Update on Marine Carbohydrate Hydrolyzing Enzymes: Biotechnological Applications

Trincone, Antonio

doi:10.3390/molecules23040901

Cited by 32 publications

(23 citation statements)

References 116 publications

(116 reference statements)

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“…This indicates that they have developed various structural and metabolic changes that enable them to accommodate for the effects of the adverse condition . Furthermore, metabolites from these marine microorganisms are categorized by renowned features, such as halo tolerance, thermostability, barophilicity, and flexibility to cold, entirely connected to their habitation . Hence, the present study was focused on evaluating the biosurfactant‐producing potential of marine bacteria.…”

Section: Discussionmentioning

confidence: 99%

Effect of biosurfactant derived from Vibrio natriegens MK3 against Vibrio harveyi biofilm and virulence

et al. 2019

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Vibrio harveyi is a marine luminous pathogen, which causes biofilm-mediated infections, pressures the search for an innovative alternate approach to strive against vibriosis in aquaculture. This study anticipated to explore the effect of glycolipid biosurfactant as an antipathogenic against V. harveyi to control vibriosis. In this study, 27 bacterial strains were isolated from marine soil sediments. Out of these, 11 strains exhibited surfactant activity and the strain MK3 showed high emulsification index. The potent strain was identified as Vibrio natriegens and named as V. natriegens MK3. The extracted biosurfactant was purified using high-performance liquid chromatography and it was efficient to decrease the surface tension of the growth medium up to 21 mN/m. The functional group and composition of the biosurfactant were determined by Fourier-transform infrared spectroscopy and nuclear magnetic resonance spectroscopy spectral studies and the nature of the biosurfactant was identified as glycolipid. The surfactant was capable of reducing the biofilm formation, bioluminescence, extracellular polysaccharide synthesis, and quorum sensing in marine shrimp pathogen V. harveyi. The antagonistic effect of biosurfactant was evaluated against V. harveyi-infected brine shrimp Artemia salina. This study reveals that biosurfactant can be considered for the management of biofilmrelated aquatic infections.

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Section: Discussionmentioning

confidence: 99%

Effect of biosurfactant derived from Vibrio natriegens MK3 against Vibrio harveyi biofilm and virulence

et al. 2019

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“…Fungi and bacteria are capable of biologically pretreating lignocellulosic biomass by modifying its structure and degrading it into simpler substrates for ligninolytic enzyme digestion. Cellulose and hemicellulose are normally hydrolyzed in biological pretreatment to monomeric sugars using cellulolytic and hemicellulolytic microorganisms (Sharma et In addition to microorganisms such as bacteria and fungi, there are other organisms which could be used for biological pretreatment of biomass including insects (Varelas and Langton, 2017), worms (Devi et al, 2019), and gastropods (Trincone, 2018). Such macro-organisms are equipped with various mechanisms ranging from mechanical, enzymatic, gut flora and/or combo with certain physiological functions for the breakdown of cellulosic biomass.…”

Section: Biological Pretreatmentmentioning

confidence: 99%

Pretreatment methods for lignocellulosic biofuels production: current advances, challenges and future prospects

et al. 2020

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Keywords:Lignocellulosic biomass has been recognized as promising feedstock for biofuels production. However, the high cost of pretreatment is one of the major challenges hindering large-scale production of biofuels from these abundant, indigenouslyavailable, and economic feedstock. In addition to high capital and operation cost, high water consumption is also regarded as a challenge unfavorably affecting the pretreatment performance. In the present review, advances in lignocellulose pretreatment technologies for biofuels production are reviewed and critically discussed. Moreover, the challenges faced and future research needs are addressed especially in optimization of operating parameters and assessment of total cost of biofuel production from lignocellulose biomass at large scale by using different pretreatment methods. Such information would pave the way for industrial-scale lignocellulosic biofuels production. Overall, it is important to ensure that throughout lignocellulosic bioethanol production processes, favorable features such as maximal energy saving, waste recycling, wastewater recycling, recovery of materials, and biorefinery approach are considered.

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“…The capability of metabolic utilization of plant or macroalgae polysaccharides allows for an increase in the production of fungal biomass enriched by mycelium proteins and extracellular enzymes that can be used in animal or fish feeding, or in the bioremediation of soils and water (Supplementary Table 1 ). The unique properties of CAZymes from the marine fungi are important for biotechnology because of their ability to function at the high salinity and pH, low water potential, high sodium ion concentrations, extremely low or high temperature, oligotrophic nutrient conditions, and the high hydrostatic pressure in comparison with the enzymes of terrestrial fungi that are mostly cultivated at pH 4.5–6.0 and low salinity (≤0.05%) ( Raghukumar, 2008 ; Farinas et al, 2010 ; Pang et al, 2011 ; Zilly et al, 2011 ; Arfi et al, 2013 ; Del-Cid et al, 2014 ; Lee et al, 2015 ; Thirunavukkarasu et al, 2015 ; Dos Santos et al, 2016 ; Trincone, 2018 ).…”

Section: Carbohydrate-active Enzymesmentioning

confidence: 99%

“…Macroalgae may contain plant-specific cellulose and xylan as well as a range of unusual polymers for land organism such as alginates, fucans/fucoidans, laminarins (brown algae), agar/agarose, carrageenan (red algae), and ulvan (green algae), many of which are sulfated and include monomers of fucose and uronic acids. Thus, algal polysaccharides are more diverse that require additional catalytic mechanisms or metabolic pathways to their fermentation ( Vera et al, 2011 ; Abdallah et al, 2016 ; Garcia-Vaquero et al, 2017 ; Trincone, 2018 ).…”

Section: Enzymes Modifying Macroalgae Polysaccharidesmentioning

confidence: 99%

“…The cell walls of marine red algae have a complex texture due to the content of cellulose, xylan, or mannan fibrils and matrix polysaccharides, including the economically important sulfated galactans such as carrageenan and agar used for the bioethanol production ( Table 1 and Figure 1 ). However, many of them need to be enzymatically pretreated before their use ( Synytsya et al, 2015 ; Abdallah et al, 2016 ; Trincone, 2018 ). The main storage polysaccharide in the brown seaweeds is laminarin formed by 1,3-β-glucans with β-1,6-branching and different reducing endings with mannitol or glucose residues ( Table 1 and Figure 1 ).…”

Section: Enzymes Modifying Macroalgae Polysaccharidesmentioning

confidence: 99%

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Biotechnology Potential of Marine Fungi Degrading Plant and Algae Polymeric Substrates

et al. 2018

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Filamentous fungi possess the metabolic capacity to degrade environment organic matter, much of which is the plant and algae material enriched with the cell wall carbohydrates and polyphenol complexes that frequently can be assimilated by only marine fungi. As the most renewable energy feedstock on the Earth, the plant or algae polymeric substrates induce an expression of microbial extracellular enzymes that catalyze their cleaving up to the component sugars. However, the question of what the marine fungi contributes to the plant and algae material biotransformation processes has yet to be highlighted sufficiently. In this review, we summarized the potential of marine fungi alternatively to terrestrial fungi to produce the biotechnologically valuable extracellular enzymes in response to the plant and macroalgae polymeric substrates as sources of carbon for their bioconversion used for industries and bioremediation.

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Update on Marine Carbohydrate Hydrolyzing Enzymes: Biotechnological Applications

Cited by 32 publications

References 116 publications

Effect of biosurfactant derived from Vibrio natriegens MK3 against Vibrio harveyi biofilm and virulence

Effect of biosurfactant derived from Vibrio natriegens MK3 against Vibrio harveyi biofilm and virulence

Pretreatment methods for lignocellulosic biofuels production: current advances, challenges and future prospects

Biotechnology Potential of Marine Fungi Degrading Plant and Algae Polymeric Substrates

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