Synergistic carbon metabolism in a fast growing mixotrophic freshwater microalgal species Micractinium inermum

Richard T Smith,Krys Bangert,Stephen J Wilkinson,D James Gilmour

doi:10.1016/j.biombioe.2015.04.023

Richard T Smith, Krys Bangert + Show 2 more

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https://doi.org/10.1016/j.biombioe.2015.04.023

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Journal: Biomass & Bioenergy	Publication Date: May 11, 2015
Citations: 132	License type: cc-by

Affiliation: University of Sheffield

Abstract

In recent years microalgae have attracted significant interest as a potential source of sustainable biofuel. Mixotrophic microalgae are able to simultaneously photosynthesise while assimilating and metabolising organic carbon. By combining autotrophic and heterotrophic metabolic pathways biomass productivity can be significantly increased. In this study, acetate-fed mixotrophic Micractinium inermum cultures were found to have a specific growth rate 1.74 times the sum of autotrophic and heterotrophic growth. It was hypothesised that gas exchange between the two metabolic pathways within mixotrophic cultures may have prevented growth limitation and enhanced growth. To determine the extent of synergistic gas exchange and its influence on metabolic activity, dissolved inorganic carbon (DIC), dissolved oxygen (DO) and photosynthesis and respiration rates were measured under different trophic conditions. A 32.7 fold and 2.4 fold increase in DIC and DO concentrations, relative to autotrophic and heterotrophic cultures respectively, were coupled with significant increases in rates of photosynthesis and respiration. These data strongly support the hypothesis of mixotrophic gas exchange within M. inermum cultures. In addition to enhanced growth, this phenomenon may provide reductions in aeration and oxygen stripping costs related to microalgae production.

Highlights

Microalgae derived biofuels have the potential to meet a significant fraction of global transport fuel demand, enabling a reduction in our dependency on finite fossil fuels and their associated greenhouse gas emissions
The effect of organic carbon addition on the growth of M. inermum was investigated in a non-aerated batch culture experiment
The significantly enhanced metabolic activity, augmented growth rates and comparative stability of dissolved gas concentrations support the hypothesis of synergistic gas exchange between photosynthetic and respiratory metabolic pathways within mixotrophic cultures

Summary

Introduction

Microalgae derived biofuels have the potential to meet a significant fraction of global transport fuel demand, enabling a reduction in our dependency on finite fossil fuels and their associated greenhouse gas emissions. Microalgae have similar photosynthetic machinery to higher plants, their simpler cellular structure and planktonic mode of growth allow efficient access via diffusion to CO2 and other nutrients, enabling high biomass productivities. Oleaginous microalgae accumulate significant proportions of their biomass as lipids (typically 20e50% compared to

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