References [ 19 ]
Morris GJ, Coulson GE & Leeson EA (1985) Changes in the shape of mitochondria following osmotic stress to the unicellular green alga Chlamydomonas reinhardii. Journal of Cell Science 76: 145-153.
DOI: none
Reynoso GT & de Gamboa BA (1982) Salt tolerance in the freshwater algae Chlamydomonas reinhardtii: Effect of proline and taurine. Comparative Biochemistry and Physiology 73A(1): 95-99.
DOI: none
Pittman JK, Edmond C, Sunderland PA & Bray CM (2009) A cation-regulated and proton gradient-dependent cation transporter from Chlamydomonas reinhardtii has a role in calcium and sodium homeostasis. Journal of Biological Chemistry 284: 525-533.
Maberly SC & Spence DHN (1983) Photosynthetic inorganic carbon use by freshwater plants. Journal of Ecology 71: 705-724.
DOI: none
Clarke KJ & Leeson EA (1985) Plasmalemma structure in freezing tolerant unicellular algae. Protoplasma 129: 120-126.
DOI: 10.1007/BF01279909
Webster RE, Dean AP & Pittman JK (2011) Cadmium exposure and phosphorus limitation increases metal content in the freshwater alga Chlamydomonas reinhardtii. Environmental Science & Technology 45: 7489-7496.
DOI: 10.1021/es200814c
Kebelmann K, Hornung A, Karsten U & Griffiths G (2013) Intermediate pyrolysis and product identification by TGA and Py-GC/MS of green microalgae and their extracted protein and lipid components. Biomass and Bioenergy 49: 38-48.
Morris GJ, Coulson G & Clarke A (1979) The cryopreservation of Chlamydomonas. Cryobiology 16: 401-410.
DOI: none
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.
Taylor NS, Merrifield R, Williams TD, Chipman JK, Lead JR & Viant MR (2015) Molecular toxicity of cerium oxide nanoparticles to the freshwater alga Chlamydomonas reinhardtii is associated with supra-environmental exposure concentrations. Nanotoxicology 10: 32-41.
Costa PM & Fadeel B (2016) Emerging systems biology approaches in nanotoxicology: Towards a mechanism-based understanding of nanomaterial hazard and risk. Toxicology and Applied Pharmacology 299: 101-111.
Larronde-Larretche M & Jin X (2017) Microalgal biomass dewatering using forward osmosis membrane: Influence of microalgae species and carbohydrates composition. Algal Research 23: 12-19.
Bekirogullari M, Fragkopoulos IS, Pittman JK & Theodoropoulos C (2017) Production of lipid-based fuels and chemicals from microalgae: An integrated experimental and model-based optimization study. Algal Research 23: 78-87.
Loera-Quezada MM, Leyva-González MA, Velázquez-Juárez G, Sanchez-Calderón L, Do Nascimento M, López-Arredondo D & Herrera-Estrella L (2016) A novel genetic engineering platform for the effective management of biological contaminants for the production of microalgae. Plant Biotechnology Journal 14: 2066-2076.
DOI: 10.1111/pbi.12564
Bekirogullari M, Pittman JK & Theodoropoulos C (2018) Multi-factor kinetic modelling of microalgal biomass cultivation for optimised lipid production Bioresource Technology -: -.
Tassoni A, Awad N & Griffiths G (2018) Effect of ornithine decarboxylase and norspermidine in modulating cell division in the green alga Chlamydomonas reinhardtii Plant Physiology and Biochemistry 123: 125-131.
Dash A & Banerjee R (2018) In silico optimization of lipid yield utilizing mix-carbon sources for biodiesel production from Chlorella minutissima Energy Conversion and Management 164: 533-542.
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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: Chlorophyceae Order: Chlamydomonadales
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:
EG:JM;
Axenic; maintained by serial subculture;
| Attributes | |
| Authority | Dangeard 1888 |
| Isolator | Smith |
| Collection Site | potato field Amherst, Massachusetts, USA |
| Notes | this strain carries the nit1 and nit2 mutations and cannot grow on nitrate as the sole N source (via www.chlamycollection.org record for 11/32C). |
| Axenicity Status | Axenic |
| Area | North America |
| Country | USA |
| Environment | Soil |
| GMO | No |
| In Scope of Nagoya Protocol | No |
| ABS Note | Collected pre Nagoya Protocol. No known Nagoya Protocol restrictions for this strain. |
| Collection Date | pre. 1961 |
| Original Designation | 137C+ |
| Pathogen | Not pathogenic: Hazard Class 1 |
| Strain Maintenance Sheet | SM_FreshwaterGreens.pdf |
| Toxin Producer | Not Toxic / No Data |
| Type Culture | No |
| Taxonomy WoRMS ID | 608420 |
CCAP 11/32C
Chlamydomonas reinhardtii
- Product Code: CCAP 11/32C
- Availability: See Availability/Lead Times
Related Products
CCAP FAEGJM-C
EG:JM Medium
CONCENTRATED STOCKS
Non-sterile concentrated stocks to make up 5 litres of EG:JM medium (a 1:1 mix of EG and JM media).
CCAP FAEGJM-P
EG:JM Medium
1 LITRE PREMADE
1 litre of sterile, ready to use, EG:JM medium. EG:JM medium is used for culturing freshwater algae