Using absorbance and fluorescence spectra to discriminate microalgae

DAVID F. MILLIE; OSCAR M. E. SCHOFIELD; GARY J. KIRKPATRICK; GEIR JOHNSEN; TERENCE J. EVENS

doi:10.1017/S0967026202003700

Abstract

The utility of absorbance and fluorescence-emission spectra for discriminating among microalgal phylogenetic groups, selected species, and phycobilin- and non-phycobilin-containing algae was examined using laboratory cultures. A similarity index algorithm, in conjunction with fourth-derivative transformation of absorbance spectra, provided discrimination among the chlorophyll [Chl] a/phycobilin (cyanobacteria), Chl a/Chl c/phycobilin (cryptophytes), Chl a/Chl b (chlorophytes, euglenophytes, prasinophytes), Chl a/Chl c/fucoxanthin (diatoms, chrysophytes, raphidophytes) and Chl a/Chl c/peridinin (dinoflagellates) spectral classes, and often between/among closely related phylogenetic groups within a class. Spectra for phylogenetic groups within the Chl a/Chl c/fucoxanthin, Chl a/Chl c/peridinin, Chl a/phycobilins and Chl a/Chl c/phycobilin classes were most distinguishable from spectra for groups within the Chl a/Chl b spectral class. Chrysophytes/diatoms/raphidophytes and dinoflagellates (groups within the comparable spectral classes, Chl a/Chl c/fucoxanthin and Chl a/Chl c/peridinin, respectively) displayed the greatest similarity between/among groups. Spectra for phylogenetic groups within the Chl a/Chl c classes displayed limited similarity with spectra for groups within the Chl/phycobilin classes. Among the cyanobacteria and chlorophytes surveyed, absorbance spectra of species possessing dissimilar cell morphologies were discriminated, with the greatest range of differentiation occurring among cyanobacteria. Among the cyanobacteria, spectra for selected problematic species were easily discriminated from spectra from each other and from other cyanobacteria. Fluorescence-emission spectra were distinct among spectral classes and the similarity comparisons involving fourth-derivative transformation of spectra discriminated the increasing contribution of distinct cyanobacterial species and between phycobilin- and non-phycobilin-containing species within a hypothetical mixed assemblage. These results were used to elucidate the application for in situ moored instrumentation incorporating such approaches in water quality monitoring programmes, particularly those targeting problematic cyanobacterial blooms.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Creed, E. Kerfoot, J. Mudgal, C. Glenn, S. Schofield, O. Jones, C. Webb, D. Campbell, T. Twardowski, M. Kirkpatrick, G. and Hillier, J. 2003. Automated control of a fleet of Slocum gliders within an operational coastal observatory. p. 726.

Roldán, M. Thomas, F. Castel, S. Quesada, A. and Hernández-Mariné, M. 2004. Noninvasive Pigment Identification in Single Cells from Living Phototrophic Biofilms by Confocal Imaging Spectrofluorometry. Applied and Environmental Microbiology, Vol. 70, Issue. 6, p. 3745.

Schofield, Oscar Bergmann, Trisha Oliver, Mathew J. Irwin, Andrew Kirkpatrick, Gary Bissett, W. Paul Moline, Mark A. and Orrico, Cris 2004. Inversion of spectral absorption in the optically complex coastal waters of the Mid‐Atlantic Bight. Journal of Geophysical Research: Oceans, Vol. 109, Issue. C12,

Glasgow, Howard B Burkholder, JoAnn M Reed, Robert E Lewitus, Alan J and Kleinman, Joseph E 2004. Real-time remote monitoring of water quality: a review of current applications, and advancements in sensor, telemetry, and computing technologies. Journal of Experimental Marine Biology and Ecology, Vol. 300, Issue. 1-2, p. 409.

Moline, Mark A. Blackwell, Shelley M. Chant, Robert Oliver, Matthew J. Bergmann, Trisha Glenn, Scott and Schofield, Oscar M. E. 2004. Episodic physical forcing and the structure of phytoplankton communities in the coastal waters of New Jersey. Journal of Geophysical Research: Oceans, Vol. 109, Issue. C12,

Gregor, J and Maršálek, B 2004. Freshwater phytoplankton quantification by chlorophyll a: a comparative study of in vitro, in vivo and in situ methods. Water Research, Vol. 38, Issue. 3, p. 517.

Evangelista, Valtere Barsanti, Laura Frassanito, Anna Maria Passarelli, Vincenzo and Gualtieri, Paolo 2005. From Cells to Proteins: Imaging Nature across Dimensions. p. 323.

Gaevsky, N. A. Kolmakov, V. I. Anishchenko, O. V. and Gorbaneva, T. B. 2005. Using DCMU-fluorescence method for the identification of dominant phytoplankton groups. Journal of Applied Phycology, Vol. 17, Issue. 6, p. 483.

Gregor, Jakub Geriš, Rodan Maršálek, Blahoslav Heteša, Jiří and Marvan, Petr 2005. In situ Quantification of Phytoplankton in Reservoirs Using a Submersible Spectrofluorometer. Hydrobiologia, Vol. 548, Issue. 1, p. 141.

WOLF, ELKE and SCHÜΒLER, ARTHUR 2005. Phycobiliprotein fluorescence of Nostoc punctiforme changes during the life cycle and chromatic adaptation: characterization by spectral confocal laser scanning microscopy and spectral unmixing. Plant, Cell & Environment, Vol. 28, Issue. 4, p. 480.

Parésys, G. Rigart, C. Rousseau, B. Wong, A.W.M. Fan, F. Barbier, J.-P. and Lavaud, J. 2005. Quantitative and qualitative evaluation of phytoplankton communities by trichromatic chlorophyll fluorescence excitation with special focus on cyanobacteria. Water Research, Vol. 39, Issue. 5, p. 911.

Lokuhewage, Asha Udayamali M. Naiki, Yasuhiro and Toyooka, Satoru 2005. Quantitative Estimation of Phytoplankton Species in Freshwater by Two Step Linear Regression Analysis Using Spectral Absorption Method. Optical Review, Vol. 12, Issue. 5, p. 420.

Evangelista, Valtere Frassanito, Anna Maria Passarelli, Vincenzo Barsanti, Laura and Gualtieri, Paolo 2006. Microspectroscopy of the Photosynthetic Compartment of Algae. Photochemistry and Photobiology, Vol. 82, Issue. 4, p. 1039.

Robbins, I.C. Kirkpatrick, G.J. Blackwell, S.M. Hillier, J. Knight, C.A. and Moline, M.A. 2006. Improved monitoring of HABs using autonomous underwater vehicles (AUV). Harmful Algae, Vol. 5, Issue. 6, p. 749.

Craig, Susanne E. Lohrenz, Steven E. Lee, Zhongping Mahoney, Kevin L. Kirkpatrick, Gary J. Schofield, Oscar M. and Steward, Robert G. 2006. Use of hyperspectral remote sensing reflectance for detection and assessment of the harmful alga, Karenia brevis. Applied Optics, Vol. 45, Issue. 21, p. 5414.

Pérez, Gonzalo Queimaliños, Claudia Balseiro, Esteban and Modenutti, Beatriz 2007. Phytoplankton absorption spectra along the water column in deep North Patagonian Andean lakes (Argentina). Limnologica, Vol. 37, Issue. 1, p. 3.

Barsanti, Laura Evangelista, Valtere Frassanito, Anna Maria Vesentini, Nicoletta Passarelli, Vincenzo and Gualtieri, Paolo 2007. Absorption microspectroscopy, theory and applications in the case of the photosynthetic compartment. Micron, Vol. 38, Issue. 3, p. 197.

Barillé, Laurent Méléder, Vona Combe, Jean-Philippe Launeau, Patrick Rincé, Yves Carrère, Véronique and Morançais, Michèle 2007. Comparative analysis of field and laboratory spectral reflectances of benthic diatoms with a modified Gaussian model approach. Journal of Experimental Marine Biology and Ecology, Vol. 343, Issue. 2, p. 197.

Adler, Nicole E. Schmitt‐Jansen, Mechthild and Altenburger, Rolf 2007. Flow cytometry as a tool to study phytotoxic modes of action. Environmental Toxicology and Chemistry, Vol. 26, Issue. 2, p. 297.

Mohan, Rahul Shukla, Sunil Kumar Anilkumar, N. Sudhakar, M. Prakash, Satya and Ramesh, R. 2009. Relative Microalgal Concentration in Prydz Bay, East Antarctica during Late Austral Summer, 2006. ALGAE, Vol. 24, Issue. 3, p. 139.

Download full list

Article contents

Using absorbance and fluorescence spectra to discriminate microalgae

Abstract

Keywords

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Using absorbance and fluorescence spectra to discriminate microalgae

Abstract

Keywords

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests