A big image opens when the thumbnail is clicked.(nies-0391.jpg)
Strain number NIES-391  
Phylum Heterokontophyta  
Class Bacillariophyceae  
Scientific name Fragilaria capucina Desmazières  
Synonym  
Former name  
Common name Pennate diatom  
Locality (Date of collection) Lake Kasumigaura, Ibaraki, Japan (1985-04-25)  
Latitude / Longitude 36.0428477398 / 140.373233439 
Habitat (Isolation source) Freshwater (Lake water)  
History < Sawaguchi, Tomohiro  
Isolator (Date of isolation) Sawaguchi, Tomohiro (1985-04-26)  
Identified by Idei, Masahiko  
State of strain Subculture; Unialgal; Clonal; Non-axenic  
Culture condition
(Preculture condition)
Medium:  CSi  
Temperature:  15 C
Light intensity:  12-15 µmol photons/m2/sec, L/D cycle:  10L:14D
Duration:  1 M  
Gene information 18S rRNA ( LC037435 )  
Cell size (min - max) - 13 μm  
Organization Unicellular 
Characteristics  
Other strain no. Other strain no. : KEB-24  
Remarks  
Movie  
Reference
Yamada, E., Sasai, K., Higa, R., Mizuguchi, H., Fuse Y. 2020 Characterization and dynamic analysis of dissolved proteins in Lake Biwa using two-dimensional electrophoresis. Anal. Sci., 36, 753-759.
Strain(s): 109275391665 
PubMed: 31956160
DOI: 10.2116/analsci.19P450

Mizuguchi, H., Fujii, S., Fujii, S., Higa, R., Ishikawa, K., Hayakawa, K., Okamoto, T., Fuse, Y., Karatani, H., Yamada, E. 2018 Application of SYBR green real-time PCR assay to monitoring of phytoplankton during cultivation and in Lake Biwa. Limnological Study, , 3-12.
Keywords: SYBR Green; real-time PCR; phytoplankton; Lake Biwa; dissolved organic matter
Strain(s): 109275391665 

Mitani, E., Nakayama, F., Matsuwaki, I., Ichi, I., Kawabata, A., Kawachi, M., Kato, M. 2017 Fatty acid composition profiles of 235 strains of three microalgal divisions within the NIES Microbial Culture Collection. Microb. Resour. Syst., 33, 19-29.
Keywords: Cryptophyta; docosahexaenoic acid; eicosapentaenoic acid; fatty acid; Haptophyta; Heterokontophyta; microalgae
Strain(s): 1891415177111522322523323426527427527627727827928028128228429332332433033334434534634734835035337237738839139540740840941341441746146246648753454855355655755855956056258758858959060360562262369569669769869970070170270370470570670770870971071171271371471571674176576676780583799710011002100310041005100610071009101110161017104410451046104713021303132413271330133913401349135313701375137613791383138413851386138713911392139313951398139914001401169917001730181318151816182618271831186218631864186518741963196419651974197519762142214321442145214721482300233123322351236323642365236923702376250625332534253525362537259026332668268926902691269326942696269727072716271727182720272227232725272627292730273127322770277127722773283928402841284228432844285928722878289028993391368936903691 

Fukuda, S., Iwamoto, K., Atsumi, M., Yokoyama, A., Nakayama, T., Ishida, K-I., Inouye, I., Shiraiwa, Y. 2014 Global searches for microalgae and aquatic plants that can eliminate radioactive cesium, iodine and strontium from the radio-polluted aquatic environment: a bioremediation strategy. J. Plant Res., 127, 79-89.
Keywords: Algal phytoremediation; Bioaccumulation; Radiopollution; Radionuclide elimination; Radioactive cesium; The Fukushima 1 Nuclear Power Plant accident
Strain(s): 24367115516020323324632933339140541744048750352953153854855358759767872780584385993199510031012101510171031104410451259132613311377138213881411143514391440144114421458172818261831183318401846186218651956213121442146214721502175217621852268232523412352237724122437285428552856285828592860 
PubMed: 24346654
DOI: 10.1007/s10265-013-0596-9

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