A filter fermenter-apparatus and control equipment

Laboratory equipment for cultivation of microorganisms with the removal of cell-free medium is described. Separation is accomplished by filtration through a membrane which is built into a top-driven fermenter. A system is presented which controls the flow rate by automatic cleaning of the filter. Flow schemes for batch and continuous fermentations are shown. The filter fermenter is useful when studying continuous culture with feedback of biomass or processes where growth or product formation rates are influenced by inhibitory metabolites. Results are presented from experiments with Saccharomyces cerevisiae, Pedicoccus pentosaceus, and Zymomonas mobilis.     

Elicitation: A biotechnological tool for enhanced production of secondary metabolites in hairy root cultures

Elicitation is a possible aid to overcome various difficulties associated with the large‐scale production of most commercially important bioactive secondary metabolites from wild and cultivated plants, undifferentiated or differentiated cultures. Secondary metabolite accumulation in vitro or their efflux in culture medium has been elicited in the undifferentiated or differentiated tissue cultures of several plant species by the application of a low concentration of biotic and abiotic elicitors in the last three decades. Hairy root cultures are preferred for the application of elicitation due to their genetic and biosynthetic stability, high growth rate in growth regulator‐free media, and production consistence in response to elicitor treatment. Elicitors act as signal, recognized by elicitor‐specific receptors on the plant cell membrane and stimulate defense responses during elicitation resulting in increased synthesis and accumulation of secondary metabolites. Optimization of various parameters, such as elicitor type, concentration, duration of exposure, and treatment schedule is essential for the effectiveness of the elicitation strategies. Combined application of different elicitors, integration of precursor feeding, or replenishment of medium or in situ product recovery from the roots/liquid medium with the elicitor treatment have showed improved accumulation of secondary metabolites due to their synergistic effect. This is a comprehensive review about the progress in the elicitation approach to hairy root cultures from 2010 to 2019 and the information provided is valuable and will be of interest for scientists working in this area of plant biotechnology.     

DMSO、Tween-20和Triton X-100对野葛悬浮细胞异黄酮生产的影响

二甲基亚砜(DMSO)、Tween-20和Triton X-100可以增大悬浮培养细胞的细胞膜和液泡膜的透性,促进细胞内次生代谢物的释放,从而影响这些次生代谢产物的产量。为了提高野葛悬浮细胞中异黄酮类化合物的产量,以1％、3％和5％的DMSO、Tween-20和Triton X-100分别处理野葛叶悬浮细胞,结果显示,Tween-20和Triton X-100皆明显促进细胞生物量和葛根素和异黄酮化合物的释放。5％的Triton X-100处理3d,促进细胞产生总异黄酮化合物,增产率达40．6％。     

Production of rosmarinic acid in high density perfusion cultures ofAnchusa officinalis using a high sugar medium

Summary The most direct approach to enhancing the volumetric yield of secondary metabolites in plant tissue cultures is to operate the culture under high cell density. In this study, a cell suspension ofAnchusa officinalis was cultivated using a semi-continuous perfusion technique, i.e. batch cultivation with intermittent medium exchange. Using a perfusion medium containing sucrose concentration which was two times that in the normal growth medium, the final cell density and the final product concentration were increased by more than 2-fold compared with a batch culture without medium exchange. The high cell density obtained from the semi-continuous perfusion culture can be explained by the prevention of nutrient depletion, removal of toxic by-products, as well as the control of cell size by virtue of the high sugar medium osmolarity.     

In situ extraction strategy affects benzophenanthridine alkaloid production fluxes in suspension cultures of Eschscholtzia californica

The effect of contact between cells and extractive phase on secondary metabolite production was investigated in two-phase suspension cultures of Eschscholtzia californica. A system was designed to extract benzophenanthridine alkaloids from the cell culture, without contact between XAD-7 resins and the cells: only medium was recirculated through a column packed with the extractive phase. This strategy was compared to the classic method of addition of resins directly into the cell suspension. Removal of the product directly from the medium enabled important increases in production of alkaloids, namely a 20-fold increase in sanguinarine production and a 10-fold increase in chelerythrine, with high recovery in the resin. The recirculation strategy greatly simplified the production process since the resins are easily recovered from the cell culture and enable harvest of product without termination of culture. However, due to limited flow rate, the recirculation strategy was slightly less effective than direct addition of resins into the cell suspension. In addition to enabling increased production, removal of secondary metabolites from the medium changed metabolic flux distribution, testifying to a complex control mechanism of production.     

Product enhancement and recovery from transformed root cultures of Nicotiana glauca

Transformed roots of Nicotiana glauce synthesize the alkaloids nicotine and anabasine at levels reflecting the parent plants. Media composition, strength, and pH were evaluated with respect to biomass yield and productivity. Full-strength Gamborg's B5 medium proved the best for biomass yield while half-strength, or low-salt, medium enhanced alkaloid accumulation. A detailed investigation of media nitrate levels demonstrated how these may be manipulated to promote growth and intracellular or extracellular alkaloid levels. High nitrate concentrations were found to significantly enhance media alkaloid levels at the end of the growth phase. Media pH is also important, although transformed roots will grow in Gamborg's B5 medium between pH 3 and 9, root biomass is favored by an increase in medium alkalinity, while alkaloid release is encouraged by mildly acidic pH.Transformed roots release a proportion of their secondary metabolites into the growth medium. By continually removing root products, any feedback inhibition on enzymatic reactions is reduced, as are the toxic effects resulting from product accumulation. In this article we describe the use of Amberlite resins (XAD-2 and XAD-4) to enhance alkaloid levels (nicotine and anabasine) of hairy root cultures of Nicotiana glauca by a factor of 10 with no adverse effect on root growth. The performance of the Amberlite columns was subsequently investigated with respect to alkaloid adsorption and desorption, including an evaluation of the effects of pH and loading capacity. The resins also adsorb media constituents which are identified and quantified as part of this work. Resulting nutritional stresses are thought to be partly responsible for enhancing secondary metabolism at the expense of biomass yield. However, the net effects of using Amberlite resins as a means of product removal significantly increases the overall product yield and the extent to which products are released into the growth medium.     

Whole-Nodule Carbon Metabolites Are Not Involved in the Regulation of the Oxygen Permeability and Nitrogenase Activity in White Clover Nodules

To test the hypothesis of an indirect or direct involvement of carbon metabolites in the short-term regulation of nitrogenase activity, nodule O2 permeability was manipulated either by defoliation or by varying rhizosphere O2 partial pressure. In contrast to defoliation, a 50% reduction of the nodule O2 permeability, due to adapting nodules to 40 kPa O2, had no effect on nodule sucrose concentration. Likewise, total concentrations of other carbon metabolites such as fructose, starch, L-malate, and succinate tended to be differentially affected by the two treatments. Upon defoliation, carbon metabolites in roots responded in a manner similar to those in nodules. Sucrose concentration in nodules decreased significantly after the removal of 40% of the leaf area, which is known to have no effect on nitrogenase activity and O2 permeability. During regrowth after a 100% defoliation, nitrogenase activity could be increased at any time by elevating rhizospheric O2 partial pressure. Thus, during the entire growing cycle nitrogenase activity seems primarily oxygen limited. Changes in whole nodule sucrose pools after defoliation have to be viewed as secondary effects not necessarily linked to nodule activity. Whole-nodule carbon metabolites appear not to be determinants of nodule activity, either through direct metabolic involvement or through indirect effects such as triggering O2 permeability.     

Plasmodium falciparum-induced channels

To survive within a red blood cell, the malaria parasite alters dramatically the permeability of the host's plasma membrane (allowing the uptake of essential nutrients and the removal of potentially hazardous metabolites). The pathway(s) responsible for the increased permeability have been proposed as putative chemotherapeutic targets and/or selective routes for antimalarial agents that target the internal parasite. This review covers our current understanding of this parasite-induced phenomenon in Plasmodium falciparum-infected human red blood cells. In particular, recent electrophysiological studies, using the patch-clamp technique, are reviewed.     

TOPICAL PAPER: Utilization of Hairy Root Cultures for Production of Secondary Metabolites

The possibility of producing useful chemicals by plant cell cultures has been studied intensively for the past 30 years. However, problems associated with low product yields and culture instabilities have restricted wider industrial application of plant cell culture. The employment of hairy root culture technology, developed in the past 10 years, offers new opportunities for in vitro production of plant secondary metabolites. In contrast to cell suspension cultures, hairy root cultures are characterized by high biosynthetic capacity and genetic as well as biochemical stability. In this review, the establishment and cultivation of hairy root cultures as well as their properties and application for production of secondary metabolites are discussed.     

Application of cell technologies for production of plant-derived bioactive substances of plant origin

Bioactive substances (BAS) of plant origin are known to play a very important role in modern medicine. Their use, however, is often limited by availability of plant resources and may jeopardize rare species of medicinal plants. Plant cell cultures can serve as a renewable source of valuable secondary metabolites. To the date, however, only few examples of their commercial use are known. The main reasons for such a situation are the insufficient production of secondary metabolites and high cultivation costs. It is possible to increase the performance of plant cell cultures by one or two orders of magnitude using traditional methods, such as selection of highly productive strains, optimization of the medium composition, elicitation, and addition of precursors of secondary metabolite biosynthesis. The progress in molecular biology methods brought about the advent of new means for increasing of the productivity of cell cultures based on the methods of metabolic engineering. Thus, overexpression of genes encoding the enzymes involved in the synthesis of the target product or, by contrast, repression of these genes significantly influences the cell biosynthetic capacity in vitro. Nevertheless, the attempts of the production of many secondary metabolites in plant cell culture were unsuccessful so far, probably due to the peculiarities of the cell culture as an artificial population of plant somatic cells. The use of plant organ culture or transformed roots (hairy root) could turn to be a considerably more efficient solution for this problem. The production of plant-derived secondary metabolites in yeast or bacteria transformed with plant genes is being studied currently. Although the attempts to use metabolic engineering methods were not particularly successful so far, new insights in biochemistry and physiology of secondary metabolism, particularly in regulation and compartmentation of secondary metabolite synthesis as well as mechanisms of their transport and storage make these approaches promising.     

Covalent incorporation of 3'-O-(4-benzoyl)benzoyl-ATP into a P2 purinoceptor in transformed mouse fibroblasts.

ATP, 3'-O-(4-benzoyl)benzoyl-ATP (BzATP), a photoaffinity analog of ATP, and several other ATP analogs induced an increase in plasma membrane permeability to monovalent ions and normally impermeant metabolites, including nucleotides, in transformed 3T6 mouse fibroblasts. The rank order of agonist potency for induction of nucleotide channels was BzATP (EC50 = 15 microM) greater than ATP (EC50 = 50 microM) approximately adenosine 5'-O-(1-thiotriphosphate) (ATP alpha S) greater than 2-methylthio-ATP (EC50 = 75 microM) approximately 3'-amino-3'-deoxy-ATP greater than adenosine 5'-O-(3-thiotriphosphate) (ATP gamma S) (EC50 = 175 microM). Long wavelength UV illumination of 3T6 cells in the presence of greater than or equal to 20 microM BzATP at 4 degrees C, a nonpermeabilizing temperature, followed by removal of unbound BzATP, resulted in the efflux of 86Rb+ and the release of a prelabeled pool of cytoplasmic nucleotides when the temperature was shifted to 37 degrees C. Photoincorporation of BzATP was inhibited by ATP, ATP alpha S, ATP gamma S, and other ATP analogs that induced an increase in plasma membrane permeability to nucleotides in 3T6 cells under nonphotoactivating conditions. GTP, ITP, UTP, adenosine, and ATP analogs that did not alter plasma membrane permeability to nucleotides under nonphotoactivating conditions also had no effect on BzATP photoincorporation. Photoincorporation of BzATP occurred optimally between pH 6.6 and pH 8.2 but was inhibited at pH 6.0. Photoincorporation of BzATP was also modulated by the osmolarity and the divalent cation concentration of the assay medium. The increase in plasma membrane permeability to nucleotides induced by photoincorporated BzATP occurred at the same rate and had the same temperature, pH, ionic strength, and divalent cation requirements as the increase in plasma membrane permeability to nucleotides induced by ATP and BzATP under nonphotoactivating conditions. These findings support the hypothesis that BzATP can be covalently incorporated into a P2 purinoceptor in 3T6 cells that is coupled to plasma membrane channels for ions and other metabolites.     

A simple method for enhancing paclitaxel release from<Emphasis Type="Italic"> Taxus canadensis</Emphasis> cell suspension cultures utilizing cell wall digesting enzymes

Paclitaxel storage in Taxus suspension cell cultures was studied through the simple use of cell wall digesting enzymes. The application of cellulase (1%) and pectolyase (0.1%) to Taxus canadensis suspension cultures induced a significant increase in the paclitaxel present in the extracellular medium while maintaining membrane integrity, suggesting that paclitaxel is stored in the cell wall. The addition of cell wall digesting enzymes to a cell culture bioprocess may be an effective way of enhancing paclitaxel release to the extracellular medium and hence simplify product recovery.Communicated by K.K. Kamo     

Bioprocessing of differentiated plant in vitro systems

Plant cells contain a wide range of interesting secondary metabolites, which are used as natural pigments and flavoring agents in foods and cosmetics as well as phyto‐pharmaceutical products. However, conventional industrial extraction from whole plants or parts of them is limited due to environmental and geographical issues. The production of secondary metabolites from in vitro cultures can be considered as alternative to classical technologies and allows a year‐round cultivation in the bioreactor under optimal conditions with constant high‐level quality and quantity. Compared to plant cell suspensions, differentiated plant in vitro systems offer the advantage that they are genetically stable. Moreover, the separation of the biomass from culture medium after fermentation is much easier. Nevertheless, several investigations in the literature described that differentiated plant in vitro systems are instable concerning the yield of the target metabolites, especially in submerged cultivations. Other major problems are associated with the challenges of cultivation conditions and bioreactor design as well as upscaling of the process. This article reviews bioreactor designs for cultivation of differentiated plant in vitro systems, secondary metabolite production in different bioreactor systems as well as aspects of process control, management, and modeling and gives perspectives for future cultivation methods.     

Cell and process design for targeting of recombinant protein into the culture medium of <Emphasis Type="Italic">Escherichia coli</Emphasis>

This paper is a review of strategies to introduce protein into the liquid medium of Escherichia coli K-12 industrial production cells. The cell design strategies are generally based on one of two general mechanisms. The first strategy involves a two-stage translocation using active transporters in the cytoplasmic membrane followed by passive transport through the outer membrane. Passive transport is achieved through either external or internal destabilization of the E. coli structural components. The latter can be achieved by transplantation of destabilizing components (lysis proteins) that work by permeabilization of the outer membrane from the interior of the cell, or by using cells carrying mutations of structural components. Passive transport can also be achieved by a chemical, mechanical, or enzymatic permeabilization directed from outside the cell. The second strategy is realized through transplantation of proteins capable of active transport over one or both of the membranes. This involves the transplantation of secretion mechanisms into the K-12 cell from pathogenic E. coli as well as from other species. The process design strategies are dependent on environmental conditions and must take into account changes in physical parameters, medium design, and influx of limiting carbon source in fed-batch cultivation.     

On simultaneous determinations of the permeability of a membrane and of the diffusion coefficient in an adjacent medium

This paper deals with diffusion into a medium of finite thickness through a flat structure which can be considered either as a slice of tissue or as a membrane. Formulae are given to determine the diffusion coefficients in both the flat structure and the adjacent medium from the knowledge of the amount of substance penetrating the medium. The meaning of the formula: (permeability coefficient) = (diffusion coefficient)/(membrane thickness) and the experimentally observed variability of the permeability coefficient in the non-steady state are interpreted on the basis of the mathematical theory of diffusion.     

Effects of dl-2-Amino-5-Phosphonovalerate on Metabolism of Catecholamines in Synaptosomes from Rat Brain

Incubation of synaptosomes from rat brain with DL-2-amino-5-phosphonovalerate (APV) stimulated an increased release of dopamine, and this effect was strictly dependent on the extrasynaptosomal calcium level. APV increased biosynthesis of dopamine from tyrosine by 30%, whereas monoamine oxidase activity was inhibited by 30%. When synaptosomes were incubated with radioactive dopamine, APV caused a large decrease in incorporation of label into 3,4-dihydroxyphenylacetic acid but greatly increased incorporation into norepinephrine and its N-methyl derivatives. Quantification of dopamine and its metabolites in synaptosomes, using electrochemical detection, indicated that the presence of APV resulted in changes in the absolute levels of the aforementioned dopamine metabolites similar to the changes in radiolabel incorporation. Omission of Ca2+ from the extrasynaptosomal medium greatly diminished the APV-induced changes in catecholamine metabolism. The metabolic changes appear to largely result from an increased intrasynaptosomal Ca2+ level due to the APV-induced increase in calcium permeability of the plasma membrane.     

Bioreactor for cultivation of red beet hairy roots and in situ recovery of primary and secondary metabolites

To arrive at an appropriate bioreactor design and in situ recovery of the products, red beet hairy roots were used as a model system where the levels of betalain pigments (betacyanins and betaxanthins) were followed as secondary metabolite and the peroxidase enzyme as primary metabolite. Medium volume and other kinetic parameters were found to play significant roles by way of directly affecting the biomass yield rather than a specific metabolite. The hydrodynamic stress created on the roots by large culture volume could be minimized by pulse‐feeding of medium in shake‐flasks; and by separating the biomass chamber from the aerated medium reservoir in circulatory fed‐batch bioreactor. Accordingly the bioreactor was modified to provide anchorage and air‐enrichment chamber which resulted in higher formation of both the metabolites than in shake‐flasks. Various down‐stream processing aspects such as in situ release of pigments by non‐destructive methods, followed by adsorption through a column and recovery by desorption were optimized for betalains. A strategy for simultaneous recovery of pigment and peroxidase was worked out using aqueous two phase extraction (ATPE).     

Erythrocyte membrane sulfhydryl groups and cation permeability

Reaction of the slowly penetrating organic mercurial compound parachloromercuribenzene sulfonate (PCMBS) with intact erythrocytes has been characterized. Addition of concentrations of PCMBS which result in binding within the interior of the membrane of more than 1.9 × 10^?18 moles/cell produces alterations in Na⁺ and K⁺ permeability, but does not affect choline permeability. However, the increased cation permeability is observed only after a lag period of over two hours. After ten hours, a spontaneous slow “recovery” to normal rates of K⁺ leakage occurs at 25°C but not at 2°C. Subsequent to the effects on cation balance, increasing degrees of hemolysis occur, interpreted as colloid osmotic lysis. The relationships between the binding of the agent and its effects are as follows: a small, rapid initial uptake does not affect cation permeability; the subsequent slower uptake is associated with increased leakage of K⁺ and Na⁺; and the recovery at 25°C is associated with desorption of about half of the PCMBS due to competition by soluble thiol substances released into the medium from the cells. Desorption and “recovery” can be mimicked at any time by addition of small amounts of protein in the medium. The half of the PCMBS that cannot be desorbed is assumed to be bound by the hemoglobin inside the cell. The sulfhydryl groups involved in control of cation permeability constitute only a fraction of the total within the membrane (4–18%). They are located within the interior of the membrane separated from the medium and from the interior of the cell by diffusion barriers to PCMBS.     

地衣及其内生真菌活性次级代谢产物研究进展

地衣是一种独特的菌藻共生体,能够在荒漠、高山、冻土等恶劣环境生存,具有特殊的生理结构和独特的生存环境.地衣及其内生真菌能够产生结构新颖、活性广泛的次级代谢产物,研究地衣及其内生真菌次级代谢产物对新型药用资源开发以及利用等方面都具有重要的意义.本文关注了近年来地衣及其内生真菌的次级代谢产物相关研究,并对其生物活性方面的研...