Sustainability of in vitro light-dependent NADPH generation by the thylakoid membrane of Synechocystis sp. PCC6803

Tong, Xiaomeng; Kim, Eui-Jin; Lee, Chang Kyu

doi:10.1186/s12934-022-01825-1

Cited by 4 publications

(2 citation statements)

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“…In nature, biological photosynthesis is regulated inside the thylakoids that form separate compartments (lumen) surrounded by a protein membrane present in chloroplasts of plants, cyanobacteria and algae [119]. The resulting products of photosynthesis, i.e., NADPH and ATP proteins, are used by the photosynthetic cells to produce organic molecules [120]. The integral membrane proteins form different complexes in the thylakoid membrane (e.g., photosystems PSI and PSII) and initiate a range of catalytic light-dependent reactions for photosynthesis [121].…”

Section: Mimicking Nature For Artificial Photosynthesis Platformsmentioning

confidence: 99%

Role of Nanocellulose in Light Harvesting and Artificial Photosynthesis

et al. 2023

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Artificial photosynthesis has rapidly developed as an actual field of research, mimicking natural photosynthesis processes in plants or bacteria to produce energy or high-value chemicals. The nanocelluloses are a family of biorenewable materials that can be engineered into nanostructures with favorable properties to serve as a host matrix for encapsulation of photoreactive moieties or cells. In this review, the production of different nanocellulose structures such as films, hydrogels, membranes, and foams together with their specific properties to function as photosynthetic devices are described. In particular, the nanocellulose’s water affinity, high surface area and porosity, mechanical stability in aqueous environment, and barrier properties can be tuned by appropriate processing. From a more fundamental viewpoint, the optical properties (transparency and haze) and interaction of light with nanofibrous structures can be further optimized to enhance light harvesting, e.g., by functionalization or appropriate surface texturing. After reviewing the basic principles of natural photosynthesis and photon interactions, it is described how they can be transferred into nanocellulose structures serving as a platform for immobilization of photoreactive moieties. Using photoreactive centers, the isolated reactive protein complexes can be applied in artificial bio-hybrid nanocellulose systems through self-assembly, or metal nanoparticles, metal-organic frameworks, and quantum dots can be integrated in nanocellulose composites. Alternatively, the immobilization of algae or cyanobacteria in nanopaper coatings or a porous nanocellulose matrix allows to design photosynthetic cell factories and advanced artificial leaves. The remaining challenges in upscaling and improving photosynthesis efficiency are finally addressed in order to establish a breakthrough in utilization of nanocellulose for artificial photosynthesis.

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Section: Mimicking Nature For Artificial Photosynthesis Platformsmentioning

confidence: 99%

Role of Nanocellulose in Light Harvesting and Artificial Photosynthesis

et al. 2023

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“…[33][34][35][36] 3) The thylakoid membrane can produce ATP and NADPH under light irradiation, which serve as energy currencies to promote and regulate cellular functions comprehensively. [37,38] 4) Chlorophyll in the thylakoid membrane shows encouraging absorption of light. It is a promising way to exploit the light absorption and photothermal conversion ability of chlorophyll within thylakoid membrane in photothermal treatment (PTT) of cancer.…”

Section: Introductionmentioning

confidence: 99%

Nature‐Inspired Thylakoid‐Based Photosynthetic Nanoarchitectures for Biomedical Applications

Kong,

Zhu,

et al. 2023

Small Methods

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Abstract“Drawing inspiration from nature” offers a wealth of creative possibilities for designing cutting‐edge materials with improved properties and performance. Nature‐inspired thylakoid‐based nanoarchitectures, seamlessly integrate the inherent structures and functions of natural components with the diverse and controllable characteristics of nanotechnology. These innovative biomaterials have garnered significant attention for their potential in various biomedical applications. Thylakoids possess fundamental traits such as light harvesting, oxygen evolution, and photosynthesis. Through the integration of artificially fabricated nanostructures with distinct physical and chemical properties, novel photosynthetic nanoarchitectures can be catalytically generated, offering versatile functionalities for diverse biomedical applications. In this article, an overview of the properties and extraction methods of thylakoids are provided. Additionally, the recent advancements in the design, preparation, functions, and biomedical applications of a range of thylakoid‐based photosynthetic nanoarchitectures are reviewed. Finally, the foreseeable challenges and future prospects in this field is discussed.

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