Co-Cultivation of Fungal and Microalgal Cells as an Efficient System for Harvesting Microalgal Cells, Lipid Production and Wastewater Treatment

Wrede, Digby; Taha, Mohamed; Miranda, Ana F.; Kadali, Krishna K.; Stevenson, Trevor W.; Ball, Andrew S.; Mouradov, Aidyn

doi:10.1371/journal.pone.0113497

Cited by 173 publications

(127 citation statements)

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“…Microbial fl occulants have been isolated from auto-fl occulating microalgal cultures grown on wastewater (Manheim and Nelson 2013 ;Guo et al 2013 ). Cocultivation of microalgae with a fi lamentous fungus has been reported to induce fl occulation with an effi ciency of 90 % after the fi rst 24 h, with additional synergistic effects on total biomass yield, on the level and composition of lipids, and on the effi ciency of wastewater treatment (Wrede et al 2014 ). Both cocultivating partners contribute to the total biomass, that was found to be higher than the additive biomass.…”

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confidence: 99%

“…Both cocultivating partners contribute to the total biomass, that was found to be higher than the additive biomass. Moreover, cocultivation has the capacity to tailor the composition of fatty acids without the need for genetic engineering, suggesting benefi ts of this approach on both biomass harvesting and lipid biosynthesis for biodiesel production (Wrede et al 2014 ).…”

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Solar-to-fuel conversion in algae and cyanobacteria

Formighieri¹

2015

SpringerBriefs in Environmental Science

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confidence: 99%

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Solar-to-fuel conversion in algae and cyanobacteria

Formighieri¹

2015

SpringerBriefs in Environmental Science

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“…Although positive growth is demonstrated, there is a disproportionate focus concerned over using filamentous fungi to facilitate the harvesting of algae cells and disregard the lipid content of algae (Zhang and Hu 2012;Gultom and Hu 2013;Wrede et al 2014). And when lipid content is considered in a co-cultivation scheme of algae and fungi, the only explanations for the stimulation in biomass and lipid increase is an improved uptake of glucose from the medium and an induced fungal cellulase activity for the consumption of algal cell debris (Xie et al 2013).…”

Section: Cultivation Stress and Genetic Manipulationsmentioning

confidence: 99%

Enhancing Algal Biomass and Lipid Production through Bacterial and Fungal Co-Culture

Berthold¹

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“…Neste contexto, o cultivo misto entre diferentes microrganismos, ao invés de culturas independentes, é uma abordagem usualmente praticada em microbiologia para promover interações diretas que podem estimular o acúmulo de produtos naturais presentes constitutivamente ou induzir à expressão de vias biossintéticas silenciadas levando à produção de novos compostos (ANGELIS et al, 2012;BRAKHAGE, 2013;OLA et al, 2013;SANTOS & REIS, 2014;WREDE et al, 2014). Estudo com fungos associados da água viva Nemopilema nomurai, envolvendo cultivo independente e cultivo misto entre eles, mostraram que houve diferenças nos níveis da produção de metabólitos antibacterianos e antifúngicos produzidos (YUE et al, 2015).…”

Section: Trichoderma Atrovirideunclassified

“…Assim, até o momento, nenhuma pesquisa visando à produção de fármacos foi descrita. A associação (fungo e cianobactéria), no entanto, não é uma novidade, ela existe naturalmente a mais de 400 milhões de anos, na forma de líquens (WREDE et al, 2014). Estes que, por sua vez, podem ser formados pela associação entre fungos e algas ou fungos e cianobactérias, apresentam características interessantes como a produção de metabólitos secundários com aplicação na indústria farmacêutica, alimentícia, cosmética e etc (SUZUKI et al, 2016;SANTOS & REIS, 2014).…”

Section: Trichoderma Atrovirideunclassified

Estudo químico de cianobactérias marinhas e do cultivo misto entre a linhagem Geitlerinema sp CENA556 e o fungo Trichoderma atroviride, endófito da alga marinha Bostrychia tenella

Silva¹

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Estudo químico de cianobactérias marinhas e do cultivo misto entre a linhagem Geitlerinema sp CENA556 e o fungoMarine organisms are recognized as a rich reservoir of natural products with exceptional molecular structures. In this context, cyanobacteria and endophytic fungi has emerged as source of promising bioactive compounds. The aim of this work was to look for biologically active compounds from the marine cyanobacteria strains, collected in Ubatuba, coast of the São Paulo state (Brazil), and to explore the biosynthetic potential of the fungus Trichoderma atroviride (endophyte isolated from marine seaweed Bostrychia tenella, collected in the rocky Shore of Praia de Fortaleza, Ubatuba, SP) by coculture with the cyanobacteria strain Geitlerinema sp CENA556. Initially, five species of marine cyanobacteria were isolated from the sample collected at the coast of São Paulo, and then characterized phylogenetically. Among them, the strains coded as Geitlerinema sp CENA552 and Geitlerinema sp CENA556 were cultured in mimicking seawater medium and extracted with a mix of CH 2 Cl 2 / MeOH (2:1), and then EtOAc. The concentrated extract was partitioned into hexane fraction and MeOH/H2O (95: 5) fraction. Four known compounds were identified from the hexane fraction of the Geitlerinema sp CENA552 extract by GC-MS analysis: 2-hexyl-1-decanol, 3-octadecene, neophytadiene, and methyl palmitate. Similarly, the compounds dodecanal, 8-heptadecene, palmitaldehyde, neophytadiene, phytol, methyl palmitoleate, methyl 7-hexadecenoate, and methyl 9-hexadecenoate were identified from the hexane fraction of the Geitlerinema sp CENA556 extract. Starting of MeOH/H2O (95: 5) fraction of Geitlerinema sp CENA556 extract, seven compounds were isolated by semi preparative HPLC-PDA and identified by NMR spectroscopy and HR-MS analysis. Among them, five known nucleosides first isolated from cyanobacteria: 2'-deoxyuridine, thymidine, adenosine, 2'-deoxyadenosine, and uridine. Also two amino acids: D-leucine and L-phenylalanine. Trichoderma atroviride was grown alone in rice and Czapeck media and the coculture between the fungus and the cyanobacteria (Geitlerinema sp CENA556) were performed using the same media. The CH 2 Cl 2 / MeOH (2:1) and EtOAc pooled extract from the coculture of the fungus T. atroviride and the cyanobacteria Gleiterinema sp CENA556 in Czapek medium shows significant difference in the metabolites production when compared to individually cultured fungus and cyanobacteria. Four catechol type siderophores were isolated from MeOH/H2O (95: 5) fraction of this extract: agrobactin, agrobactin A, photobactin and one novel compound. Agrobactin, the major compound, showed substantial antibacterial activity against P. mirabilis, E. coli, S. saprophyticus, S. aureus and P. aeruginosa. Thus, the studied brazilian cyanobacteria Geitlerinema sp appeared to be promising for isolation of nucleosides with biological activity. Furthermore, the fungus T. atroviride proved to be a prolific source of antibacterial siderophores obtained by biologic...

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Co-Cultivation of Fungal and Microalgal Cells as an Efficient System for Harvesting Microalgal Cells, Lipid Production and Wastewater Treatment

Cited by 173 publications

References 72 publications

Solar-to-fuel conversion in algae and cyanobacteria

Solar-to-fuel conversion in algae and cyanobacteria

Enhancing Algal Biomass and Lipid Production through Bacterial and Fungal Co-Culture

Estudo químico de cianobactérias marinhas e do cultivo misto entre a linhagem Geitlerinema sp CENA556 e o fungo Trichoderma atroviride, endófito da alga marinha Bostrychia tenella

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