthesis has been hampered by their unusually large genomes. To overcome this challenge, for the first time, we sequenced the genome, microRNAs, and mRNA isoforms of a basal dinoflagellate, Amphidinium gibbosum, and employed an integrated omics approach to understand its secondary metabolite biosynthesis. Results We assembled the ~ 6.4-Gb A. gibbosum genome, and by probing decoded dinoflagellate genomes and transcriptomes, we identified the non-ribosomal peptide synthetase adenylation domain as essential for generation of specialized metabolites. Upon starving the cells of phosphate and nitrogen, we observed pronounced shifts in metabolite biosynthesis, suggestive of post-transcriptional regulation by microRNAs. Using Iso-Seq and RNA-seq data, we found that alternative splicing and polycistronic expression generate different transcripts for secondary metabolism. Conclusions Our genomic findings suggest intricate integration of various metabolic enzymes that function iteratively to synthesize metabolites, providing mechanistic insights into how dinoflagellates synthesize secondary metabolites, depending upon nutrient availability. This study provides insights into toxin production associated with dinoflagellate blooms. The genome of this basal dinoflagellate provides important clues about dinoflagellate evolution and overcomes the large genome size, which has been a challenge previously.

Published

2020

2. A New Dinoflagellate Genome Illuminates a Conserved Gene Cluster Involved in Sunscreen Biosynthesis

Author

Masanobu Kawachi, Noriyuki Satoh, Eiichi Shoguchi, Ipputa Tada, Kanako Hisata, Haruhi Narisoko, Chuya Shinzato, and Girish Beedessee

Subjects

AcademicSubjects/SCI01140, 0106 biological sciences, Ultraviolet Rays, Lineage (evolution), 010603 evolutionary biology, 01 natural sciences, Genome, 03 medical and health sciences, Symbiodinium, Symbiodiniaceae, Gene cluster, Genetics, MAAs, Amino Acids, Gene, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, 0303 health sciences, Phylogenetic tree, biology, AcademicSubjects/SCI01130, Dinoflagellate, biology.organism_classification, GMC oxidoreductase, Biosynthetic Pathways, Genome Report, Genes, Durusdinium trenchii, Dinoflagellida, WGS, GC-content

Abstract

Photosynthetic dinoflagellates of the Family Symbiodiniaceae live symbiotically with many organisms that inhabit coral reefs and are currently classified into fifteen groups, including seven genera. Draft genomes from four genera, Symbiodinium, Breviolum, Fugacium, and Cladocopium, which have been isolated from corals, have been reported. However, no genome is available from the genus Durusdinium, which occupies an intermediate phylogenetic position in the Family Symbiodiniaceae and is well known for thermal tolerance (resistance to bleaching). We sequenced, assembled, and annotated the genome of Durusdinium trenchii, isolated from the coral, Favia speciosa, in Okinawa, Japan. Assembled short reads amounted to 670 Mb with ∼47% GC content. This GC content was intermediate among taxa belonging to the Symbiodiniaceae. Approximately 30,000 protein-coding genes were predicted in the D. trenchii genome, fewer than in other genomes from the Symbiodiniaceae. However, annotations revealed that the D. trenchii genome encodes a cluster of genes for synthesis of mycosporine-like amino acids, which absorb UV radiation. Interestingly, a neighboring gene in the cluster encodes a glucose–methanol–choline oxidoreductase with a flavin adenine dinucleotide domain that is also found in Symbiodinium tridacnidorum. This conservation seems to partially clarify an ancestral genomic structure in the Symbiodiniaceae and its loss in late-branching lineages, including Breviolum and Cladocopium, after splitting from the Durusdinium lineage. Our analysis suggests that approximately half of the taxa in the Symbiodiniaceae may maintain the ability to synthesize mycosporine-like amino acids. Thus, this work provides a significant genomic resource for understanding the genomic diversity of Symbiodiniaceae in corals.

Published

2020

3. Comparative genomics-first approach to understand diversification of secondary metabolite biosynthetic pathways in symbiotic dinoflagellates

Author

Michael C. Roy, Eiichi Shoguchi, Nori Satoh, Girish Beedessee, Kanako Hisata, and Van Dolah Fm

Subjects

Comparative genomics, Polyketide, Symbiodinium, biology, Evolutionary biology, Polyketide synthase, biology.protein, Gene family, Genomics, Secondary metabolism, biology.organism_classification, Genome

Abstract

Symbiotic dinoflagellates of the genus Symbiodinium are photosynthetic and unicellular. They possess smaller nuclear genomes than other dinoflagellates and produce structurally specialized, biologically active, secondary metabolites. Polyketide biosynthetic genes of toxic dinoflagellates have been studied extensively using transcriptomic analyses; however, a comparative genomic approach to understand secondary metabolism has been hampered by their large genome sizes. Here, we use a combined genomic and metabolomics approach to investigate the structure and diversification of secondary metabolite genes to understand how chemical diversity arises in three decoded Symbiodinium genomes (A3, B1 and C). Our analyses identify 71 polyketide synthase and 41 non-ribosomal peptide synthetase genes from two newly decoded genomes of clades A3 and C. Additionally, phylogenetic analyses indicate that almost all of the gene families are derived from lineage-specific gene duplications in Symbiodinium clades, suggesting divergence for environmental adaptation. Few metabolic pathways are conserved among the three clades and we detect metabolic similarity only in the recently diverged clades, B1 and C. We establish that secondary metabolism protein architecture guides substrate specificity and that gene duplication and domain shuffling have resulted in diversification of secondary metabolism genes.

Published

2018

4. Two divergent Symbiodinium genomes reveal conservation of a gene cluster for sunscreen biosynthesis and recently lost genes

Author

Takeshi Kawashima, Eiichi Shoguchi, Girish Beedessee, Manabu Fujie, Noriyuki Satoh, Michio Hidaka, Ipputa Tada, Nana Arakaki, Masanobu Kawachi, Michael C. Roy, Takeshi Takeuchi, Kanako Hisata, Chuya Shinzato, and Ryo Koyanagi

Subjects

0106 biological sciences, 0301 basic medicine, Repetitive Sequences, Amino Acid, Nuclear gene, lcsh:QH426-470, lcsh:Biotechnology, Mycosporine-like amino acids, 010603 evolutionary biology, 01 natural sciences, Genome, Evolution, Molecular, 03 medical and health sciences, Symbiodinium, Phylogenetics, lcsh:TP248.13-248.65, Gene cluster, Genetics, Gene family, Amino Acids, Clade, Symbiosis, Gene, Phylogeny, biology, Evolutionary genomics, biology.organism_classification, Cyclohexanols, Dinoflagellates, lcsh:Genetics, 030104 developmental biology, Genes, Multigene Family, Dinoflagellida, Gene Deletion, Biotechnology, Research Article

Abstract

Background The marine dinoflagellate, Symbiodinium, is a well-known photosynthetic partner for coral and other diverse, non-photosynthetic hosts in subtropical and tropical shallows, where it comprises an essential component of marine ecosystems. Using molecular phylogenetics, the genus Symbiodinium has been classified into nine major clades, A-I, and one of the reported differences among phenotypes is their capacity to synthesize mycosporine-like amino acids (MAAs), which absorb UV radiation. However, the genetic basis for this difference in synthetic capacity is unknown. To understand genetics underlying Symbiodinium diversity, we report two draft genomes, one from clade A, presumed to have been the earliest branching clade, and the other from clade C, in the terminal branch. Results The nuclear genome of Symbiodinium clade A (SymA) has more gene families than that of clade C, with larger numbers of organelle-related genes, including mitochondrial transcription terminal factor (mTERF) and Rubisco. While clade C (SymC) has fewer gene families, it displays specific expansions of repeat domain-containing genes, such as leucine-rich repeats (LRRs) and retrovirus-related dUTPases. Interestingly, the SymA genome encodes a gene cluster for MAA biosynthesis, potentially transferred from an endosymbiotic red alga (probably of bacterial origin), while SymC has completely lost these genes. Conclusions Our analysis demonstrates that SymC appears to have evolved by losing gene families, such as the MAA biosynthesis gene cluster. In contrast to the conservation of genes related to photosynthetic ability, the terminal clade has suffered more gene family losses than other clades, suggesting a possible adaptation to symbiosis. Overall, this study implies that Symbiodinium ecology drives acquisition and loss of gene families. Electronic supplementary material The online version of this article (10.1186/s12864-018-4857-9) contains supplementary material, which is available to authorized users.

Published

2018

5. Diversified secondary metabolite biosynthesis gene repertoire revealed in symbiotic dinoflagellates

Author

Eiichi Shoguchi, Kanako Hisata, Frances M. Van Dolah, Girish Beedessee, Noriyuki Satoh, and Michael C. Roy

Subjects

0301 basic medicine, Secondary Metabolism, lcsh:Medicine, Genome, Article, Evolution, Molecular, 03 medical and health sciences, Symbiodinium, 0302 clinical medicine, Phylogenetics, Polyketide synthase, Gene duplication, Gene family, Animals, Peptide Synthases, Secondary metabolism, Symbiosis, lcsh:Science, Gene, Phylogeny, Multidisciplinary, biology, lcsh:R, biology.organism_classification, Anthozoa, Biological Evolution, 030104 developmental biology, Evolutionary biology, Polyketides, biology.protein, Dinoflagellida, lcsh:Q, Polyketide Synthases, 030217 neurology & neurosurgery

Abstract

Symbiodiniaceae dinoflagellates possess smaller nuclear genomes than other dinoflagellates and produce structurally specialized, biologically active, secondary metabolites. Till date, little is known about the evolution of secondary metabolism in dinoflagellates as comparative genomic approaches have been hampered by their large genome sizes. Here, we overcome this challenge by combining genomic and metabolomics approaches to investigate how chemical diversity arises in three decoded Symbiodiniaceae genomes (clades A3, B1 and C). Our analyses identify extensive diversification of polyketide synthase and non-ribosomal peptide synthetase genes from two newly decoded genomes of Symbiodinium tridacnidorum (A3) and Cladocopium sp. (C). Phylogenetic analyses indicate that almost all the gene families are derived from lineage-specific gene duplications in all three clades, suggesting divergence for environmental adaptation. Few metabolic pathways are conserved among the three clades and we detect metabolic similarity only in the recently diverged clades, B1 and C. We establish that secondary metabolism protein architecture guides substrate specificity and that gene duplication and domain shuffling have resulted in diversification of secondary metabolism genes.

Published

2019

6. Multifunctional polyketide synthase genes identified by genomic survey of the symbiotic dinoflagellate, Symbiodinium minutum

Author

Noriyuki Satoh, Kanako Hisata, Michael C. Roy, Eiichi Shoguchi, and Girish Beedessee

Subjects

Nuclear gene, Symbiodinium minutum, Zooxanthellamide D, Genome, Polyketide, Genome-wide survey, Polyketide synthase, Botany, polycyclic compounds, Genetics, Gene, biology, NRPS, Dinoflagellate, Horizontal gene transfer, biology.organism_classification, Bacterial PKS, Dinoflagellates, Spliced-leader trans-splicing, Protein Structure, Tertiary, Acyl carrier protein, Polyketides, biology.protein, Dinoflagellida, Polyketide Synthases, Gene diversification, Research Article, Biotechnology

Abstract

Background Dinoflagellates are unicellular marine and freshwater eukaryotes. They possess large nuclear genomes (1.5–245 gigabases) and produce structurally unique and biologically active polyketide secondary metabolites. Although polyketide biosynthesis is well studied in terrestrial and freshwater organisms, only recently have dinoflagellate polyketides been investigated. Transcriptomic analyses have characterized dinoflagellate polyketide synthase genes having single domains. The Genus Symbiodinium, with a comparatively small genome, is a group of major coral symbionts, and the S. minutum nuclear genome has been decoded. Results The present survey investigated the assembled S. minutum genome and identified 25 candidate polyketide synthase (PKS) genes that encode proteins with mono- and multifunctional domains. Predicted proteins retain functionally important amino acids in the catalytic ketosynthase (KS) domain. Molecular phylogenetic analyses of KS domains form a clade in which S. minutum domains cluster within the protist Type I PKS clade with those of other dinoflagellates and other eukaryotes. Single-domain PKS genes are likely expanded in dinoflagellate lineage. Two PKS genes of bacterial origin are found in the S. minutum genome. Interestingly, the largest enzyme is likely expressed as a hybrid non-ribosomal peptide synthetase-polyketide synthase (NRPS-PKS) assembly of 10,601 amino acids, containing NRPS and PKS modules and a thioesterase (TE) domain. We also found intron-rich genes with the minimal set of catalytic domains needed to produce polyketides. Ketosynthase (KS), acyltransferase (AT), and acyl carrier protein (ACP) along with other optional domains are present. Mapping of transcripts to the genome with the dinoflagellate-specific spliced leader sequence, supports expression of multifunctional PKS genes. Metabolite profiling of cultured S. minutum confirmed production of zooxanthellamide D, a polyhydroxy amide polyketide and other unknown polyketide secondary metabolites. Conclusion This genomic survey demonstrates that S. minutum contains genes with the minimal set of catalytic domains needed to produce polyketides and provides evidence of the modular nature of Type I PKS, unlike monofunctional Type I PKS from other dinoflagellates. In addition, our study suggests that diversification of dinoflagellate PKS genes comprises dinoflagellate-specific PKS genes with single domains, multifunctional PKS genes with KS domains orthologous to those of other protists, and PKS genes of bacterial origin. Electronic supplementary material The online version of this article (doi:10.1186/s12864-015-2195-8) contains supplementary material, which is available to authorized users.