Bioprospecting of Microorganism-Based Industrial Molecules. Группа авторов

Bioprospecting of Microorganism-Based Industrial Molecules - Группа авторов


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rel="nofollow" href="#ulink_b45bf29a-a882-5f39-ae81-422773d1c192">Table 3.1 Microbial gums and their producer organisms.

Microbial gum Microorganism Monosaccharides present Linkages present References
Xanthan gum Xanthomonas campestris Glucose, mannose, and glucoronic acid (2:2:1) β‐(1,4), β‐(1,2), and α‐(1,3) [14]
Gellan gum Sphingomonas elodea, Sphingomonas paucimobilis ATCC 31461 D‐glucose, D‐glucoronic acid, and l‐rhamnose (2:1:1) β‐(1,3), β‐(1,4), and α‐(1,4) [20]
Welan gum Sphingomonas spp ATCC 31555 L‐mannose, L‐rhamnose, D‐glucose, and D‐glucuronic acid (1.0:4.5:3.1:2.3) β‐(1,3), β‐(1,4), and α‐(1,4) [3]
Rhamsan gum Sphingomonas spp. RH‐1 D‐glucose, D‐glucoronic acid and L‐rhamnose β‐(1,3), β‐(1,4), β‐(1,6), and α‐(1,4) [21]
Diutan gum Sphingomonas sp. ATCC 53159 D‐glucose, D‐glucoronic acid, and L‐rhamnose β‐(1,3), β‐(1,4), and α‐(1,4) [22]
Pullulan Aureobasidium pullulans Eurotium chevalieri, Cryphonectria parasitica, Cyttaria darwinii, and yeast Rhodotorula baracum D‐glucose α‐(1,6) and α‐(1,4) [5, 23]
Scleroglucan Sclerotium glucanicum D‐glucose β‐(1,3) and β‐(1,6) [24]
Curdlan Alcaligenes faecalis D‐glucose β‐(1,3) and β‐(1,6) [6]
Levan Bacillus subtilis, Bacillus polymyxa, Aerobacter levanicum, Leuconostoc mesenteroides, Streptococcus sp., Pseudomonas sp., and Corynebacterium laevaniformans. D‐fructose β‐(2,6) and β‐(2,1) [12]
Dextran Various LAB genera‐like Leuconostoc, Lactobacillus, Streptococcus, Pediococcus, and Weissella D‐glucose α‐(1,6), α‐(1,2), α‐(1,3) and α‐(1,4) [25, 26]

      3.5.1 Xanthan Gum

      Xanthan is a microbial gum produced by Xanthomonas campestris, a plant pathogenic bacteria. The molecular weight of xanthan, in general, can be 2000 kDa, but can also reach a higher weight of up to 50 000 kDa. Xanthan is a HePS and is composed of three different monosaccharides: glucose, mannose, and glucoronic acid in the molar ratio of 2:2:1 along with O‐acetyl and pyruvate groups [14]. Xanthan gum is resistant to degradation by enzymes and is highly pseudoplastic in nature, and it can maintain its viscosity over a wide range of temperatures and pH. In the presence of high shear stress, the xanthan gum viscosity is reduced but is recovered immediately upon the removal of the stress. This phenomenon occurs in xanthan due to the formation of intermolecular aggregates and polymer entanglement when mixed with water [27].

      Xanthan gum is a highly efficient food hydrocolloid, emulsifier, and stabilizer, which is commonly used in the food industry. It is nontoxic in nature and is used as a natural food additive. The United States Food and Drug Administration (FDA) and European Economic Community have approved the use of xanthan gum as a safe food additive in 1984 and 1980, respectively [28]. After the approval of xanthan gum from X. campestris as a food additive, the demand for it has seen a steady rise at a rate of 5–10% annually [11]. In many scenarios, xanthan gum is mixed with plant‐based gum, guar gum, to obtain solutions of even higher viscosity than that from either one gum when used alone [29]. Xanthan gum has been reported to act as a prebiotic for dairy‐based lactic acid bacteria by improving bacterial viability under low pH, refrigeration, and the presence of bile salts [30]. Xanthan gum acts as a low‐calorie food hydrocolloid, as well as a fat replacer in various fat‐rich foods such as salad dressing, mayonnaise, ice creams, and cakes. The mixture of xanthan gum and guar gum had been reported to improve the crip and porous characteristics of deep‐fried foods when they were incorporated into the batter mix [29].

      3.5.2 Sphingans

      3.5.2.1 Gellan Gum

Schematic illustration of the structures of different sphingans.