References [ 14 ]
Mohsenpour SF, Richards B & Willoughby N (2012) Spectral conversion of light for enhanced microalgae growth rates and photosynthetic pigment production. Bioresource Technology 125: 75-81.
Osundeko O, Davies H & Pittman JK (2013) Oxidative stress-tolerant microalgae strains are highly efficient for biofuel feedstock production wastewater. Biomass and Bioenergy 56: 284-294.
Mohsenpour SF & Willoughby N (2013) Luminescent photobioreactor design for improved algal growth and photosynthetic pigment production through spectral conversion of light. Bioresource Technology 142: 147-153.
Memon AR, Andresen J, Habib M & Jaffar M (2014) Simulated sugar factory wastewater remediation kinetics using algal-bacterial raceway reactor promoted by Polyacrylate polyalcohol. Bioresource Technology 157: 37-43.
Germond A, Hata H, Fujikawa Y & Nakajima T (2013) The phylogenetic position and phenotypic changes of a Chlorella-like alga during 5-year microcosm culture. European Journal of Phycology 48: 485-496.
Lim DKY, Garg S, Timmins M, Zhang ESB, Thomas-Hall SR, Schuhmann H, Li Y & Schenk PM (2012) Isolation and evaluation of oil-producing microalgae from subtropical coastal and brackish waters. PLoS ONE 7(7): e40751.
Driver T, Bajhaiya AK, Allwood JW, Goodacre R, Pittman JK & Dean AP (2015) Metabolic responses of eukaryotic microalgae to environmental stress limit the ability of FT-IR spectroscopy for species identification. Algal Research 11: 148-155.
Osundeko O, Dean AP, Davies H & Pittman JK (2014) Acclimation of microalgae to wastewater environments involves increased oxidative stress tolerance activity. Plant & Cell Physiology 55: 1848-1857.
DOI: 10.1093/pcp/pcu113
Mohsenpour SF & Willoughby N (2016) Effect of CO2 aeration on cultivation of microalgae in luminescent photobioreactors. Biomass and Bioenergy 85: 168-177.
Li T, Xu J, Gao B, Xiang W, Li A & Zhang C (2016) Morphology, growth, biochemical composition and photosynthetic performance of Chlorella vulgaris (Trebouxiophyceae) under low and high nitrogen supplies. Algal Research 16: 481-491.
Hodac L, Hallmann C, Spitzer K, Elster J, Faßhauer F, Brinkmann N, Lepka D, Diwan V & Friedl T (2016) Widespread green algae Chlorella and Stichococcus exhibit polar-temperate and tropical-temperate biogeography. FEMS Microbiology Ecology 92: fiw122.
Evans L, Hennige SJ, Willoughby N, Adeloye AJ, Skroblin M & Gutierrez T (2017) Effect of organic carbon enrichment on the treatment efficiency of primary settled wastewater by Chlorella vulgaris. Algal Research 24: 368-377.
Ferro L, Gentili FG & Funk C (2018) Isolation and characterization of microalgal strains for biomass production and wastewater reclamation in Northern Sweden Algal Research 32: 44-53.
Ciurli A, Modeo L, Pardossi A & Chiellini C (2021) Multidisciplinary integrated characterization of a native Chlorella-like microalgal strain isolated from a municipal landfill leachate Algal Research 54: 102202.
Sequences [ 1 ]
EMBL/Genbank Links
(Bold text = submission by CCAP staff or collaborators)
(Bold text = submission by CCAP staff or collaborators)
18S-28S
Division/Phylum: Chlorophyta Class: Trebouxiophyceae Order: Chlorellales
Note: for strains where we have DNA barcodes we can be reasonably confident of identity, however for those not yet sequenced we rely on morphology
and the original identification, usually made by the depositor. Although CCAP makes every effort to ensure the correct taxonomic identity of strains, we cannot guarantee
that a strain is correctly identified at the species, genus or class levels. On this basis users are responsible for confirming the identity of the strain(s) they receive
from us on arrival before starting experiments.
For strain taxonomy we generally use AlgaeBase for algae and
Adl et al. (2019) for protists.
Culture media, purity and growth conditions:
Medium:
3N-BBM+V;
Bacteria and fungi present; maintained by serial subculture; contains fungi
| Attributes | |
| Authority | Beyerinck [Beijerinck] 1890 |
| Isolator | Bustard (2000) |
| Collection Site | biofilter for treatment of waste solvent vapour Heriot-Watt University, Edinburgh, UK |
| Climatic Zone | Temperate |
| Notes | solvent-tolerant; original accession sheet has optimal temp range as 18-25 deg C, pH 5.5-6.0, cultivation may be achieved in the presence of 3% v/v solvent (isopropanol/acetone) |
| Axenicity Status | Bacteria and fungi present |
| Area | Europe |
| Country | UK |
| Environment | Freshwater |
| GMO | No |
| In Scope of Nagoya Protocol | No |
| ABS Note | Collected pre Nagoya Protocol. No known Nagoya Protocol restrictions for this strain. |
| Collection Date | c 2000 |
| Original Designation | SDC-1 |
| Pathogen | Not pathogenic: Hazard Class 1 |
| Strain Maintenance Sheet | SM_GeneralFreshwaterGreens.pdf |
| Toxin Producer | Not Toxic / No Data |
| Type Culture | No |
| Taxonomy WoRMS ID | 532029 |
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3N-BBM+V Medium
CONCENTRATED STOCKS
Non-sterile concentrated stocks to make up 5 litres of 3N-BBM+V medium. 3N-BBM+V medium is used for
CCAP FA3N-P
3N-BBM+V Medium
1 LITRE PREMADE
1 litre of sterile, ready to use, 3N-BBM+V medium. 3N-BBM+V medium is used for culturing freshwater