Cyanobacterial blooms in Lake Atitlan, Guatemala

Lake Atitlan, one of the most important lakes not only in Central America but in the whole world, is facing serious problems with increasing water pollution. Over the last several decades, the uncontrolled nutrient input into the lake has lead to high P levels and low N:P ratios, initiating cyanobac...

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Bibliographic Details
Published in:Limnologica 2011-12, Vol.41 (4), p.296-302
Main Authors: Rejmánková, Eliška, Komárek, Jiří, Dix, Margaret, Komárková, Jaroslava, Girón, Nancy
Format: Article
Language:English
Subjects:
chlorophyll
Cyanobacteria
Cyanobacterial bloom
cylindrospermopsin
education
Freshwater
Lake Atitlan
lakes
Lyngbya
Lyngbya hieronymusii
Lyngbya robusta
monitoring
Nitrogen fixation
nitrogenase
Phosphorus
Planktic Lyngbya-species
remote sensing
water pollution
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Summary:Lake Atitlan, one of the most important lakes not only in Central America but in the whole world, is facing serious problems with increasing water pollution. Over the last several decades, the uncontrolled nutrient input into the lake has lead to high P levels and low N:P ratios, initiating cyanobacterial blooms. The first bloom occurred in December of 2008, followed by more extensive bloom in October 2009. The blooms are formed by cyanobacteria from the rare planktic Lyngbya hieronymusii/birgei/robusta complex. Based on the species morphology, the Atitlan population corresponds to L. robusta and this is the first case of reported bloom of this species worldwide. Remote sensing images documented that at the maximum bloom development, 40% of the 137km2 of the lake area were covered by dense patches of Lyngbya, with the chlorophyll a concentration reaching over 100μgL−1. The only toxins detected in the 2009 bloom were trace levels of cylindrospermopsin and saxitoxin with 12 and 58ngg−1, respectively. The nitrogen fixation followed a pattern expected in non-heterocytous cyanobacteria, i.e., the nitrogenase activity was minimal during the day, while during the night the activity reached 2.2nmol C2H4μg Ch a−1h−1. Delta 15N of −0.86‰ was well in the range given for nitrogen fixing organisms. The cell C, N and P content was 36.7%, 5.9% and 0.9%, respectively, resulting in the molar ratio of 105:14.4:1. A well designed and executed lake monitoring program, strict control of nutrient input into the lake, and public education are the necessary prerequisites for potential prevention of even more severe blooms than the one from 2009.
ISSN:0075-9511
1873-5851
DOI:10.1016/j.limno.2010.12.003