<p>In the commercial production of <i>Arthrospira platensis</i> in outdoor environments, contamination by other microorganisms remains a major challenge. To exploit the high free ammonia (NH<sub>3</sub>) tolerance of <i>A. platensis</i>, we investigated whether continuous NH₃ exposure could enable its selective cultivation by suppressing the growth of biological contaminants. The cyanobacterium <i>Synechococcus leopoliensis</i>, which exhibits relatively high NH₃ tolerance, albeit lower than that of <i>A. platensis</i>, was used as a model contaminant. The absolute half-maximal effective concentrations (EC<sub>50</sub>) of NH<sub>3</sub> for <i>A. platensis</i> and <i>S. leopoliensis</i> in batch monocultures were 3.7 and 1.2 mmol L<sup><b>−</b>1</sup>, respectively. In the subsequent semi-continuous co-culture of <i>A. platensis</i> and <i>S. leopoliensis</i>, the selective growth of <i>A. platensis</i> was achieved at an NH<sub>3</sub> concentration of 2.5 mmol L<sup>−1</sup>, which was predicted to completely suppress the growth of <i>S. leopoliensis</i>. Although the inhibitory effect of NH<sub>3</sub> on <i>A. platensis</i> tended to be enhanced when co-cultured with <i>S. leopoliensis</i> compared to the monoculture, <i>A. platensis</i> continued to proliferate at a cell yield of 9.30×10<sup>8</sup> cells L<sup>-1</sup> day<sup>-1</sup>. Since the NH<sub>3</sub> tolerance of <i>S. leopoliensis</i> is comparable to or even higher than that of many other contaminants and grazers, these lab-scale results suggest the feasibility of the selective culture of <i>A. platensis</i> in the presence of biological contamination through appropriate control of NH<sub>3</sub> concentration.</p>

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Selective culture of Arthrospira platensis by continuous NH3 exposure to control microalgal contaminants and grazers, exemplified by Synechococcus leopoliensis

  • Mutsumi Sekine,
  • Akari Yoshida,
  • Masatoshi Kishi,
  • Ken Furuya,
  • Tatsuki Toda

摘要

In the commercial production of Arthrospira platensis in outdoor environments, contamination by other microorganisms remains a major challenge. To exploit the high free ammonia (NH3) tolerance of A. platensis, we investigated whether continuous NH₃ exposure could enable its selective cultivation by suppressing the growth of biological contaminants. The cyanobacterium Synechococcus leopoliensis, which exhibits relatively high NH₃ tolerance, albeit lower than that of A. platensis, was used as a model contaminant. The absolute half-maximal effective concentrations (EC50) of NH3 for A. platensis and S. leopoliensis in batch monocultures were 3.7 and 1.2 mmol L1, respectively. In the subsequent semi-continuous co-culture of A. platensis and S. leopoliensis, the selective growth of A. platensis was achieved at an NH3 concentration of 2.5 mmol L−1, which was predicted to completely suppress the growth of S. leopoliensis. Although the inhibitory effect of NH3 on A. platensis tended to be enhanced when co-cultured with S. leopoliensis compared to the monoculture, A. platensis continued to proliferate at a cell yield of 9.30×108 cells L-1 day-1. Since the NH3 tolerance of S. leopoliensis is comparable to or even higher than that of many other contaminants and grazers, these lab-scale results suggest the feasibility of the selective culture of A. platensis in the presence of biological contamination through appropriate control of NH3 concentration.