酶解破壁促进废次烟叶中茄尼醇溶浸

协同应用纤维素酶和木质素酶催化降解废次烟叶,探讨清洁高效的酶解破壁效应及浸提茄尼醇工艺条件。结果发现复配酶催化裂解溶浸茄尼醇效果明显优于单一酶,酶解时间、温度、pH值以及酶投加量等条件均影响酶破壁浸提茄尼醇能效。结果表明,采用纤维素酶：木质素酶酶活比15∶1 (U/U) 的复配酶,在体积为5倍烟草质量的水介质环境中,当复配酶投加量为175 U/g,水浴温度40 ℃,pH=6时,催化酶解烟叶8 h后,茄尼醇溶浸浓度可达0.33 g/L。在此条件下,茄尼醇平均提取率可达96.53％,是化学回流浸提方法的1.68倍。该方法为有效提取废次烟草中茄尼醇提供了一种新途径。     

Selective Recovery of Carbohydrates from Aqueous Solution Facilitated by a Carrier

Carbohydrate recovery is an active area of supramolecular chemistry, motivated by the biological importance of saccharides as well as the unusual challenge presented by these complex substances. The recovery of carbohydrates from aqueous media is a difficult separation problem due to the large, irregular and multivalent structure and the low solubility of carbohydrates in organic solvents. A method for the selective recovery of mono‐ and disaccharides from aqueous media has been developed. The use of different organic solvents like butanol, methyl tertiary‐butyl ether (MTBE), n‐hexane or toluene for liquid‐liquid extraction of carbohydrates was investigated. This extraction process is facilitated by a carrier, i.e., primary amines such as cyclooctylamine. The influence of different parameters (temperature, amine concentration, extraction time) on the efficiency of the extraction was studied. Recovery rates up to 40 % are possible in a one‐stage process. Selectivities range from 1.3 up to 875.4.     

Properties of natural cellulose fibers from hop stems

This paper reports the development of natural cellulose fibers from hop stems with properties similar to that of hemp. Hop stems are currently considered as byproducts and have limited applications. Since hop belongs to the genus cannabis that also includes hemp, it should be possible to obtain natural cellulose fibers from the stems of hop plants with properties similar to that of hemp. A simple alkaline extraction was used to obtain fibers from the bark of hop stems. Fibers obtained have high cellulose content, low% crystallinity but show good orientation of the cellulose crystals to the fiber axis. The strength and modulus of the fibers are lower but elongation is higher than that of hemp. Based on the properties of the fibers, we expect that the hop stem fibers will be suitable for use in textiles and composites similar to the common cellulose fibers currently in use.     

Algae as production systems of bioactive compounds

Algal extracts are gaining increasing interest due to their unique composition and possibilities of wide industrial applications. Various extraction techniques are used for conversion of algal biomass into extracts. Recently, attention of scientists has been paid to novel methods, such as enzyme‐assisted extraction, microwave‐assisted extraction, pressurized liquid extraction, supercritical fluid extraction, and ultrasound‐assisted extraction, which enable the extraction of biologically active compounds without their degradation. In this review, the properties of biologically active compounds extracted from the biomass of algae reported in the literature are presented in a structured way. Algal extracts contain compounds such as carbohydrates, proteins, minerals, oil, fats, polyunsaturated fatty acids as well as bioactive compounds such as antioxidants (polyphenols, tocopherols [vitamin E], vitamin C, mycosporine‐like amino acids), and pigments, such as carotenoids (carotene xanthophyll), chlorophylls, and phycobilins (phycocyanin, phycoerythrin), which possess antibacterial, antiviral, antifungal, antioxidative, anti‐inflammatory, and antitumor properties. Finally, we assemble a list of applications of algal extracts in different developing branches of agriculture (biostimulants, bioregulators, feed additives) and in pharmaceutical industry.     

Cover as a simple predictor of biomass for two shrubs in Tibet

Knowledge of the quantitative relationship between plant cover and its corresponding biomass for shrubs is not well known, especially for those on the Tibetan Plateau. Based on investigations of 35 sites, 90 plots and 95 standard individuals for two typical shrub species (Rhododendron nivale Hook. f. and Sophora moorcroftiana (Benth.) Baker) across Tibet, we developed allometric models for biomass estimation from measurements of crown diameter and/or height. We found that the parameters of crown projection area (CPA), height and their product (volume) were all significantly (p < 0.01) correlated with dry mass of different organs for both species at individual level. The CPA rather than volume best predicted aboveground dry mass. This is because that the bulk density declined significantly with increasing plant height, leading to the inappropriateness for plant height itself being employed as a parameter in biomass estimation, especially for shrubs in smaller size groups. At community level, cover was tightly correlated with the aboveground, belowground and total biomass (R² = 0.97–0.99). Therefore, biomass for the two shrubs can be simply estimated by measuring plant cover, which enables rapid estimation of shrubland carbon stock at large scales by using satellite data and repeated experiments over time. This non-destructive method using cover to estimate shrub biomass can be applied not only in arid ecosystems but also in alpine or subalpine environment.     

Olive-derived biomass as a renewable source of value-added products

Olive oil is a characteristic product of Mediterranean countries, and its production is rapidly expanding to many other regions due to the health benefits attributed to the consumption of high-quality olive oil. Taking into account that the oil content is, on average, only 20% by weight of olives, a great amount of biomass, including leaves, pits, and pomace, is produced in the mill along with the main product. Moreover, the pruning of olive trees and the production of the olive pomace also generates a great amount of biomass. Currently, the usual practices for disposal of these different biomasses do not take advantage of the wide range of products that can be produced from them. This work summarizes the most relevant practices considering both the bioprocesses studied for the exploitation of the olive-derived biomass and the potential products obtained. The integration of processes in a single facility, i.e., the concept of a biorefinery based on olive-derived biomass, is also reviewed, including technoeconomic and environmental assessment.     

Potential of Biowaste from the Food Industry as a Biomass Resource

The importance of biomass as a resource for energy production or as a chemical feedstock will increase significantly in the next decades. The amounts of biomass that can be used for non‐food purposes however will be limited and its use will compete with other claims like food and feed production. In order to minimize such food‐feed‐fuel conflicts it is necessary to integrate all kinds of biowaste into a biomass economy. The food industry in particular might be a good candidate for assessment, since it produces inevitably large amounts of biogenic residues each year. The possibilities to use food processing residues for non‐food purposes like bioenergy, biomaterial production, chemical feedstock or as animal feed are therefore discussed in more detail in this paper. It is shown that food processing residues represent a small but valuable biomass fraction that can be exploited in numerous ways. The most promising approach appears to be to design new microbial bioconversion processes as part of more complex biorefinery concepts.     

Plants as a green alternative for alcohol preparation from aromatic aldehydes

A general methodology for the efficient reduction of aromatic aldehydes and three ketones to their corresponding alcohols (interesting as cosmetic fragrances in their majority) with moderate to excellent chemical yield was achieved by using homogenates of broccoli (B. oleracea var. italic), cauliflower (B. oleracea var. botrytis), beet (B. vulgaris var. cicla), and spinach (S. oleraceae) in aqueous suspension and mild reaction conditions. B. oleracea var. italic and B. oleracea var. botrytis gave the maximum bioconversion yields within short reaction times. Vegetables assayed exhibited an excellent yield (≥ 99%) after 24 hours for aromatic aldehydes.     

Bistability in feedback circuits as a byproduct of evolution of evolvability

Noisy bistable dynamics in gene regulation can underlie stochastic switching and is demonstrated to be beneficial under fluctuating environments. It is not known, however, if fluctuating selection alone can result in bistable dynamics. Using a stochastic model of simple feedback networks, we apply fluctuating selection on gene expression and run in silico evolutionary simulations. We find that independent of the specific nature of the environment–fitness relationship, the main outcome of fluctuating selection is the evolution of increased evolvability in the network; system parameters evolve toward a nonlinear regime where phenotypic diversity is increased and small changes in genotype cause large changes in expression level. In the presence of noise, the evolution of increased nonlinearity results in the emergence and maintenance of bistability. Our results provide the first direct evidence that bistability and stochastic switching in a gene regulatory network can emerge as a mechanism to cope with fluctuating environments. They strongly suggest that such emergence occurs as a byproduct of evolution of evolvability and exploitation of noise by evolution.     

Potential Aqueous Two‐Phase Processes for the Primary Recovery of Colored Protein from Microbial Origin

The primary recovery of c‐phycocyanin and b‐phycoerythrin from Spirulina maxima and Porphyridium cruentum, respectively, using an established extraction strategy was selected as a practical model system to study the generic application of polyethylene glycol (PEG)‐phosphate aqueous two‐phase systems (ATPS). The generic practical implementation of ATPS extraction was evaluated for the recovery of colored proteins from microbial origin. A comparison of the influence of system parameters, such as PEG molecular mass, concentration of PEG as well as salt, system pH and volume ratio, on the partition behavior of c‐phycocyanin and b‐phycoerythrin was carried out to determine under which conditions target colored protein and contaminants concentrate to opposite phases. One‐stage processes are proposed for the primary recovery of the colored proteins. PEG1450‐phosphate ATPS extraction (volume ratio (V_R) equal to 0.3, tie‐line length (TLL) of 34 % w/w and system pH 7.0) for the recovery of c‐phycocyanin from Spirulina maxima resulted in a primary recovery process that produced a protein purity of 2.1 ± 0.2 (defined as the relationship of 620 nm to 280 nm absorbance) and a product yield of 98 % [w/w]. PEG1000‐phosphate ATPS extraction (i.e., V_R = 1.0, PEG 1000, TLL 50 % w/w and system pH 7.0) was preferred for the recovery of b‐phycoerythrin from Porphyridium cruentum, which resulted in a protein purity of 2.8 ± 0.2 (defined as the relationship of 545 nm to 280 nm absorbance) and a product yield of 82 % [w/w]. The purity of c‐phycocyanin and b‐phycoerythrin from the crude extract increased 3‐ and 4‐fold, respectively, after ATPS. The results reported herein demonstrated the benefits of the practical generic application of ATPS for the primary recovery of colored proteins from microbial origin as a first step for the development of purification processes.     

Properties and potential applications of natural cellulose fibers from the bark of cotton stalks

Natural cellulose fibers have been obtained from the bark of cotton stalks and the fibers have been used to develop composites. Cotton stalks are rich in cellulose and account for up to 3 times the quantity of cotton fiber produced per acre. Currently, cotton stalks have limited use and are mostly burned on the ground. Natural cellulose fibers obtained from cotton stalks are composed of approximately 79% cellulose and 13.7% lignin. The fibers have breaking tenacity of 2.9 g per denier and breaking elongation of 3% and modulus of 144 g per denier, between that of cotton and linen. Polypropylene composites reinforced with cotton stalk fibers have flexural, tensile and impact resistance properties similar to jute fiber reinforced polypropylene composites. Utilizing cotton stalks as a source for natural cellulose fibers provides an opportunity to increase the income from cotton crops and make cotton crops more competitive to the biofuel crops.     

Influence of Incubation Solution on the Rate of Recovery of Pratylenchus brachyurus from Cotton Roots

The rate of recovery of Pratylenchus brachyurus from cotton roots was enhanced when the tissue was incubated in solutions containing 10 ppm ethoxyethyl mercuric chloride, 50 ppm dihydrostreptomycin sulfate, 50, 100, or 1,000 ppm diisobutylphenoxethyl dimethyl benzyl ammonium chloride, or mixtures of these compounds. Incubation in 10 or 100 ppm zinc sulfate, zinc chloride, or magnesium chloride also enhanced the rate of recovery. Incubation solutions containing 1 or 1,000 ppm zinc chloride or magnesium chloride had no influence on this phenomenon, whereas, 10,000 ppm zinc sulfate, zinc chloride, or magnesium chloride retarded the rate of recovery. A t all incubation intervals during the first 21 days after the roots were removed from soil, the P. brachyurus population consisted of approximately 25% second-stage juveniles, 44% third and fourth-stage juveniles, and 31% females. At least 88% of the second-stage juveniles and 51% of the third and fourth-stage juveniles passed through a single 325-mesh sieve, whereas, 84% of the females collected were retained on a sieve of this mesh.     

Recovery of adsorbed zinc in acid soils as influenced by prior phosphorus applications

Summary Five acid soils of Hawaii, having histories of heavy P applications were equilibrated with graded quantities of Zn. Amounts of adsorbed Zn were extracted with a single extraction of 0.005M DTPA. The data indicated that most of the added Zn was in available form. Prior P applications either had no effect on recovery or slightly increased it. The results substantiated the earlier findings that P-induced Zn deficiency could not be due to precipitation of Zn as insoluble Zn–P compounds in the soils.     

Sericin from Bombyx mori cocoons. Part I: Extraction and physicochemical-biological characterization for biopharmaceutical applications

In the present research effort, production of crude sericin extracts from Bombyx mori silk cocoons was attempted using two different approaches. Sericin was extracted from cocoons by high-temperature autoclaving followed either by lyophilization or freezing-thawing precipitation, to obtain a crude sericin powder. The physico-chemical and biological characteristics of the crude sericin extracts were evaluated in detail, via FTIR, XRD, XRF, XRT, UV–vis scanning, TGA and DSC, protein quantification, antimicrobial activity, free radical scavenging activity, cytotoxic activity, potential for inducing chromosomal aberrations via Allium cepa assays, and genotoxicity via Comet™ analyses. The molecular weight distribution of the crude sericin extracts was also investigated, via sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS–PAGE), and the results duly compared to standard sericin. The results gathered clearly suggest that the crude sericin extracts had both obvious radical scavenging effects with the 2.2-diphenyl-1-picryl-hydrazil (DPPH) assay, and antibacterial activity, further suggesting that this protein might be a valuable addition for either food and biopharmaceutical applications.     

S-layers as a tool kit for nanobiotechnological applications

Crystalline bacterial cell surface layers (S-layers) have been identified in a great number of different species of bacteria and represent an almost universal feature of archaea. Isolated native S-layer proteins and S-layer fusion proteins incorporating functional sequences self-assemble into monomolecular crystalline arrays in suspension, on a great variety of solid substrates and on various lipid structures including planar membranes and liposomes. S-layers have proven to be particularly suited as building blocks and patterning elements in a biomolecular construction kit involving all major classes of biological molecules (proteins, lipids, glycans, nucleic acids and combinations of them) enabling innovative approaches for the controlled 'bottom-up' assembly of functional supramolecular structures and devices. Here, we review the basic principles of S-layer proteins and the application potential of S-layers in nanobiotechnology and biomimetics including life and nonlife sciences.     

Chlorsulfuron resistant transgenic tobacco as a tool for broomrape control

Broomrape (Orobanche ramosa L.) is the most important parasitic plant that infests tobacco (Nicotiana tabacum L.). Chemical treatment of the soil is not effective and crop rotation is not acceptable to solve this problem because of the long viability period of Orobanche seeds in the soil. Application of systemic herbicides in the field with herbicide resistant tobacco could be a successful tool for broomrape control. Several tobacco cultivars were transformed with a mutant ahas3R gene for resistance to the herbicide chlorsulfuron (Glean^®, DuPont). Transformed plants were selfed and the segregation of resistance was followed in the next generation. The efficiency of the herbicide was demonstrated in greenhouse and field trials. An Orobanche/tobacco growth system was used in order to prove the lethal effect of the herbicide to the attached broomrape plants.     

Strain engineering for microbial production of value-added chemicals and fuels from glycerol

While the widespread reliance on fossil fuels is driven by their low cost and relative abundance, this fossil-based economy has been deemed unsustainable and, therefore, the adoption of sustainable and environmentally compatible energy sources is on the horizon. Biorefinery is an emerging approach that integrates metabolic engineering, synthetic biology, and systems biology principles for the development of whole-cell catalytic platforms for biomanufacturing. Due to the high degree of reduction and low cost, glycerol, either refined or crude, has been recognized as an ideal feedstock for the production of value-added biologicals, though microbial dissimilation of glycerol sometimes can be difficult particularly under anaerobic conditions. While strain development for glycerol biorefinery is widely reported in the literature, few, if any, commercialized bioprocesses have been developed as a result, such that engineering of glycerol metabolism in microbial hosts remains an untapped opportunity in biomanufacturing. Here we review the recent progress made in engineering microbial hosts for the production of biofuels, diols, organic acids, biopolymers, and specialty chemicals from glycerol. We begin with a broad outline of the major pathways for fermentative and respiratory glycerol dissimilation and key end metabolites, and then focus our analysis on four key genera of bacteria known to naturally dissimilate glycerol, i.e. Klebsiella, Citrobacter, Clostridium, and Lactobacillus, in addition to Escherichia coli, and systematically review the progress made toward engineering these microorganisms for glycerol biorefinery. We also identify the major biotechnological and bioprocessing advantages and disadvantages of each genus, and bottlenecks limiting the production of target metabolites from glycerol in engineered strains. Our analysis culminates in the development of potential strategies to overcome the current technical limitations identified for commonly employed strains, with an outlook on the suitability of different hosts for the production of key metabolites and avenues for their future development into biomanufacturing platforms.