References [ 13 ]
Henderson RK, Parsons SA & Jefferson B (2010) The impact of differing cell and algogenic organic matter (AOM) characteristics on the coagulation and flotation of algae. Water Research 44: 3617-3624.
Vezie C, Benoufella F, Sivonen K, Bertru G & Laplanche A (1996) Detection of toxicity of cyanobacterial strains using Artemia salina and Microtox® assays compared with mouse bioassay results. Phycologia 35 (6S): 198-202.
Hilton J, Rigg E & Jaworski G (1989) In vivo algal fluorescence, spectral change due to light intensity changes and the automatic characterization of algae. Freshwater Biology 21: 375-382.
Henderson RK, Baker A, Parsons SA & Jefferson B (2008) Characterisation of algogenic organic matter extracted from cyanobacteria, green algae and diatoms. Water Research 42: 3435-3445.
Devlin S, Meneely JP, Greer B, Greef C, Lochhead MJ & Elliott CT (2013) Next generation planar waveguide detection of microcystins in freshwater and cyanobacterial extracts, utilising a novel lysis method for portable sample preparation and analysis. Analytica Chimica Acta 769: 108-113.
Devlin S, Meneely JP, Greer B, Campbell K, Vasconcelos V & Elliott CT (2014) Production of a broad specificity antibody for the development and validation of an optical SPR screening method for free and intracellular microcystins and nodularin in cyanobacteria cultures. Talanta 12: 8-15.
Yap RKL, Whittaker M, Diao M, Stuetz RM, Jefferson B, Bulmus V, Peirson WL, Nguyen AV & Henderson RK (2014) Hydrophobically-associating cationic polymers as micro-bubble surface modifiers in dissolved air flotation for cyanobacteria cell separation. Water Research 61: 253-262.
Murphy C, Stack E, Krivelo S, McPartlin DA, Byrne B, Greef C, Lochhead MJ, Husar G, Devlin S, Elliott CT & O'Kennedy RJ (2014) Detection of the cyanobacterial toxin, mycrocystin-LR, using a novel recombinant antibody-based optical-planar waveguide platform. Biosensors and Bioelectronics 67: 708-714.
Whitton R, Le Mével A, Pidou M, Ometto F, Villa R & Jefferson B (2016) Influence of microalgal N and P composition on wastewater nutrient remediation. Water Research 91: 371-378.
Greer B, McNamee SE, Boots B, Cimarelli L, Guillebault D, Helmi K, Marcheggiani S, Panaiotov S, Breitenbach U, Akcaalan R, Medlin LK, Kittler K, Elliott CT & Campbell K (2016) A validated UPLC-MS/MS method for the surveillance of ten aquatic biotoxins in European brackish and freshwater systems. Harmful Algae 55: 31-40.
Goslan EH, Seigle C, Purcell D, Henderson R, Parsons SA, Jefferson B & Judd SJ (2017) Carbonaceous and nitrogenous disinfection by-product formation from algal organic matter. Chemosphere 170: 1-9.
Hanumanth Rao NR, Yap R, Whittaker M, Stuetz RM, Jefferson B, Peirson WL, Granville AM & Henderson RK (2018) The role of algal organic matter in the separation of algae and cyanobacteria using the novel "Posi" - Dissolved air flotation process. Water Research 130: 20-30.
Hanumanth Rao NR, Granville AM, Browne CI, Dagastine RR, Yap R, Jefferson B & Henderson RK (2018) Determining how polymer-bubble interactions impact algal separation using the novel "Posi"-dissolved air flotation process Separation and Purification Technology 201: 139-147.
Sequences [ 1 ]
EMBL/Genbank Links
(Bold text = submission by CCAP staff or collaborators)
(Bold text = submission by CCAP staff or collaborators)
16S
Division/Phylum: Cyanophyta Class: Cyanophyceae Order: Chroococcales
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:
JM;
Bacteria present; maintained by serial subculture and cryopreserved;
| Attributes | |
| Authority | Kützing emend. Elenkin 1924 |
| Isolator | Jaworski (1968) |
| Collection Site | Esthwaite Water, Cumbria, England, UK |
| Notes | unicellular; LC-MS analysis by RGU in 2021 for cylindrospermopsins, microcystins and anatoxins: None Detected. |
| Axenicity Status | Bacteria present |
| Area | Europe |
| Country | UK |
| Environment | Freshwater |
| GMO | No |
| Group | Cyanobacteria |
| Original Designation | FBA L155 |
| Pathogen | Not pathogenic: Hazard Class 1 |
| Strain Maintenance Sheet | SM_FreshwaterCyanobacteria.pdf |
| Toxin Producer | Not Toxic / No Data |
| Type Culture | No |
| Taxonomy WoRMS ID | 146558 |
CCAP 1450/3
Microcystis aeruginosa
- Product Code: CCAP 1450/3
- Availability: See Availability/Lead Times
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CCAP FAJM-P
Jaworski's Medium (JM)
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1 litre of sterile, ready to use, JM medium. Jaworski's Medium is used for culturing freshwater alg