Allelopathic effects of Alexandrium tamarense on other algae: evidence from mixed growth experiments

Urban Tillmann; Per Juel Hansen

doi:10.3354/ame01329

Allelopathic effects of Alexandrium tamarense on other algae: evidence from mixed growth experiments

Urban Tillmann, Per Juel Hansen

56 Citationer (Scopus)

Abstract

Udgivelsesdato: 2009

Originalsprog	Engelsk
Tidsskrift	Aquatic Microbial Ecology
Vol/bind	57
Udgave nummer	1
Sider (fra-til)	101-112
Antal sider	12
ISSN	0948-3055
DOI	https://doi.org/10.3354/ame01329
Status	Udgivet - 2009

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10.3354/ame01329

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@article{f56b2f70dfe911deba73000ea68e967b,

title = "Allelopathic effects of Alexandrium tamarense on other algae: evidence from mixed growth experiments",

abstract = "The effect of 2 strains (Alex2 and Alex5) of the marine red tide dinoflagellate Alexandrium tamarense on 10 other planktonic algal target species common in temperate waters was studied in mixed growth experiments under nutrient-rich conditions. In a comparative approach, the 2 strains of A. tamarense, similar in their cellular paralytic shellfish toxin (PST) content, were selected because of their fundamentally different lytic potencies. The Alex2 strain clearly affected all target algae while the Alex5 strain had no negative effect on the growth of any of the target species during the study period, even though cell concentrations of Alex5 became very high (2 × 104 cells ml-1). As both strains contained comparable amounts of PST, this confirmed previous suggestions that so far unidentified compounds are causing the negative effects on other algae. Sensitivity of the tested algae to Alex2 differed considerably. The growth of some species was affected at very low Alex2 cell concentrations (<102 cells ml-1), while the growth of other algae was not affected until cell concentrations exceeded 103 cells ml-1. While a complete dieoff was the ultimate fate for almost all target species when grown in mixed culture with Alex2, Scrippsiella trochoidea formed temporary cysts, the number of which remained constant during the course of the experiment. The pH in the mixed cultures increased as the cultures grew dense. This had a substantial effect on Alex5 in the mixed cultures, in which Alex5 eventually died off because the target species have a higher tolerance to high pH. pH values did not determine the outcome of the experiments with Alex2 because the adverse effects of Alex2 on the growth of the other algae was evident before pH values became too high. Lytic extracellular compounds, which are produced by the large majority of A. tamarense strains tested so far, clearly have the potential to benefit this dinoflagellate by reducing competitor growth rates.",

author = "Urban Tillmann and Hansen, {Per Juel}",

note = "KEY WORDS: Alexandrium · PST · Paralytic shellfish toxin · Allelopathy · Growth · Algae · pH",

year = "2009",

doi = "10.3354/ame01329",

language = "English",

volume = "57",

pages = "101--112",

journal = "Aquatic Microbial Ecology",

issn = "0948-3055",

publisher = "Inter research",

number = "1",

}

TY - JOUR

T1 - Allelopathic effects of Alexandrium tamarense on other algae: evidence from mixed growth experiments

AU - Tillmann, Urban

AU - Hansen, Per Juel

N1 - KEY WORDS: Alexandrium · PST · Paralytic shellfish toxin · Allelopathy · Growth · Algae · pH

PY - 2009

Y1 - 2009

N2 - The effect of 2 strains (Alex2 and Alex5) of the marine red tide dinoflagellate Alexandrium tamarense on 10 other planktonic algal target species common in temperate waters was studied in mixed growth experiments under nutrient-rich conditions. In a comparative approach, the 2 strains of A. tamarense, similar in their cellular paralytic shellfish toxin (PST) content, were selected because of their fundamentally different lytic potencies. The Alex2 strain clearly affected all target algae while the Alex5 strain had no negative effect on the growth of any of the target species during the study period, even though cell concentrations of Alex5 became very high (2 × 104 cells ml-1). As both strains contained comparable amounts of PST, this confirmed previous suggestions that so far unidentified compounds are causing the negative effects on other algae. Sensitivity of the tested algae to Alex2 differed considerably. The growth of some species was affected at very low Alex2 cell concentrations (<102 cells ml-1), while the growth of other algae was not affected until cell concentrations exceeded 103 cells ml-1. While a complete dieoff was the ultimate fate for almost all target species when grown in mixed culture with Alex2, Scrippsiella trochoidea formed temporary cysts, the number of which remained constant during the course of the experiment. The pH in the mixed cultures increased as the cultures grew dense. This had a substantial effect on Alex5 in the mixed cultures, in which Alex5 eventually died off because the target species have a higher tolerance to high pH. pH values did not determine the outcome of the experiments with Alex2 because the adverse effects of Alex2 on the growth of the other algae was evident before pH values became too high. Lytic extracellular compounds, which are produced by the large majority of A. tamarense strains tested so far, clearly have the potential to benefit this dinoflagellate by reducing competitor growth rates.

AB - The effect of 2 strains (Alex2 and Alex5) of the marine red tide dinoflagellate Alexandrium tamarense on 10 other planktonic algal target species common in temperate waters was studied in mixed growth experiments under nutrient-rich conditions. In a comparative approach, the 2 strains of A. tamarense, similar in their cellular paralytic shellfish toxin (PST) content, were selected because of their fundamentally different lytic potencies. The Alex2 strain clearly affected all target algae while the Alex5 strain had no negative effect on the growth of any of the target species during the study period, even though cell concentrations of Alex5 became very high (2 × 104 cells ml-1). As both strains contained comparable amounts of PST, this confirmed previous suggestions that so far unidentified compounds are causing the negative effects on other algae. Sensitivity of the tested algae to Alex2 differed considerably. The growth of some species was affected at very low Alex2 cell concentrations (<102 cells ml-1), while the growth of other algae was not affected until cell concentrations exceeded 103 cells ml-1. While a complete dieoff was the ultimate fate for almost all target species when grown in mixed culture with Alex2, Scrippsiella trochoidea formed temporary cysts, the number of which remained constant during the course of the experiment. The pH in the mixed cultures increased as the cultures grew dense. This had a substantial effect on Alex5 in the mixed cultures, in which Alex5 eventually died off because the target species have a higher tolerance to high pH. pH values did not determine the outcome of the experiments with Alex2 because the adverse effects of Alex2 on the growth of the other algae was evident before pH values became too high. Lytic extracellular compounds, which are produced by the large majority of A. tamarense strains tested so far, clearly have the potential to benefit this dinoflagellate by reducing competitor growth rates.

U2 - 10.3354/ame01329

DO - 10.3354/ame01329

M3 - Journal article

SN - 0948-3055

VL - 57

SP - 101

EP - 112

JO - Aquatic Microbial Ecology

JF - Aquatic Microbial Ecology

IS - 1

ER -

Allelopathic effects of Alexandrium tamarense on other algae: evidence from mixed growth experiments

Abstract

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