BIODEGRADABLE PLASTIC PRODUCTION FROM POLYHYDROXYBUTYRATE(PHB) PRODUCING BACTERIA AND ITS IMPACT ON ENVIRONMENT.

Plastic materials have been used in various ways such as packaging material, glass wares, certain parts of instruments of various grades, many more. As plastic products are not easily decomposed and accumulate in environment. This has created an adverse effect on our ecosystem. Bioplastics are best alternative to overcome these issues and reduce damages in ecosystem. Bioplastics are easily and speedily degrade under natural environmental conditions. Polyhydroxybutyrate or PHB is a bioplastic, one of the best natural polymer and alternative of synthetic plastic material. Bioplastic are comparative more flexible to convert into various forms also. Normally, it is a lipid reserve material produce in adverse or under stress conditions and stored within the cell wall of micro-organisms. Poly-3-hydroxybutyrate (PHB) is a natural biopolymer produce by wide range of microbes which is a storage granule used by microbes as an energy as well as carbon source.this microbes includes from extremophiles to mesophiles. The objective of our work was to isolate potential PHB producing bacteria using agro-residues as carbon sources within natural environment conditions. This work describes the understanding of microbes that are involved in the degradation of both natural and synthetic polymers.Also to contribute in green environment by providing eco- friendly product.

BIODEGRADABLE PLASTIC (PHB) FROM BACTERIA COLLECTED FROM GOPALPUR BEACH, BHUBANESWAR

Objective: Environmental concerns have prompted research into the development of biodegradable polymer as an alternative to petroleum-based plastics. Polyhydroxybutyrates (PHBs) are good alternatives to produce biodegradable plastics. Some bacteria are found to be producing PHB. The aim of this work was to isolate potential PHB producing bacteria and screen them for their ability to produce PHB. Methods: Contaminated water sample from Gopalpur beach, Bhubaneswar was the source of bacteria. Three colonies were isolated from the water sample. The samples were named as C1, C2 and C3. The colonies were first identified by colony morphology. The sudan black screening test was done to screen for the production of (PHB) polyhydroxy butyrate by bacterial isolates. Results: The bacterial isolates C1 and C2 showed a positive result for the production of polyhydroxy butyrate (PHB). Presence of PHB granules in Cocobacillus and Rod shaped bacillus was confirmed. Conclusion: Polyhydroxybutyrate (PHB), a kind of microbial polyester that accumulates as a carbon/energy reserve material in various microorganisms, was thus concluded to be a decent alternative for plastics. Because of their special characteristics and broad biological applications, biodegradable plastics are compounds with a promising future.

Contractual procurement alternatives of air force contingency pharmaceuticals: a cost-benefit analysis

Purpose This paper aims to explore effective supply chain principles, through the theory of transaction cost economics, as measures to improve current contingency pharmaceutical item shortfalls in the Air Force Medical Service (AFMS) Contingency Pharmaceutical Programme. Design/methodology/approach In this research, AFMS contingency pharmaceutical data was collected from various databases, including the Joint Medical Asset Repository, Medical Contingency Requirements Workflow and the Medical Requirements List. Through the methodology of cost-benefit analysis, alternative sourcing and fulfilment practices are evaluated. Findings The findings of this research indicate that the application of centralized purchasing principles, in an effort to leverage prime vendor contract fill rates for shortage items, can lead to 12%–17% increases in pharmaceutical material availability across the programme. Originality/value This research clearly shows that consolidating demand for shortage items across Active Duty War Reserve Material assemblages, though applications of centralized purchasing principles that leverage prime vendor contract fill rates, can lead to substantial increases in material availability at costs that justify the calculated benefits.

Screenning and determination of polyhydroxyalkanoate production by Bacillus sp. strains

Polyhydroxyalkanoates (PHAs) are biodegradable polymers produced by microbes as reserve material when they were cultured in a limitation of nutrients and excess C source mediums. PHAs can be synthesized by various bacteria including gram positive and gram-negative bacteria. Among the PHA-producing gram-positive bacteria, Bacillus sp. produce and accumulate various monomer compositions of PHAs. In this study, about 83,3% of strains (05/06 strains) can accumulate PHAs production. Bacillus sp. DV01 accumulated a amount of PHA 23,9% of CWD after 96h when cultured in modified basal medium containing 1% (w/v) glucose. Bacillus sp.  DV01 was identified by sequecing the gene coding for 16S rRNA. BLAST results showed the obtained 16S rRNA sequence of this strain revealed 100% with the Bacillus megaterium and so-called Bacillus megaterium DV01.

Thauera aminoaromatica MZ1T Identified as a Polyhydroxyalkanoate-Producing Bacterium within a Mixed Microbial Consortium

Polyhydroxyalkanoates (PHAs) form a highly promising class of bioplastics for the transition from fossil fuel-based plastics to bio-renewable and biodegradable plastics. Mixed microbial consortia (MMC) are known to be able to produce PHAs from organic waste streams. Knowledge of key-microbes and their characteristics in PHA-producing consortia is necessary for further process optimization and direction towards synthesis of specific types of PHAs. In this study, a PHA-producing mixed microbial consortium (MMC) from an industrial pilot plant was characterized and further enriched on acetate in a laboratory-scale selector with a working volume of 5 L. 16S-rDNA microbiological population analysis of both the industrial pilot plant and the 5 L selector revealed that the most dominant species within the population is Thauera aminoaromatica MZ1T, a Gram-negative beta-proteobacterium belonging to the order of the Rhodocyclales. The relative abundance of this Thauera species increased from 24 to 40% after two months of enrichment in the selector-system, indicating a competitive advantage, possibly due to the storage of a reserve material such as PHA. First experiments with T. aminoaromatica MZ1T showed multiple intracellular granules when grown in pure culture on a growth medium with a C:N ratio of 10:1 and acetate as a carbon source. Nuclear magnetic resonance (NMR) analyses upon extraction of PHA from the pure culture confirmed polyhydroxybutyrate production by T. aminoaromatica MZ1T.

Ultrastructure of the midgut epithelium in three species of Macrobiotidae (Tardigrada: Eutardigrada: Parachela)

Three species of Macrobiotidae, Macrobiotus polonicus, Macrobiotus diversus and Macrobiotus pallarii, were selected for analysis of the fine structure of the midgut epithelium. They are gonochoric and carnivorous species that live in wet terrestrial and freshwater environments. The ultrastructure of the midgut epithelium of the investigated Macrobiotidae species was analysed in both males and females. Their digestive system is composed of fore- and hindguts that are covered by a cuticle, and the middle region, termed the midgut. It is lined with a simple epithelium that is formed by digestive cells that have a distinct brush border. Crescent-shaped cells that form an anterior ring in the border between the fore- and midgut were detected. The ultrastructure of the intestinal epithelium of the examined species differs slightly depending on sex. The digestive cells of the posterior segment of the intestine contain numerous lipid droplets, which are the reserve material. We concluded that the digestive cells of the Macrobiotidae midgut are responsible for its intracellular digestion owing to endocytosis. They also participate in the extracellular digestion owing to merocrine secretion (exocytosis). However, the midgut is not the main organ that accumulates reserve material. Additionally, the midgut epithelium does not participate in oogenesis.

Autophagy and apoptosis in starved and refed Neocaridina davidi (Crustacea, Malacostraca) midgut

Adult specimens of the freshwater shrimp Neocaridina davidi Bouvier, 1904 (Crustacea) were starved for 7, 14, and 21 days. Specimens from the first and second experimental group were collected for the studies. The majority of animals starved for 21 days died. Additionally, some specimens from each group were refed for 4, 7, and 14 days. The epithelium of the midgut, which is composed of the intestine and hepatopancreas, was analyzed. While the epithelium of the intestine is formed by D- and R-cells, the epithelium of the hepatopancreas has R-, B-, and F-cells. Autophagy and apoptosis in the midgut epithelium were analyzed using transmission electron microscopy and immunohistochemical methods. These processes were only observed in the D-cells of the intestine and the F- and B-cells of the hepatopancreas. Starvation led to a reduction in the amount of reserve material in the B-cells. Although this process activated autophagy in both regions of the midgut, the intestine and hepatopancreas, after refeeding, the level of autophagy decreased. Starvation caused an increase in the apoptotic cells in both organs, while the refeeding caused a decrease in the number of apoptotic cells in both organs analyzed. Refeeding after periods of starvation caused an accumulation of reserve material in the hepatopancreas.

Inhibition of raffinose family oligosaccharides and galactosyl pinitols breakdown delays germination of winter vetch (Vicia villosa Roth.) seeds

Beside RFOs, which are commonly present in legume seeds, seeds of some species contain galactosyl pinitols (GPs). These carbohydrates, like RFOs, have been hypothesized to constitute an important energy and carbon skeletal source during germination. To test this hypothesis we have applied a specific α-galactosidase inhibitor (1-deoxygalactonojirimycin, DGJ) to germinating winter vetch (<em>Vicia villosa</em> Roth.) seeds, containing more galactosyl pinitols than RFOs. The breakdown of RFOs but not that of GPs was completely blocked in both embryonic axes and cotyledons tissues, during the first 18 h of imbibition in DGJ. The inhibitor only decreased the rate of GPs degradation. The inhibitory effect of DGJ on GPs degradation was partially alleviated by addition of sucrose or galactose to DGJ solutions. After three days of germination in water, RFOs and GPs disappeared in axial tissues of seeds imbibed in water, galactose or sucrose. Eighteen-hour imbibition of seeds in DGJ drastically reduced germination, by ca 50%, during the first three days. The inhibitory effect of DGJ decreased during the next seven days of germination. The presence of galactose or sucrose in imbibition solution initially stimulated seed germination, but later this effect was not statistically significant. Our study provides clear evidence that galactosyl pinitols play an important role in early winter vetch seeds germination. Additionally, we suggest that galactosyl pinitols can replace RFOs as reserve material necessary for early germination.

Cyanophycin Synthetase-Like Enzymes of Non-Cyanobacterial Eubacteria: Characterization of the Polymer Produced by a Recombinant Synthetase of Desulfitobacterium hafniense

Some bacterial genomes were found to contain genes encoding putative proteins with considerable sequence homology to cyanophycin synthetase CphA of cyanobacteria. Such a gene from the Gram-positive, spore-forming anaerobe Desulfitobacterium hafniense was cloned. Expression in Escherichia coli resulted in the formation of a polydispers copolymer of aspartic acid and arginine, with a minor amount of lysine, of about 30 kDa molecular mass. In contrast to cyanophycin, this polymer was water-soluble. The structure of the polymer formed by the synthetase from Desulfitobacterium hafniense was studied by enzymatic degradation with the cyanophycin-specific hydrolase cyanophycinase, and by chemical and mass-spectroscopic analyses. Despite of the differences in solubility, indicating that both polymers cannot be completely identical, the chemical structure was found to be very similar to that of cyanophycin. The results suggest that the use of cyanophycin-like polymers as a nitrogen- rich reserve material is not restricted to cyanobacteria, and that such polymers may not necessarily be stored in granules.