Alaina J. LaPanse, Tyson A. Burch, Jacob M. Tamburro, Jesse C. Traller, Agnieszka Pinowska, Matthew C. Posewitz
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引用次数: 0
Abstract
Outdoor microalgal cultivation for the production of valuable biofuels and bioproducts typically requires high insolation and strains with high thermal (>37°C) tolerance. While some strains are naturally thermotolerant, other strains of interest require improved performance at elevated temperatures to enhance industrial viability. In this study, adaptive laboratory evolution (ALE) was performed for over 300 days using consecutive 0.5°C temperature increases in a constant temperature incubator to attain greater thermal tolerance in the industrially relevant diatom Nitzschia inconspicua str. Hildebrandi. The adapted strain was able to grow at a constant temperature of 37.5°C; whereas this constant temperature was lethal to the parental control, which had an upper-temperature boundary of 35.5°C before adaptive evolution. Several high-temperature clonal isolates were obtained from the evolved population following ALE, and increased temperature tolerance was observed in the clonal, parent, and non-clonal adapted cultures. This ALE method demonstrates the development of enhanced industrial algal strains without the production of genetically modified organisms (GMOs).
用于生产有价值的生物燃料和生物产品的室外微藻培养通常需要高日照和耐热性(37°C)高的菌株。虽然有些菌株天生耐热,但其他菌株需要在高温下改进性能以提高工业生存能力。在本研究中,在恒温培养箱中连续升温0.5°C,进行了300多天的适应性实验室进化(ALE),以获得工业相关硅藻Nitzschia inua str. Hildebrandi的更大耐热性。适应菌株能在37.5℃恒温下生长;而这一恒定温度对亲代控制是致命的,在适应进化之前,亲代控制的温度上限为35.5℃。从ALE后进化的群体中获得了几个高温克隆分离物,并且在克隆、亲本和非克隆适应培养中观察到耐温性增强。这种ALE方法证明了在不生产转基因生物(GMOs)的情况下开发增强的工业藻类菌株。
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