Abstract

Haloferax mediterranei produces C50 carotenoids that have strong antioxidant properties. The response surface methodology (RSM) tool helps to accurately analyze the most suitable conditions to maximize C50 carotenoids production by haloarchaea. The effects of temperature (15–50 °C), pH (4−10), and salinity (5–28% NaCl (w/v)) on the growth and carotenoid content of H. mediterranei were analyzed using the RSM approach. Growth was determined by measuring the turbidity at 600 nm. To determine the carotenoid content, harvested cells were lysed by freeze/thawing, then re-suspended in acetone and the total carotenoid content determined by measuring the absorbance at 494 nm. The analysis of carotenoids was performed by an HPLC system coupled with mass spectrometry. The results indicated the theoretical optimal conditions of 36.51 or 36.81 °C, pH of 8.20 or 8.96, and 15.01% or 12.03% (w/v) salinity for the growth of haloarchaea (OD600 = 12.5 ± 0.64) and production of total carotenoids (3.34 ± 0.29 mg/L), respectively. These conditions were validated experimentally for growth (OD600 = 13.72 ± 0.98) and carotenoid production (3.74 ± 0.20 mg/L). The carotenoid profile showed four isomers of bacterioruberin (89.13%). Our findings suggest that the RSM approach is highly useful for determining optimal conditions for large-scale production of bacterioruberin by haloarchaea.

Highlights

  • Carotenoids are pigments present in all living organisms; they are synthesized only by bacteria, algae, fungi, and plants

  • We demonstrate that response surface methodology (RSM) is useful for optimization of conditions for growth rate and carotenoid production by H. mediterranei at the laboratory scale

  • This study was not aimed at determining the optimal air phase volume for production of H. mediterranei as it depends on the cultivation system design and parameters selected in each production process

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Summary

Introduction

Carotenoids (carotenes and xanthophylls) are pigments present in all living organisms; they are synthesized only by bacteria, algae, fungi, and plants. They comprise a large family of over 700 naturally-occurring pigments characteristically present in leaves, flowers, and fruits of plants, where they play various roles. They utilize light energy to support the chlorophyll-dependent photosynthetic electron flow inside the chloroplasts. Mar. Drugs 2018, 16, 372; doi:10.3390/md16100372 www.mdpi.com/journal/marinedrugs. Mar. Drugs 2018, 16, 372 dissipate excess light energy and owing to their antioxidant activity, protect the photosynthetic machinery against photoinhibition caused by free oxygen radicals [1]

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