taxonID	type	format	identifier	references	title	description	created	creator	contributor	publisher	audience	source	license	rightsHolder	datasetID
03A52852FF96FFDFFF00F9B0CFC1A9CF.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138772/files/figure.png	https://doi.org/10.5281/zenodo.13138772	Fig. 1. Microphotographs of Sphaerospermopsis reniformis from the strain FBCC-A194. (A) Raw sample, (B) Akinetes (a) from both sides adjacent to heterocytes(h), (C, D) Mucilaginous sheaths, (E-I) Heterocytes and morphologies of trichomes. Scale bars=(A, C, D) 50μm, (B) 20μm, (E-I) 10 μm.	Fig. 1. Microphotographs of Sphaerospermopsis reniformis from the strain FBCC-A194. (A) Raw sample, (B) Akinetes (a) from both sides adjacent to heterocytes(h), (C, D) Mucilaginous sheaths, (E-I) Heterocytes and morphologies of trichomes. Scale bars=(A, C, D) 50μm, (B) 20μm, (E-I) 10 μm.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF91FFDDFC87F934CEE0AA9B.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138774/files/figure.png	https://doi.org/10.5281/zenodo.13138774	Fig. 2. Microphotographs of Pelatocladus maniniholoensis from the strain FBCC-A1476. (A-C) Various branching patterns of trichomes, (D, E) Intercalary (ih), lateral (lh), and terminal (th) heterocytes, (F) Hormogonia sheath (sh) branched from the main axis, (G) Hormogonia. Scale bars=(A) 20μm, (B-G) 10 μm.	Fig. 2. Microphotographs of Pelatocladus maniniholoensis from the strain FBCC-A1476. (A-C) Various branching patterns of trichomes, (D, E) Intercalary (ih), lateral (lh), and terminal (th) heterocytes, (F) Hormogonia sheath (sh) branched from the main axis, (G) Hormogonia. Scale bars=(A) 20μm, (B-G) 10 μm.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF93FFDCFF3EFA1DCC70AAE2.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138776/files/figure.png	https://doi.org/10.5281/zenodo.13138776	Fig. 3. Microphotographs of Tolypothrix carrinoi from the strains FBCC-A206, FBCC-A207, and FBCC-A208. (A-D) False branching, (E, F) Heterocytes (h), (G, H) Morphologies of trichomes, (I) Morphology of sheath. Scale bars=10μm.	Fig. 3. Microphotographs of Tolypothrix carrinoi from the strains FBCC-A206, FBCC-A207, and FBCC-A208. (A-D) False branching, (E, F) Heterocytes (h), (G, H) Morphologies of trichomes, (I) Morphology of sheath. Scale bars=10μm.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF92FFDCFF00FA25CDAAA838.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138778/files/figure.png	https://doi.org/10.5281/zenodo.13138778	Fig. 4. Microphotographs of Myxacorys chilensis from the strains FBCC-A216 and FBCC-A220. (A) Arrangement of filament in the colony, (B, C) False branching, (D, E) Firm (fs) or mucilaginous (ms) sheaths, (F) Hormogonia and slime caps (sc), (G) Necridic cells (nc). Scale bars=10μm.	Fig. 4. Microphotographs of Myxacorys chilensis from the strains FBCC-A216 and FBCC-A220. (A) Arrangement of filament in the colony, (B, C) False branching, (D, E) Firm (fs) or mucilaginous (ms) sheaths, (F) Hormogonia and slime caps (sc), (G) Necridic cells (nc). Scale bars=10μm.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF92FFD0FCE9F8FECECEA9AF.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138780/files/figure.png	https://doi.org/10.5281/zenodo.13138780	Fig. 5. Microphotographs of Tildeniella torsiva from the strain FBCC-A1474. (A) Arrangement of filament in the colony, (B) Curved terminal cells, (C) Apical cell, (D, E) Sheaths(sh), (F, G) False branching, (H-J) Morphologies of trichomes, (K) Diversity of cells morphology. Scale bars=(A) 20μm, (B-K) 10μm.	Fig. 5. Microphotographs of Tildeniella torsiva from the strain FBCC-A1474. (A) Arrangement of filament in the colony, (B) Curved terminal cells, (C) Apical cell, (D, E) Sheaths(sh), (F, G) False branching, (H-J) Morphologies of trichomes, (K) Diversity of cells morphology. Scale bars=(A) 20μm, (B-K) 10μm.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF92FFD0FCE9F8FECECEA9AF.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138782/files/figure.png	https://doi.org/10.5281/zenodo.13138782	Fig. 6. Maximum-Likelihood (ML) phylogenetic tree based on 16S rRNA gene sequences of Sphaerospermopsis reniformis, Pelatocladus maniniholoensis, Tolypothrix carrinoi and other cyanobacterial strains. 16S rRNA gene sequences of genera (Gloeobacter violaceus PCC 7421, Synechococcus elongatus PCC 6301) were included as the outgroups.Additionally, the probability of Bayesian analysis was incorporated into the ML tree to support the strength of each branch. The first and second numbers at the nodes display the bootstrap proportions (>50%) in ML and posterior probabilities(>0.50) in Bayesian analysis, respectively.The branch lengths are proportional to the scale given.	Fig. 6. Maximum-Likelihood (ML) phylogenetic tree based on 16S rRNA gene sequences of Sphaerospermopsis reniformis, Pelatocladus maniniholoensis, Tolypothrix carrinoi and other cyanobacterial strains. 16S rRNA gene sequences of genera (Gloeobacter violaceus PCC 7421, Synechococcus elongatus PCC 6301) were included as the outgroups.Additionally, the probability of Bayesian analysis was incorporated into the ML tree to support the strength of each branch. The first and second numbers at the nodes display the bootstrap proportions (>50%) in ML and posterior probabilities(>0.50) in Bayesian analysis, respectively.The branch lengths are proportional to the scale given.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
03A52852FF92FFD0FCE9F8FECECEA9AF.taxon	http://purl.org/dc/dcmitype/StillImage	image/png	https://zenodo.org/record/13138784/files/figure.png	https://doi.org/10.5281/zenodo.13138784	Fig. 7. Maximum-Likelihood (ML) phylogenetic tree based on 16S rRNA gene sequences of Myxacorys chilensis, Tildeniella torsiva and other cyanobacterial strains. 16S rRNA gene sequences of genera (Gloeobacter violaceus PCC 7421, Pseudanabaena catenata PCC 7408) were included as the outgroups.Additionally, the probability of Bayesian analysis was incorporated into the ML tree to support the strength of each branch. The first and second numbers at the nodes display the bootstrap proportions (>50%) in ML and posterior probabilities (>0.50) in Bayesian analysis, respectively. The branch lengths are proportional to the scale given.	Fig. 7. Maximum-Likelihood (ML) phylogenetic tree based on 16S rRNA gene sequences of Myxacorys chilensis, Tildeniella torsiva and other cyanobacterial strains. 16S rRNA gene sequences of genera (Gloeobacter violaceus PCC 7421, Pseudanabaena catenata PCC 7408) were included as the outgroups.Additionally, the probability of Bayesian analysis was incorporated into the ML tree to support the strength of each branch. The first and second numbers at the nodes display the bootstrap proportions (>50%) in ML and posterior probabilities (>0.50) in Bayesian analysis, respectively. The branch lengths are proportional to the scale given.	2022-12-31	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min		Zenodo	biologists	Kim, So-Won;Lee, Nam-Ju;Kim, Do-Hyun;Song, Ji-Ho;Lee, Hye-Ryeung Wang and Ok-Min			
