Isolation, characterization, and validation of oleaginous, multi-trophic, and haloalkaline-tolerant microalgae for two-stage cultivation

Wensel, Pierre; Helms, Greg; Hiscox, William C.; Davis, William C.; Kirchhoff, Helmut; Bule, Mahesh V.; Yu, Liang; Chen, Shulin

doi:10.1016/j.algal.2013.12.005

Cited by 37 publications

(15 citation statements)

References 41 publications

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“…2 ). In general, lipids can be over-produced by microalgae by introducing stress at the second cultivation stage, for instance nitrogen depletion [ 26 ], light intensity [ 27 ], temperature [ 28 ], salt concentration [ 29 ], or iron concentration in the second stage [ 30 ]. In one approach, microalgae were grown under red LEDs (660 nm) in the first phase to obtain the maximum biomass production, and stressed in the second phase using green LEDs (520 nm) to stimulate lipid accumulation [ 31 ].…”

Section: Manipulation Of Stresses By Different Cultivation Modesmentioning

confidence: 99%

Microalgae for the production of lipid and carotenoids: a review with focus on stress regulation and adaptation

Sun

Ren

Zhao

et al. 2018

Biotechnol Biofuels

318

129

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Microalgae have drawn great attention as promising sustainable source of lipids and carotenoids. Their lipid and carotenoids accumulation machinery can be trigged by the stress conditions such as nutrient limitation or exposure to the damaging physical factors. However, stressful conditions often adversely affect microalgal growth and cause oxidative damage to the cells, which can eventually reduce the yield of the desired products. To overcome these limitations, two-stage cultivation strategies and supplementation of growth-promoting agents have traditionally been utilized, but developing new highly adapted strains is theoretically the simplest strategy. In addition to genetic engineering, adaptive laboratory evolution (ALE) is frequently used to develop beneficial phenotypes in industrial microorganisms during long-term selection under specific stress conditions. In recent years, many studies have gradually introduced ALE as a powerful tool to improve the biological properties of microalgae, especially for improving the production of lipid and carotenoids. In this review, strategies for the manipulation of stress in microalgal lipids and carotenoids production are summarized and discussed. Furthermore, this review summarizes the overall state of ALE technology, including available selection pressures, methods, and their applications in microalgae for the improved production of lipids and carotenoids.

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Section: Manipulation Of Stresses By Different Cultivation Modesmentioning

confidence: 99%

Microalgae for the production of lipid and carotenoids: a review with focus on stress regulation and adaptation

Sun

Ren

Zhao

et al. 2018

Biotechnol Biofuels

318

129

View full text Add to dashboard Cite

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“…,b; Kitcha and Cheirslip ; Louhasakul and Cheirsilp ; Wensel et al . ), or as a substrate for the production of metabolic compounds (such as citric acid, acetic acid, polyols, etc.) by yeast strains (Papanikolaou et al .…”

Section: Introductionmentioning

confidence: 99%

“…Single cell oils are of great interest for industrial biotechnology, since they can be used either as replacements of high-added value oils and fats rarely found in the plant or animal kingdom, or they can constitute precursors of the synthesis of '2nd' or '3rd' generation biodiesel Aggelis 2009, 2011a,b;Abghari and Chen 2014). Although (crude, biodiesel-derived) glycerol has been used in many studies as a substrate for the production of SCOs by several eukaryotic microbial strains (Meesters et al 1996;Papanikolaou et al 2002;Chi et al 2007;Pyle et al 2008;Andr e et al 2009Andr e et al , 2010Liang et al 2010a,b;Makri et al 2010;Chatzifragkou et al 2011a;Ethier et al 2011;Saenge et al 2011;Dedyukhina et al 2012Dedyukhina et al , 2014Fontanille et al 2012;Cui et al 2012;Chang et al 2013;Duarte et al 2013a,b;Kitcha and Cheirslip 2013;Louhasakul and Cheirsilp 2013;Wensel et al 2014), or as a substrate for the production of metabolic compounds (such as citric acid, acetic acid, polyols, etc.) by yeast strains (Papanikolaou et al 2002(Papanikolaou et al , 2008Rymowicz et al 2008Rymowicz et al , 2010Andr e et al 2009;Rywi nska and Rymowicz 2009;Chatzifragkou et al 2011a,b;Kamzolova et al 2011;Rywi nska et al 2011;Morgunov et al 2013;Petrik et al 2013), data concerning the growth and lipid production by strains of yeasts Rhodosporidium toruloides and Lipomyces starkeyi growing on glycerol are scarce in the international literature <...>…”

Section: Introductionmentioning

confidence: 99%

Lipid production by yeasts growing on biodiesel-derived crude glycerol: strain selection and impact of substrate concentration on the fermentation efficiency

et al. 2015

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“…Furthermore, employing bicarbonate as a carbon source is superior to carbon dioxide injection as it is more soluble and is retained in the culture medium and not lost by outgassing (Chi et al 2011). The use of carbonates in conjunction with steep alkaline conditions and competent oleaginous microalgae can provide an ideal setting for large-scale production of biofuels and compounds essential to human supplements and drugs (Wensel et al 2014). Although application of alkaliphilic or alkali-tolerant microalgae may be practical in mass cultivation, native lipid-producing microalgal strains suitable for these special conditions are ideal.…”

Section: Selective Enrichment Of Alkali-tolerant Isolatesmentioning

confidence: 99%

Omega-7 producing alkaliphilic diatom <italic>Fistulifera</italic> sp. (Bacillario-phyceae) from Lake Okeechobee, Florida

Berthold¹,

Rosa²,

Engene³

et al. 2020

ALGAE

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Incorporating renewable fuel into practice, especially from algae, is a promising approach in reducing fossil fuel dependency. Algae are an exceptional feedstock since they produce abundant biomass and oils in short timeframes. Algae also produce high-valued lipid products suitable for human nutrition and supplement. Achieving goals of producing algae fuels and high-valued lipids at competitive prices involves further improvement of technology, especially better control over cultivation. Manipulating microalgae cultivation conditions to prevent contamination is essential in addition to promoting optimal growth and lipid yields. Contamination of algal cultures is a major impediment to algae cultivation that can however be mitigated by choosing extremophile microalgae. This work describes the isolation of alkali-tolerant / alkaliphilic microalgae native to South Florida with ideal characteristics for cultivation. For that purpose, water samples from Lake Okeechobee were inoculated into Zarrouk's medium (pH 9-12) and incubated for 35 days. Selection resulted in isolation of three strains that were screened for biomass and lipid accumulation. Two alkali-tolerant algae Chloroidium sp. 154-1 and Chlorella sp. 154-2 were poor lipid accumulators. One of the isolates, the diatom Fistulifera sp. 154-3, was identified as a lipid accumulating, alkaliphilic organism capable of producing 0.233 g L -1 d -1 dry biomass and a lipid content of 20-30% dry weight. Lipid analysis indicated the most abundant fatty acid within Fistulifera sp. was palmitoleic acid (52%), or omega-7, followed by palmitic acid (17%), and then eicosapentanoic acid (15%). 18S rRNA phylogenetic analysis formed a well-supported clade with Fistulifera species.

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Isolation, characterization, and validation of oleaginous, multi-trophic, and haloalkaline-tolerant microalgae for two-stage cultivation

Cited by 37 publications

References 41 publications

Microalgae for the production of lipid and carotenoids: a review with focus on stress regulation and adaptation

Microalgae for the production of lipid and carotenoids: a review with focus on stress regulation and adaptation

Lipid production by yeasts growing on biodiesel-derived crude glycerol: strain selection and impact of substrate concentration on the fermentation efficiency

Omega-7 producing alkaliphilic diatom <italic>Fistulifera</italic> sp. (Bacillario-phyceae) from Lake Okeechobee, Florida

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