Transgenic Microalgae as Green Cell Factories

AbstractWith modern genetic engineering tools, microorganisms can become resilient green cell factories to produce sustainable biofuels directly. Compared to non-engineered algae and cyanobacteria, the photon conversion efficiency can be significantly increased. Furthermore, simplified harvesting processes are feasible since the novel microorganisms are excreting the biofuels or their precursors continuously and directly into the cultivation media. Along with higher productivity and direct product harvesting, it is expected that environmental benefits can be achieved, especially for climate protection. A life cycle assessment (LCA) for biobutanol production with the genetically engineered cyanobacteria Synechocystis PCC6803 is performed to test this hypothesis. A prospective and upscaled approach was applied to assess the environmental impacts at large-scale production (20 ha plant) for better comparability with conventional butanol production. The LCA results show that the engineering of microorganisms can improve the environmental impact, mainly due to the higher productivity compared to non-engineered cyanobacteria. However, the nevertheless high electricity demand required for the cultivation and harvesting process overcompensates this benefit. According to the scenario calculations, a more favourable climate gas balance can be achieved if renewable electricity is used. Then, greenhouse gas emissions are reduced to 3.1 kg CO2 eq/kg biobutanol, corresponding to 20% more than the fossil reference: (2.45 kg CO2 eq./kg 1-butanol). The results indicate the importance of genetic engineering and the energy transition towards renewable electricity supply to take full advantage of the environmental potential of microorganisms as future green cell factories for sustainable biofuel production. Besides, the necessity of developing different scenarios for perspective and upscaled LCA for a fairer comparison with mature reference technologies is demonstrated.

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Heterologous Synthesis and Recovery of Advanced Biofuels from Bacterial Cell Factories

Protein and Peptide Letters ◽

10.2174/0929866525666180122125237 ◽

2018 ◽

Vol 25 (2) ◽

pp. 120-128 ◽

Cited By ~ 2

Author(s):

Sana Malik ◽

Ifrah Afzal ◽

Muhammad Aamer Mehmood ◽

Huda Al Doghaither ◽

Sawsan Abdulaziz Rahimuddin ◽

...

Keyword(s):

Bacterial Cell ◽

Advanced Biofuels ◽

Cell Factories

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Membrane traffic related to endosome dynamics and protein secretion in filamentous fungi

Bioscience Biotechnology and Biochemistry ◽

10.1093/bbb/zbab004 ◽

2021 ◽

Author(s):

Yujiro Higuchi

Keyword(s):

Filamentous Fungi ◽

Protein Secretion ◽

Secretory Pathway ◽

Molecular Mechanisms ◽

Membrane Traffic ◽

Early Endosome ◽

Protein Glycosylation ◽

Hyphal Cell ◽

Cell Factories ◽

Membrane Contacts

ABSTRACT In eukaryotic cells, membrane-surrounded organelles are orchestrally organized spatiotemporally under environmental situations. Among such organelles, vesicular transports and membrane contacts occur to communicate each other, so-called membrane traffic. Filamentous fungal cells are highly polarized and thus membrane traffic is developed to have versatile functions. Early endosome (EE) is an endocytic organelle that dynamically exhibits constant long-range motility through the hyphal cell, which is proven to have physiological roles, such as other organelle distribution and signal transduction. Since filamentous fungal cells are also considered as cell factories, to produce valuable proteins extracellularly, molecular mechanisms of secretory pathway including protein glycosylation have been well investigated. In this review, molecular and physiological aspects of membrane traffic especially related to EE dynamics and protein secretion in filamentous fungi are summarized, and perspectives for application are also described.

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Molecular characterization of HEK293 cells as emerging versatile cell factories

Current Opinion in Biotechnology ◽

10.1016/j.copbio.2021.05.001 ◽

2021 ◽

Vol 71 ◽

pp. 18-24

Author(s):

Michela Pulix ◽

Vera Lukashchuk ◽

Daniel C Smith ◽

Alan J Dickson

Keyword(s):

Molecular Characterization ◽

Hek293 Cells ◽

Cell Factories

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Enzymatic Hydrolysate of Cinnamon Waste Material as Feedstock for the Microbial Production of Carotenoids

International Journal of Environmental Research and Public Health ◽

10.3390/ijerph18031146 ◽

2021 ◽

Vol 18 (3) ◽

pp. 1146

Author(s):

Stefano Bertacchi ◽

Stefania Pagliari ◽

Chiara Cantù ◽

Ilaria Bruni ◽

Massimo Labra ◽

...

Keyword(s):

Industrial Sector ◽

Waste Material ◽

Fungal Cell ◽

Enzymatic Hydrolysate ◽

Carbon And Nitrogen ◽

Microbial Cell Factories ◽

Cell Factories ◽

Separate Hydrolysis And Fermentation ◽

Additional Processing ◽

Microbial Cultivation

In the context of the global need to move towards circular economies, microbial cell factories can be employed thanks to their ability to use side-stream biomasses from the agro-industrial sector to obtain additional products. The valorization of residues allows for better and complete use of natural resources and, at the same time, for the avoidance of waste management to address our needs. In this work, we focused our attention on the microbial valorization of cinnamon waste material after polyphenol extraction (C-PEW) (Cinnamomum verum J.Presl), generally discarded without any additional processing. The sugars embedded in C-PEW were released by enzymatic hydrolysis, more compatible than acid hydrolysis with the subsequent microbial cultivation. We demonstrated that the yeast Rhodosporidium toruloides was able to grow and produce up to 2.00 (±0.23) mg/L of carotenoids in the resulting hydrolysate as a sole carbon and nitrogen source despite the presence of antimicrobial compounds typical of cinnamon. To further extend the potential of our finding, we tested other fungal cell factories for growth on the same media. Overall, these results are opening the possibility to develop separate hydrolysis and fermentation (SHF) bioprocesses based on C-PEW and microbial biotransformation to obtain high-value molecules.

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Protein-Engineered Polymers Functionalized with Antimicrobial Peptides for the Development of Active Surfaces

Applied Sciences ◽

10.3390/app11125352 ◽

2021 ◽

Vol 11 (12) ◽

pp. 5352

Author(s):

Ana Margarida Pereira ◽

Diana Gomes ◽

André da Costa ◽

Simoni Campos Dias ◽

Margarida Casal ◽

...

Keyword(s):

Antimicrobial Activity ◽

Antimicrobial Peptides ◽

Recombinant Dna ◽

Biological Properties ◽

Resistant Bacteria ◽

Recombinant Dna Technology ◽

Free Standing ◽

Microbial Cell Factories ◽

Cell Factories ◽

Antimicrobial Materials

Antibacterial resistance is a major worldwide threat due to the increasing number of infections caused by antibiotic-resistant bacteria with medical devices being a major source of these infections. This suggests the need for new antimicrobial biomaterial designs able to withstand the increasing pressure of antimicrobial resistance. Recombinant protein polymers (rPPs) are an emerging class of nature-inspired biopolymers with unique chemical, physical and biological properties. These polymers can be functionalized with antimicrobial molecules utilizing recombinant DNA technology and then produced in microbial cell factories. In this work, we report the functionalization of rPBPs based on elastin and silk-elastin with different antimicrobial peptides (AMPs). These polymers were produced in Escherichia coli, successfully purified by employing non-chromatographic processes, and used for the production of free-standing films. The antimicrobial activity of the materials was evaluated against Gram-positive and Gram-negative bacteria, and results showed that the polymers demonstrated antimicrobial activity, pointing out the potential of these biopolymers for the development of new advanced antimicrobial materials.

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