Biofloc Technology: Emerging Microbial Biotechnology for the Improvement of Aquaculture Productivity

With the significant increases in the human population, global aquaculture has undergone a great increase during the last decade. The management of optimum conditions for fish production, which are entirely based on the physicochemical and biological qualities of water, plays a vital role in the prompt aquaculture growth. Therefore, focusing on research that highlights the understanding of water quality and breeding systems’ stability is very important. The biofloc technology (BFT) is a system that maximizes aquaculture productivity by using microbial biotechnology to increase the efficacy and utilization of fish feeds, where toxic materials such as nitrogen components are treated and converted to a useful product, like a protein for using as supplementary feeds to the fish and crustaceans. Thus, biofloc is an excellent technology used to develop the aquaculture system under limited or zero water exchange with high fish stocking density, strong aeration, and biota. This review is highlighted on biofloc composition and mechanism of system work, especially the optimization of water quality and treatment of ammonium wastes. In addition, the advantages and disadvantages of the BFT system have been explained. Finally, the importance of contemporary research on biofloc systems as a figure of microbial biotechnology has been emphasized with arguments for developing this system for better production of aquaculture with limited natural resources of water.Key words: biofloc, BFT, aquaculture, microbes, water quality, wastes     

A subpopulation of cultured avian neural crest cells has transient neurogenic potential

Neural crest cells of vertebrate embryos produce neurons, glia, pigment cells, and connective tissue in vivo and in vitro. To test the developmental potential of apparently undifferentiated crest cells, we have used the monoclonal antibody A2B5, which recognizes a cell surface glycolipid characteristic of neurons, to identify and immunoablate a subpopulation of cultured avian neural crest cells with a neuronal phenotype. Our results indicate that a limited neurogenic precursor subpopulation is present in cultures of avian neural crest cells and that the fate of this subpopulation can be influenced by environmental conditions arising when dispersal of neural crest cells is delayed.     

Weed and Crop Allelopathy

Allelopathy can be defined as an important mechanism of plant interference mediated by the addition of plant-produced secondary products to the soil rhizosphere. Allelochemicals are present in all types of plants and tissues and are released into the soil rhizosphere by a variety of mechanisms, including decomposition of residues, volatilization, and root exudation. Allelochemical structures and modes of action are diverse and may offer potential for the development of future herbicides. We have focused our review on a variety of weed and crop species that establish some form of potent allelopathic interference, either with other crops or weeds, in agricultural settings, in the managed landscape, or in naturalized settings. Recent research suggests that allelopathic properties can render one species more invasive to native species and thus potentially detrimental to both agricultural and naturalized settings. In contrast, allelopathic crops offer strong potential for the development of cultivars that are more highly weed suppressive in managed settings. Both environmental and genotypic effects impact allelochemical production and release over time. A new challenge that exists for future plant scientists is to generate additional information on allelochemical mechanisms of release, selectivity and persistence, mode of action, and genetic regulation. In this manner, we can further protect plant biodiversity and enhance weed management strategies in a variety of ecosystems. Referee: Dr. Steve Weller, Purdue University, Dept. of Horticulture, West Lafayette, IN 47907     

Molecular characterization of Pseudomonas aeruginosa 2NR degrading naphthalene

Three naphthalene-degrading strains were isolated from compost, characterized by morphological and physiological properties and differentiated by 16S rDNA RFLP. During growth on naphthalene, Pseudomonas aeruginosa 2NR produced ortho catechol pathway intermediates and gentisic acid. The ability to accumulate and degrade gentisic acid shows that Ps. aeruginosa 2NR has a different salicylate pathway to that of the intensely studied Ps. putida NCIB 9816. Molecular analysis showed the presence both of genes of the upper naphthalene pathway and genes of the ortho and meta catechol pathways. The insertion of nagH and nagG, coding for salicylate 5-hydroxylase in Pseudomonas sp. U2, was absent in Ps. aeruginosa 2NR, as in Ps. putida NCIMB 9816.     

Sucrose absorption and synthesis by excised Lycopersicon esculentum roots

Asymmetrically-labelled sucrose was absorbed intact by excised roots of tomato, grown in sucrose. Glucose-grown roots possessed sucrose synthetase and sucrose phosphate synthetase activity.