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A novel alginate lyase, PsAly, with a molecular mass of 33 kDa and whose amino acid sequence shares no significant similarity to other known proteins, was biochemically and structurally characterised from Paenibacillus sp. str. FPU-7. The maximum PsAly activity was obtained at 65 °C, with an optimum pH of pH 7–7.5. The activity was enhanced by divalent cations, such as Mg 2+ , Mn 2+ , or Co 2+ , and inhibited by a metal chelator, ethylenediaminetetraacetic acid. The reaction products indicated that PsAly is an endolytic enzyme with a preference for polymannuronate. Herein, we report a detailed crystal structure of PsAly at a resolution of 0.89 Å, which possesses a β-helix fold that creates a long cleft. The catalytic site was different from that of other polysaccharide lyases. Site-directed mutational analysis of conserved residues predicted Tyr184 and Lys221 as catalytic residues, abstracting from the C5 proton and providing a proton to the glycoside bond, respectively. One cation was found to bind to the bottom of the cleft and neutralise the carboxy group of the substrate, decreasing the p K a of the C5 proton to promote catalysis. Our study provides an insight into the structural basis for the catalysis of alginate lyases and β-helix polysaccharide lyases.

Nanotechnology presents the new aspect of material as nanomaterials (NMs) with unique properties such as the large surface area to the volume ratio compared to bulk types. Metal and polymer nanoparticles (NPs) are two major groups of NMs with various medicinal and non-medicinal applications. The rise of antibiotic resistance in microorganisms in general, and bacteria in particular, has necessitated the use of these NMs as novel antibacterial agents. In this regard, medicinal usage of natural polymers particularly cellulose, chitosan, and alginic acid are increasing due to their higher biocompatibility, biodegradability, and accessibility than to other biopolymers or synthetic polymers. Antibacterial activities of these polysaccharides can be improved by incorporation of silver NPs as nanocomposite (NC) forms. Therefore, in this review, recent advances related to nanoformulations of silver NPs with three biopolymers having antibacterial and biocompatibility properties have been discussed.

Alginetin is the major product formed from pentoses and hexurionic acids. Alginetin is producted by cooking process of food including pection, a naturally-occurring polysacharride found in many plants. However, the biological interaction and toxicity of alginetin are not known at all. The aim of the present study was to investigate the cellular actions of alginetin on rat thymic lymphocytes. The effects of alginetin on the cell were examined using flow cytometry with fluorescent probes. Alginetin increased cellular content of non-protein thiols ([NPT]i) and elevated intracellular Zn2+ levels ([Zn2+]i). Chelation of intracellular Zn2+ reduced the effect of alginetin on [NPT]i, and chelation of external Zn2+ almost completely diminished alginetin-induced elevation of [Zn2+]i, indicating that alginetin treatment increased Zn2+ influx. Increased [NPT]i and [Zn2+]i levels in response to alginetin were positively correlated. Alginetin protected cells against oxidative stress induced by hydrogen peroxide and Ca2+ overload by calcium ionophore. It is considered that the increases in [NPT]i and [Zn2+]i are responsible for the cytoprotective activity of alginetin because NPT attenuates oxidative stress and Zn2+ competes with Ca2+. Alginetin may be produced during manufacturing of jam, which may provide additional health benefits of jam.

A hybrid gel is developed aiming to extend the storage period for cell preservation compared with an alginate gel. The introduction of poly(2‐oxazoline)s into alginic acid promises to improve functional materials by changing their functional groups (e.g., poly(2‐isopropyl‐2‐oxazoline) has the lower critical solution temperature behavior). This study demonstrates chemical modification of a carboxylate of sodium alginate by 1,3‐diaminopropane‐terminated poly(2‐oxazoline)s using 3‐ethylcarbodiimide hydrochloride (EDC) and N ‐hydroxy succinimide (NHS) as the condensation reagents for the aminations. The incorporated ratio of poly(2‐oxazoline)s side chains into the carboxylates estimated by 1 H NMR is ca. 5–12% and the remaining pendent carboxylates are used for gelation by adding calcium salts (CaCl 2 ). Gelation is observed within 30 min producing 93–99% gel fractions that swell in water. Similar gelation occurs in the cultivation medium of green‐fluorescence protein (GFP)‐encoded and COVID‐19 spike protein‐encoded DNA recombinant E.coli in both the absence and presence of isopropyl β‐D‐1‐thiogalactopyranoside (IPTG). Even in the presence of IPTG, fluorescence ascribed to GFP is not observed while the cells are kept at 25 °C for 3 weeks. After solvation by ethylenediaminetetraacetic acid (EDTA), fluorescence intensity at 508 nm is clearly observed and cell preservation at room temperature is thereby demonstrated.

ObjectivesBifunctional alginate lyase can efficiently saccharify alginate biomass and prepare functional oligosaccharides of alginate.ResultsA new BP-2 strain that produces alginate lyase was screened and identified from rotted Sargassum. A new alginate lyase, Alg17B, belonging to the polysaccharide lyase family 17, was isolated and purified from BP-2 fermentation broth by freeze-drying, dialysis, and ion exchange chromatography. The enzymatic properties of the purified lyase were investigated. The molecular weight of Alg17B was approximately 77 kDa, its optimum reaction temperature was 40–45 °C, and its optimum reaction pH was 7.5–8.0. The enzyme was relatively stable at pH 7.0–8.0, with a temperature range of 25–35 °C, and the specific activity of the purified enzyme reached 4036 U/mg. A low Na+ concentration stimulated Alg17B enzyme activity, but Ca2+, Zn2+, and other metal ions inhibited it. Substrate specificity analysis, thin-layer chromatography, and mass spectrometry showed that Alg17B is an alginate lyase that catalyses the hydrolysis of sodium alginate, polymannuronic acid (polyM) and polyguluronic acid to produce monosaccharides and low molecular weight oligosaccharides. Alg17B is also bifunctional, exhibiting both endolytic and exolytic activities toward alginate, and has a wide substrate utilization range with a preference for polyM.ConclusionsAlg17B can be used to saccharify the main carbohydrate, alginate, in the ethanolic production of brown algae fuel as well as in preparing and researching oligosaccharides.

Particulate matter (PM) is a significant participant in air pollution and is hence an inducer of serious health issues. This study aimed to evaluate the dust protective effects of alginate from Padina boryana (PBA) via inflammatory-associated pathways to develop anti-fine dust skincare products. In between the external and internal environments, the skin is considered to be more than a physical barrier. It was observed that PM stimulates inflammation in the skin via activating NF-κB and MAPK pathways. The potential of PBA to inhibit the studied pathways were evident. The metal ion content of PM was considerably reduced by PBA and thus attributed to its chelation ability. Current research demonstrated the potential of P. boryana alginates to be implemented as a protective barrier against inflammation imposed with heavy metal and bacterial-derived endotoxin bound to the surface of the PM. Concisely, the results suggest that the bioactive components derived from the brown algae Padina boryana increased the cellular resistance to PM-stimulated inflammation-driven skin damage.

This study investigated whether mixing low viscosity alginic acid with calcium phosphate cement (CPC) causes interconnected porosity in the CPC and enhances bone replacement by improving the biological interactions. Furthermore, we hypothesized that low viscosity alginic acid would shorten the setting time of CPC and improve its strength. CPC samples were prepared with 0, 5, 10, and 20% low viscosity alginic acid. After immersion in acetate buffer, possible porosification in CPC was monitored in vitro using scanning electron microscopy (SEM), and the setting times and compressive strengths were measured. In vivo study was conducted by placing CPC in a hole created on the femur of New Zealand white rabbit. Microcomputed tomography and histological examination were performed 6 weeks after implantation. SEM images confirmed that alginic acid enhanced the porosity of CPC compared to the control, and the setting time and compressive strength also improved. When incorporating a maximum amount of alginic acid, the new bone mass was significantly higher than the control group (P = 0.0153). These biological responses are promising for the translation of these biomaterials and their commercialization for clinic applications.

The adult male albino rats were grouped into five groups (control group and four variably treated groups with thorium (Th) in single or successive with or without alginate treatment). The IP administration of thorium nitrate (13.6 mg/kg b.wt.) induced a regional distribution and accumulation ordered as cerebellum > cerebral cortex > brain stem > hippocampus > hypothalamus > striatum. Also, it induces a significant increase in Na+, Ca2+, and Fe3+ ion content and malondialdehyde (MDA) level while K+ ions and glutathione (GSH) level were significantly decreased. On the other hand, the daily oral administration of 5% alginate showed a significant decreasing in the accumulation of thorium in the different brain areas and mitigated its hazardous effects. By the alginate treatment, Na+, Ca2+, Fe3+, and level of MDA were declined while K+ ions and GSH level showed a significant increase. The improvement of the investigated parameters was attributed to the specific chelating, regeneration, and antioxidant properties of the alginate. So, alginate administration could ameliorate the hazardous effects of thorium nitrate.

The density functional theory method using the B3LYP/6-31G(d,p) level of theory was used to perform isoenergetic maps in order to determine the lower energy conformers of four disaccharides constituting alginic acids, which are based on β-D-mannuronic (M) and α-L-guluronic acid (G), called MM, GG, MG, and GM. The preferred structures are combined to monovalent (Li + , Na + , and K + ) cations and further fully optimized, and an isoenergetic map corresponding to the complex (MG 2− , 2Na + ) was performed. Then, the reactivity of MG complexes with mono- and bivalent cations was studied using the global nucleophilic index. The position selectivity was also predicted using the local nucleophilic indices. It was demonstrated that experimental trends of relative reactivity and regioselectivity of the complexes are correctly predicted using these empirical indices of reactivity. Graphical abstract MM, GG, MG, and GM alginic acid disaccharides and reactivity of the MG metallic complexes

Alum and other inorganic coagulants have been in use for water treatment since time immemorial. However, exposure to the consecutive metal ions results in chronic effects, the well known of which is Alzheimer’s disease. Alternatives to these coagulants are biopolymer based graft copolymer as flocculant. They are required in minute dosage, non-toxic and are eco-friendly. In this study, alginic acid based graft copolymers have been synthesized via conventional and microwave based technique. Molecular characterization of synthesized graft copolymers have been carried out via standard physicochemical techniques. A comparative investigation of flocculation performance of alginic acid derivatives [synthesized by both the methods i.e., Alg-g-PAM(C) and Alg-g-PAM(M)] and coagulation efficacy of alum has been accomplished in various model suspensions via standard jar test procedure. As anticipated, the flocculation efficacy of Alg-g-PAM(M) has been found much higher than that of Alg-g-PAM(C). Further, the synthesized derivatives exhibited excellent capability in reduction of pollutant load including toxic metal ions removal from wastewater.