Cyanobacteria—From the Oceans to the Potential Biotechnological and Biomedical Applications

Khalifa, Shaden A. M.; Shedid, Eslam S.; Saied, Essa M.; Jassbi, Amir Reza; Jamebozorgi, Fatemeh Heidary; Rateb, Mostafa E.; Du, Ming; Abdel-Daim, Mohamed M.; Kai, Guoyin; Atia, Mohamed A. M.; Xiao, Jianbo; Guo, Zhiming; El‐Seedi, Hesham R.

doi:10.3390/md19050241

Cited by 72 publications

(44 citation statements)

References 199 publications

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“…In particular, it is to recall that Spirulina species belong to cyanobacteria and contain both chlorophyll and phycocyanins, the respective green and blue pigments involved in photosynthesis, making Spirulina species to be commonly defined as a blue-green alga. Phycocyanins exhibit special spectral properties in term of high absorbance and fluorescence yields, accounting for their photoprotection role in cyanobacteria and for more general strong antioxidant properties, which have stimulated the use of phycocyanins in nutriceutics and pharmacology, besides the use in food and pharmaceutics as a mere dye [15,50,51,[54][55][56][57][58][59]. The absorption and fluorescence properties of purified phycocyanin and allophycocyanin have been also analyzed by time-resolved techniques to investigate ultrafast kinetic components of excitation energy transfer in phycobilisome, with the aim to improve the collection of solar energy for photovoltaic applications [15].…”

Section: Chlorophyll and Algaementioning

confidence: 99%

“…The main fluorophores described in this section are summarized in Table 2. [10,22,23] Abiotic stress in higher plants [39] Phycocyanin Allo-phycocyanin 550-670 nm 650-700 nm Light harvesting, efficient energy conversion, photoprotection in cyanobacteria [58] Food and pharmaceutic additives [15,50,51,[54][55][56][57][58][59] Models to improve photovoltaic applications [15] * Other optical parameters besides absorption/fluorescence may have been used in some applications; excitation/emission ranges may vary depending on measurement conditions.…”

Section: Chlorophyll and Algaementioning

confidence: 99%

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Light and Autofluorescence, Multitasking Features in Living Organisms

Croce

2021

Photochem

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Organisms belonging to all life kingdoms may have the natural capacity to fluoresce. Autofluorescence events depend on the presence of natural biomolecules, namely endogenous fluorophores, with suitable chemical properties in terms of conjugated double bonds, aromatic or more complex structures with oxidized and crosslinked bonds, ensuring an energy status able to permit electronic transitions matching with the energy of light in the UV-visible-near-IR spectral range. Emission of light from biological substrates has been reported since a long time, inspiring unceasing and countless studies. Early notes on autofluorescence of vegetables have been soon followed by attention to animals. Investigations on full living organisms from the wild environment have been driven prevalently by ecological and taxonomical purposes, while studies on cells, tissues and organs have been mainly promoted by diagnostic aims. Interest in autofluorescence is also growing as a sensing biomarker in food production and in more various industrial processes. The associated technological advances have supported investigations ranging from the pure photochemical characterization of specific endogenous fluorophores to their possible functional meanings and biological relevance, making fluorescence a valuable intrinsic biomarker for industrial and diagnostic applications, in a sort of real time, in situ biochemical analysis. This review aims to provide a wide-ranging report on the most investigated natural fluorescing biomolecules, from microorganisms to plants and animals of different taxonomic degrees, with their biological, environmental or biomedical issues relevant for the human health. Hence, some notes in the different sections dealing with different biological subject are also interlaced with human related issues. Light based events in biological subjects have inspired an almost countless literature, making it almost impossible to recall here all associated published works, forcing to apologize for the overlooked reports. This Review is thus proposed as an inspiring source for Readers, addressing them to additional literature for an expanded information on specific topics of more interest.

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Section: Chlorophyll and Algaementioning

confidence: 99%

Section: Chlorophyll and Algaementioning

confidence: 99%

Light and Autofluorescence, Multitasking Features in Living Organisms

Croce

2021

Photochem

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“…Cyanobacteria, in general, possess structurally diverse metabolites with immense bioactive potential for use in drug synthesis (Sharma et al, 2011;Galica et al, 2017;Khalifa et al, 2021).…”

Section: Discussionmentioning

confidence: 99%

“…The rapid growth of resistance in pathogenic bacteria and fungi has recently led to the necessity for a new strategy in drug development by depending on antimicrobial products of natural origin (e.g., El-Sheekh et al, 2008;Righini & Roberti, 2019;Besednova et al, 2020). Members of the phylum Cyanobacteria, in particular the heterocytous genera and taxa, have been characterized as keystone producers of biologically active and structurally diverse compounds with high-value pharmaceutical importance (El-Sheekh et al, 2008;Saurav et al, 2019;Khalifa et al, 2021). However, our understanding of the antimicrobial potential of the dryland-inhabiting taxa, such as the poorly studied Westiellopsis prolifica (Hapalosiphonaceae, Nostocales), remains scarce in this area of research.…”

Section: Introductionmentioning

confidence: 99%

Antimicrobial Activity of the Heterocytous Cyanobacterium Westiellopsis prolifica and Assessment of Its Microcystin–LR Biosynthesis

et al. 2021

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“…These marine natural products can be used in applications such as drugs in the fight against cancer, virus, or bacterial infections but also as cosmetics [1][2][3][4]. Cyanobacteria that represent at least 50% of the aquatic biomass are effective producers of secondary metabolites that can be used as therapeutic agents [5][6][7][8], among which peptides isolated from various strains all over the world [9]. These peptides are often synthesized by non-ribosomal peptide synthetase (NRPS) or mixed biosynthetic pathways that involve polyketide synthase (PKS) operating in conjunction with NRPS [10][11][12].…”

Section: Introductionmentioning

confidence: 99%

Thirtieth Anniversary of the Discovery of Laxaphycins. Intriguing Peptides Keeping a Part of Their Mystery

et al. 2021

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Lipopeptides are a class of compounds generally produced by microorganisms through hybrid biosynthetic pathways involving non-ribosomal peptide synthase and a polyketyl synthase. Cyanobacterial-produced laxaphycins are examples of this family of compounds that have expanded over the past three decades. These compounds benefit from technological advances helping in their synthesis and characterization, as well as in deciphering their biosynthesis. The present article attempts to summarize most of the articles that have been published on laxaphycins. The current knowledge on the ecological role of these complex sets of compounds will also be examined.

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Cyanobacteria—From the Oceans to the Potential Biotechnological and Biomedical Applications

Cited by 72 publications

References 199 publications

Light and Autofluorescence, Multitasking Features in Living Organisms

Light and Autofluorescence, Multitasking Features in Living Organisms

Antimicrobial Activity of the Heterocytous Cyanobacterium Westiellopsis prolifica and Assessment of Its Microcystin–LR Biosynthesis

Thirtieth Anniversary of the Discovery of Laxaphycins. Intriguing Peptides Keeping a Part of Their Mystery

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