γ-Linolenic acid production from Spirulina platensis

Various Spirulina strains were assayed for their productivity of -linolenic acid (Lnn). Spirulina platensis ARM-346 was found to accumulate large amounts of Lnn. Urea as a nitrogen source was found to be most effective giving a yield of 13.5 mg Lnn/g dry cell mass. With increase in temperature the Lnn content was found to increase along with biomass. The optimum temperature for maximum Lnn and biomass production was found to be 35°C. The Lnn content was highest at 0.06% (w/v) NaCl and 0.07% (w/v) K₂HPO₄. Cells cultivated in the orange region of the electromagnetic spectrum as energy source showed a high content of Lnn, and there was less biomass compared to cells grown in red light. When the culture was left in the dark for various times, after 144 h it contained about 26% more Lnn than in conventionally cultivated cells.     

Microbial production of poly-γ-glutamic acid

Poly-γ-glutamic acid (γ-PGA) is a natural, biodegradable and water-soluble biopolymer of glutamic acid. This review is focused on nonrecombinant microbial production of γ-PGA via fermentation processes. In view of its commercial importance, the emphasis is on l-glutamic acid independent producers (i.e. microorganisms that do not require feeding with the relatively expensive amino acid l-glutamic acid to produce γ-PGA), but glutamic acid dependent production is discussed for comparison. Strategies for improving production, reducing costs and using renewable feedstocks are discussed.     

Enzymatic production of α-dehydrobiotin from biotin

The enzymatic production of α-dehydrobiotin (α-DHB), an antibiotic, from biotinyl-CoA using acyl-CoA oxidase and from biotin using a coupling system of biotinyl-CoA synthetase and acyl-CoA oxidase was developed. Acyl-CoA oxidase was found to show activity for biotinyl-CoA. K_m and V_max values of acyl-CoA oxidase for biotinyl-CoA were 75 μM and 3.92 μmol min⁻¹ mg⁻¹, respectively. Optimum reaction conditions for the α-DHB production from biotin were examined. The maximum production of α-DHB (4.29 μmol ml⁻¹) was obtained, when the reaction was carried out at 30°C for 36 h in a mixture consisting of 100 mM potassium phosphate buffer (pH 8.0), 20 mM biotin, 20 mM ATP, 60 mM CoA, 20 mM MgCl₂, 2 units of biotinyl-CoA synthetase, 90 units of acyl-CoA oxidase and 25 units of catalase in a total volume of 0.6 ml under aerobic conditions. The product was purified from 14 ml of the reaction mixture and 10 mg of crystals with white needle form were obtained. From NMR, mass spectra and other physical analyses, this compound was identified as (+)-trans-α-DHB.     

Cyclic pollen production in Cedrus deodara

Based on a seven-year study of pollen production and release in two different natural populations of Cedrus deodara from Garhwal Himalaya, India, we determined that pollen output follows a two-year cycle. Pollen productivity determinations considered various sources of variability, including the number of pollen strobili per branch, strobili per tree, microsporophylls per tree and pollen grains per tree. Each of these parameters revealed significant year-to-year and population effects. Microsporangium dehiscence took from 2.5 to 3.5 days. Maximum dehiscence was observed between 12:00 and 14:00 h, which coincides with diurnal highest temperature and lowest relative humidity. Annual production of pollen per tree varied from averages of 4.7 × 10⁹, 7.2 × 10⁹ and 5.1 × 10⁹ in years of low production, with alternate high years, producing 12.6 × 10⁹, 14.1 × 10⁹, 13.3 × 10⁹ and 14.0 × 10⁹ pollen grains per tree. Annual pollen production in individual trees of C. deodara ranged from 1.4 × 10⁹ to 22.3 × 10⁹.     

Exploitation of Dunaliella for β-carotene production

Halotolerant microalga Dunaliella, which is exploited for the production of dried biomass or cell extract, is used as a medicinal food. With the advancement in this field in recent years, the production of bio-organic compounds such as β-carotene is established in many countries. Large-scale production of β-carotene is controlled by numerous stress factors like high light intensity, high salinity, temperature and availability of nutrients. The state-of-the-art strategies in industries in closed systems under new set of inductive factors will additionally promote the ease of commercial production of β-carotene. This review mainly focuses on the different methodologies employed recently for the optimum production of β-carotene from Dunaliella species.     

Trends in inulinase production – a review

This article highlights the research work carried out in the production of inulinases from various inulin substrates using strains of bacteria, yeast and fungi. Inulin is one of the numerous polysaccharides of plant origin that contains glucose or fructose. It is used as a substrate in industrial fermentation processes and in food industries due to its relatively cheap and abundant source for the microbiological production of high-fructose syrups, ethanol and acetone–butanol. The various oligosaccharides derived from inulin also find their application in the medical and dietary sector. The inulinase acts on the β-(2,1)-D-fructoside links in inulin releasing D-fructose. Hence, this article illustrates the capability of various microbes in hydrolyzing the carbon at its optimum nutrient concentration and operating condition towards inulinase production.     

Biotechnological production of acetylated thymosin β4

Thymosin β4 (43 aa) is a highly conserved acidic peptide, which regulates actin polymerization in mammalian cells by sequestering globular actin. Thymosin β4 is undergoing clinical trials as a drug for treatment of venous stasis ulcers, corneal wounds and injuries, as well as acute myocardial infarction. Currently, thymosin β4 is produced by a solid-phase chemical synthesis. Biotechnological synthesis of this peptide is difficult, because the N-terminal amino acid residue of thymosin β4 playing an essential role in the actin interaction is acetylated. In this study, we proposed a method for production of a thymosin β4 recombinant precursor and its directed chemical acetylation. Deacetylthymosin β4 was synthesized as a part of a hybrid protein containing thioredoxin and a specific TEV (tobacco etch virus) protease cleavage site. The following scheme was developed for purification of deacetylthymosin β4: (i) biosynthesis of a soluble hybrid protein (HP) in Escherichia coli, (ii) isolation of HP by ion exchange chromatography, (iii) cleavage of HP with TEV protease, and (iv) purification of deacetylthymosin β4 by ultrafiltration. N-Terminal acetylation of the serine residue of deacetylthymosin β4 was performed with acetic anhydride under acidic conditions (pH 3.0). The reaction yield was 55%. Thymosin β4 was finally purified by reverse-phase HPLC. The proposed method of isolation of recombinant thymosin β4 can be scaled-up and provide a highly purified preparation in a yield of 20 mg per 1 L of culture suitable for use in medical practice.     

Joint production of IL-22 participates in the initial phase of antigen-induced arthritis through IL-1β production

IntroductionRheumatoid arthritis (RA) is a chronic autoimmune disease characterized by neutrophil articular infiltration, joint pain and the progressive destruction of cartilage and bone. IL-22 is a key effector molecule that plays a critical role in autoimmune diseases. However, the function of IL-22 in the pathogenesis of RA remains controversial. In this study, we investigated the role of IL-22 in the early phase of antigen-induced arthritis (AIA) in mice.MethodsAIA was induced in C57BL/6, IL-22^−/−, ASC^−/− and IL-1R1^−/− immunized mice challenged intra-articularly with methylated bovine serum albumin (mBSA). Expression of IL-22 in synovial membranes was determined by RT-PCR. Articular hypernociception was evaluated using an electronic von Frey. Neutrophil recruitment and histopathological analyses were assessed in inflamed knee joint. Joint levels of inflammatory mediators and mBSA-specific IgG concentration in the serum were measured by ELISA.ResultsThe IL-22 mRNA expression and protein levels in synovial tissue were increased during the onset of AIA. In addition, pharmacological inhibition (anti-IL-22 antibody) and genetic deficiency (IL-22^−/− mice) reduced articular pain and neutrophil migration in arthritic mice. Consistent with these findings, recombinant IL-22 joint administration promoted articular inflammation per se in WT mice, restoring joint nociception and neutrophil infiltration in IL-22^−/− mice. Moreover, IL-22-deficient mice showed reduced synovitis (inflammatory cell influx) and lower joint IL-1β levels, whereas the production of IL-17, MCP-1/CCL2, and KC/CXCL1 and the humoral immune response were similar, compared with WT mice. Corroborating these results, the exogenous administration of IL-22 into the joints induced IL-1β production in WT mice and reestablished IL-1β production in IL-22^−/− mice challenged with mBSA. Additionally, IL-1R1^−/− mice showed attenuated inflammatory features induced by mBSA or IL-22 challenge. Articular nociception and neutrophil migration induced by IL-22 were also reduced in ASC^−/− mice.ConclusionsThese results suggest that IL-22 plays a pro-inflammatory/pathogenic role in the onset of AIA through an ASC-dependent stimulation of IL-1β production.

Electronic supplementary material

The online version of this article (doi:10.1186/s13075-015-0759-2) contains supplementary material, which is available to authorized users.     

Commercial production of β-glucuronidase (GUS): a model system for the production of proteins in plants

We have generated transgenic maize seed containing -glucuronidase(GUS) for commercial production. While many other investigators have demonstrated the expression of GUS as a scoreable marker, this is one of the first cases where a detailed characterization of the transgenic plants and the protein were performed which are necessary to use this as a commercial source of GUS. The recombinant -glucuronidase was expressed at levels up to 0.7% of water-soluble protein from populations of dry seed, representing one of the highest levels of heterologous proteins reported for maize. Southern blot analysis revealed that one copy of the gene was present in the transformant with the highest level of expression. In seeds, the majority of recombinant protein was present in the embryo, and subcellular localization indicated that the protein was dispersed throughout the cytoplasm. The purified recombinant -glucuronidase (GUS) was compared to native -glucuronidase using SDS-PAGE and western blot analysis. The molecular mass of both the recombinant and native enzymes was 68 000 Da. N-terminal amino acid sequence of the recombinant protein was similar to the sequence predicted from the cloned Escherichia coli gene except that the initial methionine was cleaved from the recombinant GUS. The recombinant and native GUS proteins had isoelectric points (pI) from 4.8 to 5.0. The purified proteins were stable for 30 min at 25, 37, and 50 ° C. Kinetic analysis of the recombinant and native GUS enzymes using 4-methylumbelliferyl glucuronide (MUG) as the substrate was performed. Scatchard analysis of these data demonstrated that the recombinant enzyme had a K_m of 0.20 mM and a V_max of 0.29 mM MUG per hour, and the native enzyme had a K_m and V_max of 0.21 mM and 0.22 mM/h respectively. Using D-saccharic acid 1,4-lactone, which is an inhibitor of -glucuronidase, the K_i of the native and recombinant enzymes was determined to be 0.13 mM. Thus, these data demonstrate that recombinant GUS is functionally equivalent to native GUS. We have demonstrated the expression of high levels of GUS can be maintained in stable germlines and have used an efficient recovery system where the final protein product, GUS, has been successfully purified. We describe one of the first model systems for the commercial production of a foreign protein which relies on plants as the bioreactor.     

Economics of baculovirus—insect cell production systems

Conclusions Commercial production of pharmaceutical proteins in baculovirus — insect cell systems is already a reality, and has therefore not been discussed in detail here. Cost-efficacy will depend on the productivity of the protein in culture, the dose, and the quantities required. According to the model described here, cost-effective production of baculoviruses for use in agriculture should also be feasible, assuming the commercial availability of a low-cost medium, together with a baculovirus with high productivity in cell culture, which is effective at a field application rate of 10¹² PIB ha^-1 or lower. All of these criteria appear to be achievable, given fairly modest advances over currently available technology. Given the relatively high fixed costs associated with production of baculoviruses on an agricultural scale in bioreactors however, profitability will depend on the scale of production. A substantial market opportunity (perhaps in the order of 1 million hectares) would be necessary in order to exploit the economies of scale achievable with baculovirus —insect cell production systems.     

Studies of Antarctic yeast for β-glucosidase production

Moss and lichen samples from the region of the Bulgarian base on Livingston Island, Antarctica were examined for the presence of yeasts. Six pure cultures were obtained. They were screened for -glucosidase production and two of them were selected. These were identified as Cryptococcus albidus AL₂ and C. albidus AL₃, according to their morphology, reproductive behaviour, and growth at different temperatures, salt concentrations, nutritional characteristics and various biochemical tests. These strains were examined for biosynthesis of -glucosidase on different carbon sources under aerobic conditions. High exocellular and endocellular activities were obtained when they were grown on cellobiose, methyl--D-glucopyranoside and salicin. The time course of growth and -glucosidase production of the yeast was examined by cultivation in a medium with cellobiose under aerobic conditions at temperatures 18 and 24 °C for 96 h. Cryptococcus albidus AL₂ and C. albidus AL₃ synthesized exocellular enzyme, respectively 58.33 and 55.83 U/ml and endocellular enzyme 137.75 and 205.34 U/ml at 24 °C for 72 h of the cultivation.     

Control of ��-amylase production by Bacillus subtilis

This study proposes two adaptive control algorithms for the fed-batch production of α-amylase. The first one uses online information from hardware measuring glucose. Online information of both biomass and glucose concentrations measured with different frequency is used in the second algorithm. Hardware measuring variables are inputs for software sensors of glucose concentration and (specific) glucose consumption rate. Either of the algorithms do not require any kinetic coefficients. This is a benefit, because the kinetic coefficients can vary during cultivation and between cultivations, leading to low process reproducibility and the non-stationary state of the bioprocess. The results of simulation investigations show good performance of the proposed control schemes.     

Strain selection for β-carotene production by Dunaliella

Four strains of Dunaliella were grown at 25°C and pH 8±0.5, with continous illumination at 200 W/m². Their maximum specific growth rates ranged from 0.093 day^-1 to 0.234 day^-1, nitrate yields from 3.0 to 7.8 g cells/g NaNO₃ and lipid contents from 3% to 6% of the dry wt, with carotenes 50 to 80% of the lipids. Of the carotenes, -carotene made up 7 to 19%; all-trans--carotene 32 to 52% and 9-cis--carotene 29 to 55%. There are, therefore, considerable intra-specific differences between strains of Dunaliella.     

α-Amylase and glucoamylase production by Schwanniomyces castellii

A chromogenic substrate (Cibachron blue-amylose), and soluble starch and maltose were used to characterize the amylolytic system from Schwanniomyces castellii 3754. The strain was able to produce inducible -amylase (EC 3.2.1.1) and glucoamylase (EC 3.2.1.3) when grown on different C sources. The effect of the C source was slightly different for -amylase and glucoamylase production. Melezitose, maltose and soluble starch enhanced both -amylase and glucoamylase synthesis to nearly the same extent; amylose, trehalose and cellobiose particularly induced -amylase synthesis. The optimal pH for the release of both amylases was 5.5–7.0; maximal -amylase synthesis, on the other hand, was observed in the medium buffered at pH 6.0. The optimal pH for -amylase and glucoamylase activity was in the range of 4.5–7.2 and 4.2–5.5, respectively. Temperatures allowing maximal activity were 45°C for -amylase and 45–52°C for glucoamylase; a rapid decline of both activities was observed just above these temperatures.The species Schwanniomyces castellii (together with Schw. alluvius) is now considered to be synonymous with Schw. occidentalis var. occidentalis (Kreger-Van Rij 1984).     

Does light inhibit ethylene production in leaves?

The effect of light on the rate of ethylene production was monitored using two different techniques—leaf segments incubated in closed flasks versus intact plants in a flow-through open system. Three different plants were used, viz sunflower (Helianthus annuus), tomato (Lycopersicon esculentum), and soybean (Glycine max). Experiments were conducted both in the presence and absence of 1-aminocyclopropane-1-carboxylic acid (ACC).

The results obtained indicate that, in all three species studied, light strongly inhibits ethylene production when cut leaf segments are incubated in the presence of ACC in closed flasks. When ethylene measurements are made with ACC-sprayed intact plants using a continuous flow system, the effect of light on ethylene production is only marginal. In leaf segments of sunflower and soybean incubated only in distilled H₂O in closed flasks, light promotes ethylene production. In tomato, there is no difference between the rate of ethylene production between light and darkness under such conditions. When measurements are made with intact plants in a continuous flow system, the rate of ethylene production is almost identical in light and darkness, in the three plants studied.

It is concluded that the effect of light on cut leaf segments incubated in the presence of ACC in closed flasks can be attributed to the techniques used for these measurements. Light has little effect on ethylene production by intact plants in an open system.

     

High-cell-density production of poly-β-hydroxybutyrate (PHB) from methanol by Methylobacterium extorquens: production of high-molecular-mass PHB

Methylobacterium extorquens ATCC 55366 was successfully cultivated at very high cell densities in a fed-batch fermentation system using methanol as a sole carbon and energy source and a completely minimal culture medium for the production of poly--hydroxybutyrate (PHB). Cell biomass levels were between 100 g/l and 115 g/l (dry weight) and cells contained between 40% and 46% PHB on a dry-weight basis. PHB with higher molecular mass values than previously reported for methylotrophic bacteria was obtained under certain conditions. Shake-flask and fermentor experiments showed the importance of adjusting the mineral composition of the medium for improved biomass production and higher growth rates. High-cell-density cultures were obtained without the need for oxygen-enriched air; once the oxygen transfer capacity of the fermentor was reached, methanol was thereafter added in proportion to the amount of available dissolved oxygen, thus preventing oxygen limitation. Controlling the methanol concentration at a very low level (less than 0.01 g/l), during the PHB production phase, led not only to prevention of oxygen limitation but also to the production of very high-molecular-mass PHB, in the 900–1800 kDa range. Biomass yields relative to the total methanol consumed were in the range 0.29–0.33 g/g, whereas PHB yields were in the range 0.09–0.12 g/g. During the active period of PHB synthesis, PHB yields relative to the total methanol consumed were between 0.2 g/g and 0.22 g/g. M. extorquens ATCC 55366 appears to be a promising organism for industrial PHB production.     

Cooperative pastoral production — the importance of kinship

While there is a general assumption that labour has a positive effect on pastoral production, studies that have quantified this relationship have been characterized by ambiguous results. This is most likely related to the fact that possible cooperative pastoral production has been little explored in the literature, although it is well documented that nomadic pastoralist households share and exchange labour in so-called cooperative herding groups. Consequently, this study aims at investigating possible cooperative labour-related effects on production among Saami reindeer herders in Norway by using kinship relations as a proxy for cooperation. This study found that cooperative labour investment is important for Saami reindeer herders, but that the effect of kinship and labour needs to be understood in relation to each other. When assessing the effect of labour and kinship simultaneously, both labour and genealogical relationship had positive effects on herd size. We also found a positive interaction between kinship and labour suggesting that high levels of relatedness coupled with a large potential labour pool had an increasingly positive effect on herd size.