Production and downstream processing of (1→3)-β-D-glucan from mutant strain of Agrobacterium sp . ATCC 31750
TL;DR: A mutant that produced higher levels of curdlan than the wild strain Agrobacterium sp.
Abstract: We isolated a mutant that produced higher levels of curdlan than the wild strain Agrobacterium sp. ATCC 31750 by chemical mutagenesis using N-methyl-N-nitro-nitrosoguanidine. The mutant strain produced 66 g/L of curdlan in 120 h with a yield of (0.88) while, the wild strain produced 41 g/L in 120 h with a yield of (0.62) in a stirred bioreactor. The mutant could not produce curdlan when the pH was shifted from 7.0 to 5.5 after nitrogen depletion as followed for wild strain. In contrast, pH optimum for cell growth and curdlan production for mutant was found to be 7.0. We optimized the downstream processing of curdlan by varying different volumes of NaOH and HCl for extraction and precipitation of curdlan. The molecular weight of the purified curdlan from the wild and mutant strain was 6.6 × 105 Da and 5.8 × 105 Da respectively. The monosaccharide analyses confirm that curdlan from both wild and mutant strain contains only glucose units. From the NMR and FTIR data, it has been confirmed that curdlan was exclusively composed of β (1 → 3)-D-glucan residues.
Citations
More filters
TL;DR: In this article, the potential of various microorganisms such as Saccharomyces cerevisiae, Aspergillus oryzae, Xanthomonas campestris, and Bacillus natto in producing β-glucan was discovered.
11 citations
Cites background from "Production and downstream processin..."
...The yield of b-glucans produced by bacteria, in general, has been reported to be approximately 6–7% (Kalyanasundaram et al., 2012)....
[...]
...Some studies report that the optimal pH range for b-glucan production by bacteria is 5.5–7.0 (Kalyanasundaram et al., 2012)....
[...]
TL;DR: A comprehensive review of various wastes obtained from the agri-food processing industry and plant biomass used in the production of glucan-based biopolymers is presented in this paper.
Abstract: Agro-industrial wastes and lignocellulosic biomass represents plentiful renewable carbon-based resources in the environment. An increasing interest has been shown by the researchers to utilize agri-food processing wastes and lignocellulosic biomass for production of value-added substances and biochemicals. Glucans are known as a biopolymeric chemical which is derived from D-glucose with valuable medical applications. Glucans could be extracted from different organisms including plants, fungi, bacteria and algae. In this context, agricultural and food processing wastes as well as lignocellulosic biomass have been known as low-cost feedstocks for production of glucan polymers. Hence, in this review, firstly an overview of the current glucan-derived sources including plant and microbial sources is given. Subsequently, a comprehensive review of various wastes obtained from the agri-food processing industry and plant biomass used in the production of glucan-based biopolymers is presented with providing the comparison of different sources used for the production of glucan polymer. Finally, the production of glucan polymer from agri-food processing wastes is evaluated in aspect of biorefinery.
10 citations
TL;DR: The authors describe Glucans as biopolymers made up of repeating units of D-glucose and are of biological origin with varying molecular weights with varying linkage, chemical structure, branching and subsumption.
Abstract: Glucans are biopolymers made up of repeating units of D-glucose and are of biological origin with varying molecular weights. The differences in their linkage, chemical structure, branching and subs...
10 citations
01 Jan 2015
TL;DR: This chapter briefly gives an introduction to PHA and provides recent developments in the genetic and metabolic pathways for the synthesis of microbial EPS, and possible ways to minimize the cost of production and downstream processing are covered.
Abstract: Microorganisms produce several biopolymers. Of these, intracellularly produced polyhydroxyalkanoates (PHAs) and extracellularly produced exopolysaccharides (EPS) are gaining importance over the other biopolymers. These naturally produced polymers can replace plant-based or petroleum-derived polymers. There are innumerable reports and reviews on the production of PHA and EPS by several bacteria, fungi, actinomycetes, and algae. This chapter briefly gives an introduction to PHA and provides recent developments in the genetic and metabolic pathways for the synthesis of microbial EPS. Different strategies used for fermentative production and various means of downstream processing are discussed. Possible ways to minimize the cost of production and downstream processing are covered in this chapter. Applications of these EPS in various fields such as agriculture, cosmetics, foods, medical and healthcare industry, mining, oil recovery, packaging, pharmaceuticals, printing and textile industry, wastewater treatment, etc., are presented. The potential of these polymers indicates that these microbial cell factories can be exploited for the better of mankind.
9 citations
TL;DR: It is strikingly observed that a surfactant exopolysaccharide of Ochrobactrum pseudintermedium C1 possesses a potent antibacterial property which encourages its bio-medical applications and might play a significant role in bio-medicine to combat such threat of antibiotic resistance.
9 citations
References
More filters
25,389 citations
"Production and downstream processin..." refers methods in this paper
...The absorbance was measured at 540 nm and the sucrose concentration was determined (Miller 1959)....
[...]
7,125 citations
01 Jan 1979
TL;DR: The method described in this paper has the greatest sensitivity, being able to demonstrate the presence of 0.10 μg of phosphorus per ml. It is based on the reduction of phosphomolybdate complex with ascorbic acid, and is essentially identical to the method published by Chen, Toribara and Warner (1956).
Abstract: Several different procedures are recommended for the determination of total phosphorus in biologic samples. The method described here has the greatest sensitivity, being able to demonstrate the presence of 0.10 μg phosphorus per ml. It is based on the reduction of phosphomolybdate complex with ascorbic acid. The procedure described here is essentially identical to the method published by Chen, Toribara and Warner (1956).
538 citations
"Production and downstream processin..." refers methods in this paper
...Phosphate concentration was determined with the ascorbic acid method (Chen et al. 1956)....
[...]
TL;DR: While almost all this non-structural data has accumulated from the study of Gram negative species, this background information provides a sound basis from which polysaccharides from Gram positive bacteria can now be developed.
344 citations
"Production and downstream processin..." refers background in this paper
...Sometime mutations could interfere with this process and might lead to internalisation of the polysaccharide (Sutherland 2001)....
[...]