| SAG Strain Number: | 211-12 |
| TAXONOMY |
| Genus: | Chlorella |
| Species: | vulgaris |
| Taxonomic position: | Chlorophyta - Trebouxiophyceae |
| Authority: | Beijerinck |
| Variety: | |
| Formerly called: | authentic strain of Chlorella vulgaris Beijerinck var. viridis Chodat |
| Authentic: | no |
| Division: | Chlorophyta |
| Class: | Trebouxiophyceae |
| ORIGIN |
| General habitat: | freshwater |
| Climatic zone: | |
| Continent: | |
| Country: | |
| Locality: | |
| Lat. / Long. (Precision): | |
| Year: | before 1934 |
| Isolated by: | R. Chodat |
| Strain number by isolator: | Geneva strain 45; Myer No. 2 |
| Deposition by: | E.G. Pringsheim (SAG) |
| Deposition date: | 1954 |
| CULTURE INFORMATION |
| Culture medium: | ESP Ag |
| Axenic: | axenic |
| Strain relatives: | CCAP 211/12; UTEX 30; ATCC 16487 |
| Agitation resistance: | yes |
| Special properties: | NO known Nagoya Protocol restrictions for this strain |
| |
| PUBLICATIONS |
| Publication: | Oliver A. et al. (2024) Acclimation dynamics of Chlorella vulgaris to sudden light change. Algal Res. 82:103661 |
| Publication: | Yeh Y.-C. et al. (2023) A novel model extended from the Bouguer-Lambert-Beer law can describe the nonlinear absorbance of potassium dichromate solutions and microalgae suspensions. Front. Bioeng. Biotechnol. 11:1116735 |
| Publication: | Haberkorn I. et al. (2020) Characterization of Chlorella vulgaris (Trebouxiophyceae) associated microbial communities. J. Phycol. 56:1308-1322 |
| Publication: | Helisch H. et al. (2020) High density long-term cultivation of Chlorella vulgaris SAG 211-12 in a novel microgravity-capable membrane raceway photobioreactor for future bioregenerative life support in SPACE. Life Sciences in Space Research 24:91-107 |
| Publication: | Papachristou I. et al. (2020) Evaluation of pulsed electric fields effect on the microalgae cell mechanical stability through high pressure homogenization. Algal Res. 47:101847 |
| Publication: | Woortman D.V. et al. (2020) Microalgae a Superior Source of Folates: Quantification of Folates in Halophile Microalgae by Stable Isotope Dilution Assay. Front. Bioeng. Biotechnol. 7:481 |
| Publication: | Darienko T. et al. (2019) Are there any true marine Chlorella species? Molecular phylogenetic assessment and ecology of marine Chlorella-like organisms, including a description of Droopiella gen. nov. Systematics and Biodiversity 17 (8):811-829 |
| Publication: | Guo B. et al. (2019) Hydrothermal liquefaction of residual microalgae biomass after pulsed electric field-assisted valuables extraction. Algal Res. 43:101650 |
| Publication: | Zocher K. et al. (2019) Profiling microalgal protein extraction by microwave burst heating in comparison to spark plasma exposures. Algal Res. 39:101416 |
| Publication: | Levasseur W. et al. (2018) Impact of seconds to minutes photoperiods on Chlorella vulgaris growth rate and chlorophyll a and b content. Algal Res. 36:10-16 |
| Publication: | Melo M. et al. (2018) Chlorella vulgaris (SAG 211-12) biofilm formation capacity and proposal of a rotating flat plate photobioreactor for more sustainable biomass production. J. Appl. Phycol. 30:887-899 |
| Publication: | Zocher K. et al. (2016) Comparison of Extraction of Valuable Compounds from Microalgae by Atmospheric Pressure Plasmas and Pulsed Electric Fields. Plasma Medicine 6 (3-4):273-302 |
| Publication: | Kose A. et al. (2015) Properties of microalgal enzymatic protein hydrolysates: Biochemical composition, protein distribution and FTIR characteristics. Biotechnology Reports 6:137-143 |
| Publication: | Arbib, Z. et al. (2014) Capability of different microalgae species for phytoremediation processes: wastewater tertiary treatment, CO2 bio-fixation and low cost biofuels production. Water Res 49:465-74 |
| Publication: | Münkel R. et al. (2013) Optimization of outdoor cultivation in flat panel airlift reactors for lipid production by Chlorella vulgaris. Biotechnol. Bioeng. 110:2882-2893 |
| Publication: | Degen J. et al. (2001) A novel airlift photobioreactor with baffles for improved light utilization through the flashing light effect. J. Biotechnol. 92 (2):89-94 |
| Publication: | Kessler E. (1976) Comparative physiology, biochemistry, and the taxonomy of Chlorella (Chlorophyceae). Plant Systematics and Evolution 125 (3):129-138 |
| Publication: | Liersch R. (1976) Über das ätherische Öl von Grünalgen. I. Die Öle der Gattung Chlorella (On the essential oil of green algae. I. The oils of the genus Chlorella). Arch. Microbiol. 107:353-356 |
| Publication: | Soeder C.J. et al. (1969) Unterschiedliche Wirkung von Captan auf das Wachstum einiger Stämme yon Chlorella und Scenedesmus. Arch. Mikrobiol. 67 (2):166-172 |
| Publication: | Kessler E. (1967) Physiologische und biochemische Beiträge zur Taxonomie der Gattung Chlorella III. Merkmale von 8 autotrophen Arten. Archiv für Mikrobiologie 55 (4):346-357 |
| Publication: | Chodat, R. (1913) Monographies d'algues en culture pure. Materiaux pour la flore cryptogamique Suisse. Berne. 4:1-266 |
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| SEQUENCE INFORMATION |
| Sequence Accession: | AY591503 Chlorella vulgaris strain SAG 211-12 18S ribosomal RNA gene, partial sequence; internal transcribed spacer 1, 5.8S ribosomal RNA gene, and internal transcribed spacer 2, complete sequence; and 26S ribosomal RNA gene, partial sequence. (765 bp) |
| CRYO |
| Cryopreservation: | good survival |
| TEACHING |
| Recommended for teaching: | no |
