Scanning electron microscopy of immobilizedHumicola lutea during semicontinuous production of acid proteinases

The morphology of the fungusHumicola lutea (strain 120–5), immobilized in polyacrylamide and polyhydroxyethylmethacrylate and used for the semicontinuous production of acid proteinases, was examined by scanning electron microscopy. The fungus developed a dense mycelium below the bead surface as well as in the bead interior after precultivation of entrapped spores. During maximal semicontinuous enzyme biosynthesis, formation of numerous large bulbous cells with a different shape was observed. Lysis of the cells was observed mainly in the centre of the gel beads after 13 successive fermentations with polyacrylamide-immobilized cells or after 21 re-uses of polyhydroxyethylmethacrylate-immobilized mycelia, respectively. Growth and changes in the cellular morphology of immobilizedH. lutea, accompanying biosynthesis of acid proteinases, were comparable in both gel matrices but mycelia immobilized in polyhydroxyethylmethacrylate maintained their productivity twice as long.     

Mycelial morphology and metabolite production

Mycelial microorganisms are exploited extensively in the commercial production of a wide range of secondary metabolites. They can be cultured as free mycelia, as aggregated forms (pellets/flocs), or as artificially bound/entrapped cells, though problems are associated with the culture of each morphological type. Since the morphological type can strongly influence metabolite production, the methodology for inducing pellet formation, and the type of pellets produced are an important consideration for effective metabolite production.     

Screening of microorganisms having high fumarase activity and their immobilization with carrageenan

Summary To develop an efficient method for continuous production of L-malic acid from fumaric acid using immobilized microbial cells, screening of microorganisms having high fumarase activity was carried out and cultural conditions of selected microorganisms were investigated. As a result of screening microorganisms belonging to the genera Brevibacterium, Proteus, Pseudomonas, and Sarcina were found to produce fumarase in high levels. Among these microorganisms Brevibacterium ammoniagenes, B. flavum, Proteus vulgaris, and Pseudomonas fluorescens were further selected for their high fumarase levels in the cultivation on several media. These 4 microorganisms were entrapped into a k-carrageenan gel lattice, and the resultant immobilized B. flavum showed the highest fumarase activity and operational stability.Cultural conditions for the fumarase formation and the operational stability of fumarase activity of immobilized B. flavum are detailed. Productivity for L-malic acid using immobilized B. flavum with k-carrageenan was 2.3 fold of that using immobilized B. ammoniagenes with polyacrylamide.Presented at the Annual Meeting of the Agricultural Chemical Society of Japan, Nagoya, April 3, 1978     

Steroid transformation by activated living immobilized Arthrobacter simplex cells

A preparation of living Arthrobacter simplex cells immobilized in polyacrylamide gel, which showed steroid-Δ¹-dehydrogenase activity, was studied. The entrapped microorganisms catalyzed the transformation of cortisol to prednisolone and this reaction was followed spectrophotometrically or with the aid of thin layer chromatography (TLC) and high pressure liquid chromatography (HPLC). About 40% of the original activity found with free bacteria was retained after immobilization. The steroid dehydrogenase activity of polyacrylamide-entrapped A. simplex could be raised to a minor extent in alcoholic solvents or by addition of a cofactor such as menadione. On incubation in various nutrient media, on the other hand, the activity could be increased considerablyl, usually 7–10 times. Possible causes for the observed increase in activity have been investigated, and microbial growth of the original entrapped microorganisms appears to be the major reason. Frozen activated preparations of immobilized A. simplex showed only a small loss of activity on storage for at least four months. A semicontinuous batch wise operation with immobilized A. simplex in different nutrient media was carried out. At the end of the experiment the steroid transformation capacity was 0.5 g steroid per day per g gel (wet weight).     

Chlortetracycline production with immobilized Streptomyces aureofaciens

Summary The semicontinuous production of chlortetracycline by immobilized cells of Streptomyces aureofaciens ATCC 10762 was compared with that of free cells. Immobilized cells transferred repeatedly to a new production medium, showed a fourfold increase in the half life time of antibiotic production.In an air bubble column a high chlortetracycline productivity was obtained with a high aeration rate.A semicontinuous production of chlortetracycline by immobilized S. aureofaciens could be improved by varying the fermentation conditions.For continuous chlortetracycline production by immobilized cells, no improvement was detected.     

Degradation kinetics of phenol by immobilized cells of Candida tropicalis in a fluidized bed reactor

Degradation kinetics of phenol by free and agar-entrapped cells of Candida tropicalis was studied in batch cultures. The initial phenol degradation rate achieved with free cells was higher than that obtained with immobilized cells, when phenol concentrations up to 1000 mg l^–1 were used. However, at higher phenol concentrations, the behaviour was quite different. The initial degradation rate of the immobilized yeast cells was about 10 times higher than that of the free cells, at a phenol concentration of 3500 mg l^–1. The semicontinuous and continuous degradation of phenol by immobilized yeast cells was also investigated in a multi-stage fluidized bed reactor. The highest phenol removal efficiencies and degradation rates as well as the lowest values of residual phenol and chemical oxygen demand were obtained in the semicontinuous culture when phenol concentrations up to 1560 mg l^–1 were used.     

Chlorpromazine N-demethylation by hydroperoxidase activity of covalent immobilized lipoxygenase

This work describes the application of the N-demethylase activity of immobilized soybean lipoxygenase to the oxidative degradation of xenobiotics. Previously (1) we have shown that immobilized lipoxygenase produces the oxidative degradation of CPZ in the presence of hydrogen peroxide. As a continuation of this work, here we studied the N-demethylation of CPZ by the hydroperoxidase activity of covalent immobilized soybean lipoxygenase. The obtained results clearly reveal that the immobilized system produces the N-demethylation of CPZ in the presence of hydrogen peroxide, maintaining a high level of activity in comparison with free enzyme. Additionally, the immobilized lipoxygenase shows stability higher than that of free enzyme, making feasible its use in a bioreactor operating in continuous or discontinuous mode. The results obtained in this work, together with those obtained previously by us for the oxidation of CPZ, suggest that hydroperoxidase activity of immobilized lipoxygenase may constitute a valuable tool for oxidative xenobiotics degradation or for application to synthetic processes in which a N-demethylation reaction is involved.     

Bioactive secondary metabolites produced by microorganisms associated with plants

In the past few decades groups of scientists have focused their study on relatively new microorganisms called endophytes. By definition these microorganisms, mostly fungi and bacteria, colonise the intercellular spaces of the plant tissues. The mutual relationship between endophytic microorganisms and their host plants, taxanomy and ecology of endophytes are being studied. Some of these microorganisms produce bioactive secondary metabolites that may be involved in a host-endophyte relationship. Recently, many endophytic bioactive metabolites, known as well as new substances, possesing a wide variety of biological activities as antibiotic, antitumor, antiinflammatory, antioxidant, etc. have been identified. The microorganisms such as endophytes may be very interesting for biotechnological production of bioactive substances as medicinally important agents. Therefore the aim of this review is to briefly characterize endophytes and summarize the structuraly different bioactive secondary metabolites produced by endophytic microorganisms as well as microbial sources of these metabolites and their host plants.     

Production of L-Phenylacetyl Carbinol by Immobilized Cells of Saccharomyces Cerevisiae

Conversion of benzaldehyde to L-phenylacetyl carbinol (L-PAC) was achieved with immobilized, growing cells of Saccharomyces cerevisiae in different reactors. Product formation increased (31%) with the subsequent initial reuses of the entrapped cells. Biomass production and PAC formation depleted (40 and 57%, respectively) after 4-5 continuous growth and biotransformation cycles. With the regeneration of the biocatalysts, catalytic activity of the cells was resumed. The highest yields were in a stirred tank reactor (29 g PAC) from 77 g benzeldehyde with 14 repeated uses of entrapped cells.     

Influence of phenols on growth and membrane permeability of free and immobilized Escherichia coli.

The inhibition of the exponential growth of Escherichia coli K-12 by different phenolic compounds was examined. Cells entrapped in calcium alginate showed a greater tolerance than cells grown in suspension. The extent of inhibition of growth of the immobilized cells depended on the period of growth in the gel matrix. After the addition of bacteriostatic concentrations of phenol or 4-chlorophenol, a dose-dependent efflux of metabolites such as ATP and of K+ ions was elicited. Provided that glucose was supplied as an energy substrate, a reaccumulation of K+ ions at low phenol concentrations was observed. The restoration of the membrane gradient for K+ always preceded the continuation of growth in the presence of the toxic compounds. Compared with free cells, those cells immobilized and grown in alginate suffered a smaller loss of cations after the addition of 4-chlorophenol. The reestablishment of gradients was observed at higher concentrations of the pollutants with entrapped cells than with free cells. Corresponding to the increase in tolerance, the membrane damage was reduced in cells grown in immobilized form for longer times. These data offer a mechanistic explanation of the protection of immobilized microorganisms from phenolic solvents. The data point to the membrane as an important cell component in the toxicity of these pollutants.     

Influence of phenols on growth and membrane permeability of free and immobilized Escherichia coli

The inhibition of the exponential growth of Escherichia coli K-12 by different phenolic compounds was examined. Cells entrapped in calcium alginate showed a greater tolerance than cells grown in suspension. The extent of inhibition of growth of the immobilized cells depended on the period of growth in the gel matrix. After the addition of bacteriostatic concentrations of phenol or 4-chlorophenol, a dose-dependent efflux of metabolites such as ATP and of K+ ions was elicited. Provided that glucose was supplied as an energy substrate, a reaccumulation of K+ ions at low phenol concentrations was observed. The restoration of the membrane gradient for K+ always preceded the continuation of growth in the presence of the toxic compounds. Compared with free cells, those cells immobilized and grown in alginate suffered a smaller loss of cations after the addition of 4-chlorophenol. The reestablishment of gradients was observed at higher concentrations of the pollutants with entrapped cells than with free cells. Corresponding to the increase in tolerance, the membrane damage was reduced in cells grown in immobilized form for longer times. These data offer a mechanistic explanation of the protection of immobilized microorganisms from phenolic solvents. The data point to the membrane as an important cell component in the toxicity of these pollutants.     

Semicontinuous and continuous degradation of phenol by Pseudomonas putida P8 adsorbed on activated carbon

Summary The semicontinuous and continuous degradation of phenol by Pseudomonas putida P8 which was immobilized on activated carbon was investigated. The amount of bacteria immobilized on the activated carbon surface dependend on the cell concentration in the suspension and on the type of activated carbon. In a continuous process running for four weeks the biomass, which accumulated in the activated carbon fixed bed, was removed periodically. The average phenol degradation rate in this process was 360 mg/1 h. The degradation activity of the bacteria for phenol, measured by the activity of the catechol-2,3-dioxygenase, was stimulated by the activated carbon. During the fermentation processes the carbon particles were covered with a biofilm. The bacteria grew, especially in the caverns and the entrances of the macropores, whereby the phenol adsorption by the activated carbon was decreased.     

Biodegradation of halogenated organic compounds.

In this review we discuss the degradation of chlorinated hydrocarbons by microorganisms, emphasizing the physiological, biochemical, and genetic basis of the biodegradation of aliphatic, aromatic, and polycyclic compounds. Many environmentally important xenobiotics are halogenated, especially chlorinated. These compounds are manufactured and used as pesticides, plasticizers, paint and printing-ink components, adhesives, flame retardants, hydraulic and heat transfer fluids, refrigerants, solvents, additives for cutting oils, and textile auxiliaries. The hazardous chemicals enter the environment through production, commercial application, and waste. As a result of bioaccumulation in the food chain and groundwater contamination, they pose public health problems because many of them are toxic, mutagenic, or carcinogenic. Although synthetic chemicals are usually recalcitrant to biodegradation, microorganisms have evolved an extensive range of enzymes, pathways, and control mechanisms that are responsible for catabolism of a wide variety of such compounds. Thus, such biological degradation can be exploited to alleviate environmental pollution problems. The pathways by which a given compound is degraded are determined by the physical, chemical, and microbiological aspects of a particular environment. By understanding the genetic basis of catabolism of xenobiotics, it is possible to improve the efficacy of naturally occurring microorganisms or construct new microorganisms capable of degrading pollutants in soil and aquatic environments more efficiently. Recently a number of genes whose enzyme products have a broader substrate specificity for the degradation of aromatic compounds have been cloned and attempts have been made to construct gene cassettes or synthetic operons comprising these degradative genes. Such gene cassettes or operons can be transferred into suitable microbial hosts for extending and custom designing the pathways for rapid degradation of recalcitrant compounds. Recent developments in designing recombinant microorganisms and hybrid metabolic pathways are discussed.     

Advances in microbial biotechnology of bile acids

The recent advances in microbial biotechnology of production of bile acid metabolites helped to identify a number of neutral and acidic steroidal compounds useful as drugs and drug intermediates on a scale which would not have been possible by classical chemical transformations. Microbial transformations viz., hydroxylation, dehydroxylation, reduction of the carbonyl moieties, epimerization, side-chain metabolism, introduction of carbon-carbon double bonds into the steroid nucleus, deconjugation of bile acid conjugates carried out by various microorganisms for production of useful metabolites with special reference to newer techniques including cell immobilization and transposon mutagenesis for selective transformations are reviewed. The different pathways of microbial degradation of bile acids leading to the formation of various products are discussed. A compilation of the metabolites formed by various microorganisms from the bile acids or their conjugates and reported during the period 1979-1992 is also provided.     

L-Sorbose production by cells of the strain Gluconobacter suboxydans entrapped in a polyacrylamide gel

Summary It is shown, that bacteria of the strain Gluconobacter suboxydans entrapped in a polyacrylamide gel are capable to convert D-sorbitol to L-sorbose with a sufficiently high reaction rate. The kinetics of the studied process remains the same as it has been found for the case of free cells. Both semicontinuous and continuous patterns are accomplished.     

Effect of serum concentration on retroviral vector production from the amphotropic ψCRIP murine producer cells

The production of ethanol by Saccharomyces cerevisiae immobilized cells and its esterification with oleic acid, catalysed by a lipase from Rhizomucor miehei, was the biochemical process considered as model to illustrate the concept of extractive biocatalysis. The selection of the most suitable support for lipase immobilization was carried out. The best results for the ethanol/oleic acid esterification reaction were obtained with the lipase adsorbed on a polyamide type support, Accurel EP 700. The immobilization method was optimized in terms of immobilization pH, contact time and protein/support ratio. The better performances of the extractive fermentations of ethanol were obtained when entrapped k-carrageenan Saccharomyces cerevisiae cells and a lipase from Rhizomucor miehei, free or immobilized in Accurel EP 700, were used simultaneously. The observed reutilization capacity of the immobilized enzyme could be advantageous for its application in a continuous reactor.     

Immobilization and characterization of Saccharomyces cerevisiae in crosslinked,prepolymerized polyacrylamide-hydrazide

Summary Baker's yeast (Saccharomyces cerevisiae) was immobilized in gels made of prepolymerized, linear, water soluble polyacrylamide, partially substituted with acylhydrazide groups. Gelation was effected by the addition of controlled amounts of dialdehydes (e.g. glyoxal). The immobilized yeasts retained full glycolytic activity. Moreover, the entrapped cells were able to grow inside the chemically corsslinked gel during continuous alcohol production. Glyoxal was found to be the most favourable crosslinking agent for this system. the system employed allowed for the free exchange of substrate and products. The gel surrounding the entrapped cells had no effect on temperature stability profile. On the other hand, substantial enhancement in survival of cells in presence of high ethanol concentrations was recorded for the entrapped yeast. The capability of the immobilized yeast to carry out continuous conversion of glucose to ethanol was demonstrated.     

Immobilization of fructosyltransferase by chitosan and alginate for efficient production of fructooligosaccharides

The effective system of reusing mycelial fructosyltransferase (FTase) immobilized with two polymers, chitosan and alginate were evaluated for continuous production of fructooligosaccharides (FOS). The alginate beads were successfully developed by maintaining spherical conformation of using 0.3% (w/v) sodium alginate with 0.1% (w/v) of CaCl₂ solution for highest transfructosylating activity. The characteristics of free and immobilized FTase were investigated and results showed that optimum pH and temperature of FTase activity were altered by immobilized materials. A successive production of FOS by FTase entrapped alginate beads was observed at an average of 62.96% (w/w) up to 7 days without much losing its activity. The data revealed by HPLC analysis culminate 67.75% (w/w) of FOS formation by FTase entrapped alginate beads and 42.79% (w/w) by chitosan beads in 36 h of enzyme substrate reaction.     

Poly(carbamoylsulphonate) as a matrix for whole cell immobilization - biological characterization

Summary Poly(carbamoylsulphonate) (PCS), a hydrogel matrix of low toxicity for the immobilization of microorganisms was characterized with respect to physiological properties. The survival rates of immobilized Paracoccus denitrificans in PCS were greater than 99 %, the initial division rate of the bacterium inside the gel was the same as of free suspended cells and decreases with increasing cell density within the first days. The polymer has good resistance to microbial degradation and excellent mechanical stability. First results of long term behaviour and kinetic data of nitrifying bacteria entrapped within PCS gel beads are shown.     

Specific assay for endotoxin using immobilized histidine and Limulus amebocyte lysate.

The LAL test is inhibited or enhanced by many substances. To overcome these problems, we have developed a specific endotoxin assay method using an ultrafiltration unit, a fluorometric LAL reagent, and immobilized histidine (which is a specific adsorbent for endotoxins). This method is composed of two steps. The first step is the adsorption of endotoxins. Using immobilized histidine, endotoxins are quantitatively adsorbed on the adsorbent, and the adsorbed endotoxins are separated from LAL-inhibiting or -enhancing substances by the ultrafiltration unit. The second step is the reaction of adsorbed endotoxins with the LAL reagent. The endotoxins adsorbed on immobilized histidine are directly reacted with the LAL reagent in a filter cup and show enough activity for assay. The reproducibility and the accuracy of this method are high, and the recovery of endotoxins from a sample solution is more than 95%. The new endotoxin assay method using immobilized histidine can be utilized for the determination of endotoxins in a solution containing LAL-inhibiting or -enhancing substances such as amino acids and antibiotics instead of requiring employment of the more common gel-clot technique.