Effect of montmorillonite and the capsular polysaccharide on the flocculation of Klebsiella aerogenes

A study was undertaken on the effect of colloidal montmorillonite and exocellular polysaccharide produced by Klebsiella aerogenes on the flocculation process of the bacterium.The addition of a low concentration of K-montmorillonite (350 g/ml) led to the flocculation of the non-capsulated strain K₅₄A₃ (0) of K. aerogenes. The volume of the sediment was dependent on the relative concentration of the bacteria and the clay. In contrast with its non-capsulated counterpart, the encapsulated strain K₅₄A₃ was more stable in the presence of a low concentration of K-montmorillonite. The flocculation of the cells was affected by the composition of the growth medium, the suspension being more stable when the bacteria were grown on a rich sugar agar. The addition of capsular polysaccharide to the non-capsulated strain reduced or prevented the flocculation process. These results suggest that the capsular polysaccharide, which contain COO- as sole ionogenic groups, probably attach to and neutralize the positive charges at the edges of the clay platelets. Consequently, K-montmorillonite did not cause any flocculation of the cells when the capsular polysaccharide was present.     

Anaerobic Degradation of Biphenyl by the Facultative Anaerobic Strain Citrobacter freundii BS2211

Using a synthetic medium supplemented with biphenyl (a polycyclic aromatic hydrocarbon), a new bacterial strain of Citrobacter freundiiwas isolated from enrichment cultures containing soil and industrial wastewater samples of the Serpukhov Condenser Factory. This strain was found to be capable of degrading biphenyl under anaerobic conditions in the course of nitrate reduction. When the initial concentration of biphenyl in the culture medium equaled 150 mg/ml, the culture with a titer of 10⁹ cells/ml degraded up to 26–28% of biphenyl in 3 days (28°C). At 250 mg/ml, the culture with a titer of 10⁷ cells/ml degraded 15% of biphenyl in 21 days. Approximately 10% of the substrate consumed was utilized completely, whereas the remainder underwent transformation.     

Gene cloning of the maoA gene and overproduction of a soluble monoamine oxidase from Klebsiella aerogenes

Summary We cloned the structural gene for monoamine oxidase (maoA) from Klebsiella aerogenes into a pKI212 vector in an maoA mutant strain of K. aerogenes. Deletion analysis and complementation tests of the recombinant plasmid showed that the maoA gene was located entirely within a 4.1-kb segment. In an maoA mutant strain harbouring the cloned maoA gene, synthesis of monoamine oxidase was induced by addition of tyramine and related compounds. Transfer of a plasmid containing the maoA gene into a monoamine oxidase-producing strain of K. aerogenes W70 resulted in about a 30- to 40-fold increase in total production of the enzyme. When cells of K. aerogenes carrying the plasmid containing the maoA gene were grown with tyramine, more than 85% of the monoamine oxidase was produced in soluble form, whereas the parent strain W70 produced most monoamine oxidase as the membrane-bound form. Offprint requests to: Y. Murooka     

Solid substrate fermentation of leached beet pulp withTrichoderma aureoviride

Optimum production of cellulases on leached beet pulp by native and mutant strains ofTrichoderma aureoviride in column-type, solid-substrate fermenters, at controlled temperature and aeration rate, was with a mutant strain, that produced 11 and 29 filter paper units of activity/g solids on raw and acid pre-treated leached beet pulp, respectively. The former value was 40% higher than in the native strain and 70% higher than in the reference strain. protein enrichment of residual solid was significant in all cases, with values up to 40% of total dry weight. Results are suitable for scale-up to pilot level.     

Cloning and Expression of the Vitreoscilla Hemoglobin Gene in Enterobacter Aerogenes: Effect on Cell Growth and Oxygen Uptake

The hemoglobins found in unicellular organisms show a great deal of chemical reactivity, protecting cells against oxidative stress, and hence have been implicated in a wider variety of potential functions than those traditionally associated with animal and plant hemoglobins. There are well-documented studies showing that bacteria expressing Vitreoscilla hemoglobin (VHb), the first prokaryotic hemoglobin characterized, have better growth and oxygen uptake rates than their VHb counterparts. Here, the expression of VHb, its effect on the growth and antioxidant enzyme status of cells under different culture conditions was studied by cloning the complete regulatory and coding sequences (vgb) for VHb in Enterobacter aerogenes. Contrary to what has been reported for Escherichia coli, the expression of vgb in E.aerogenes decreased several fold under 10% of atmospheric oxygen (2% oxygen) and its growth was not greatly improved by the presence of VHb. Measured either as viable cells or total cell mass, untransformed E. aerogenes grew better than the recombinant strains. At the late exponential phase, however, the vgb-bearing strain was determined to have a higher cell number and total cell mass than the strain bearing only the plasmid vector with no vgb insert. The VHb expressing strain also had an oxygen uptake rate several fold higher than its counterparts. Given that oxidative stress may occur upon elevated oxygen exposure and be balanced by the action of antioxi-dative compounds, the level of antioxidative response of E. aerogenes expressing VHb was also studied. The VHb expressing strain had substantially (1.5–2.6-fold) higher catalase activity than strains not expressing VHb. Both VHb+ and VHb- strains, however, showed similar levels of superoxide dismutase activity. The activity of both enzymes was also growth phase dependent. Stationary phase cells of all strains showed 2–5-fold higher activity for these enzymes than cells at the exponential phase.     

Enzymatic saccharification of pretreated rice straw and biomass production

A comparative study on the saccharification of pretreated rice straw was brought about by using cellulase enzyme produced by Aspergillus terreus ATCC 52430 and its mutant strain UNGI-40. The effect of enzyme and substrate concentrations on the saccharification rate at 24 and 48 were studied. A syrup with 7% sugar concentration was obtained with a 10% substrate concentration for the mutant case, whereas a syrup with 6.8% sugar concentration was obtained with 3.5 times concentrated enzyme from the wild strain. A high saccharification value was obtained with low substrate concentration; the higher the substrate concentration used, the lower the percent saccharification. The glucose content in the hydrolysate comprised 80-82% of total reducing sugars; the remainder was cellobiose and xylose together. The hydrolysate supported the growth of yeasts Candida utilis and Saccharomyces cerevisiae ATCC 52431. A biomass with a 48% protein content was obtained. The essential amino acid composition of yeast biomass was determined.     

Bioproduction of D-Psicose from Allitol with Enterobacter aerogenes IK7: A New Frontier in Rare Ketose Production

D-Psicose, a new alternative sweetener, was produced from allitol by microbial oxidation of the newly isolated strain Enterobacter aerogenes IK7. Cells grown in tryptic soy broth medium (TSB) supplemented with D-mannitol at 37 °C were found to have the best oxidation potential. The cells, owing to broad substrate specificity, oxidized various polyols (tetritol, pentitol, and hexitol) to corresponding rare ketoses. By a resting cell reaction, 10% of allitol was completely transformed to the product D-psicose, which thus becomes economically feasible for the mass production of D-psicose. Finally, the product was crystallized and confirmed to be D-psicose by analytical methods.     

Fermentation of xylose and rice straw hydrolysate to ethanol byCandida shehatae NCL-3501

Candida shehatae NCL-3501 utilized glucose and xylose efficiently in batch cultures. The specific rate of ethanol production was higher with mixtures of glucose and xylose (0.64–0.83 g g^–1 cells d^–1) compared to that with individual sugars (0.38–0.58 g g^–1 cells d^–1). Although the optimum temperature for growth was 30°C, this strain grew and produced appreciable levels of ethanol at 45°C. A stable ethanol yield (0.40–0.43 g g^–1 substrate utilized) was obtained between 10 g L^–1 and 80 g L^–1 of initial xylose concentration. Conversion efficiency was further improved by immobilization of the cells in calcium alginate beads. Free or immobilized cells ofC. shehatae NCL-3501 efficiently utilized sugars present in rice straw hemicellulose hydrolysate, prepared by two different methods, within 48 h. Ethanol yields of 0.45 g g^–1 and 0.5 g g^–1 from autohydrolysate, and 0.37 g g^–1 from acid hydrolysate were produced by free and immobilized cells, respectively.     

Enzyme regeneration during hydrolysis of steam-pretreated willow and requirement for cellulase complex composition

In order to reduce the total enzyme consumption in high-solids static hydrolysis of nonwashed steam-exploded willow Salix caprea by mixed cellulase of Trichoderma reesei + Aspergillus foetidus, two different approaches were proposed. In the first case, the enzyme activity adsorbed on residual solids after extended hydrolysis was used for hydrolysis of the newly added substrate. The initial mixing of fresh and hydrolyzed substrates was sufficient for the adsorbed enzyme redistribution and conversion of the new substrate portion, and permanent mechanical stirring was not required. Feeding of two additional portions of the exploded hardwood adjusted to pH 4 with dry caustic into the reactor with simultaneous replacement of accumulated sugars with fresh buffer (pH 4.5) resulted, on average, in a 90% conversion of cellulose at the final enzyme loading 8 IFPU per g ODM substrate, an average sugar concentration of 12%, and a glucose/xylose ratio of 5:1. In the second approach, weakly adsorbed cellulase fractions were used for static high-solids hydrolysis followed by their ultrafiltration recovery from the resultant sugar syrup. In contrast to the initial cellulase mixture whose residual activity in a syrup did not exceed 5-10% at the end of hydrolysis (48 h), up to 60% of weakly adsorbed enzyme fraction could be separated from sugar syrups by ultrafiltration and then reused. Weakly adsorbed enzymes displayed a hydrolysis efficiency of not less than 80% per IFPU enzyme consumed in extended hydrolysis of pretreated willow as compared to the original enzyme mixture. An electrophoretic study of the weakly adsorbed enzyme fraction identified T. reesei cellobiohydrolase II as the predominant component, whereas clear domination of T. reesei cellobiohydrolase I was found by electrophoresis of proteins tightly bound to hydrolysis residual solids.     

Efficient succinic acid production from high-sugar-content beverages by Actinobacillus succinogenes

This study presents the production of succinic acid (SA) by Actinobacillus succinogenes using high-sugar-content beverages (HSCBs) as feedstock. The aim of this study was the valorization of a by-product stream from the beverage industry for the production of an important building block chemical, such as SA. Three types of commercial beverages were investigated: fruit juices (pineapple and ace), syrups (almond), and soft drinks (cola and lemon). They contained mainly glucose, fructose, and sucrose at high concentration—between 50 and 1,000 g/L. The batch fermentation tests highlighted that A. succinogenes was able to grow on HSCBs supplemented with yeast extract, but also on the unsupplemented fruit juices. Indeed, the bacteria did not grow on the unsupplemented syrup and soft drinks because of the lack of indispensable nutrients. About 30–40 g/L of SA were obtained, depending on the type of HSCB, with yield ranging between 0.75 and 1.00 g_SA/g_S. The prehydrolysis step improved the fermentation performance: SA production was improved by 6–24%, depending on the HSCB, and sugar conversion was improved of about 30–50%.     

Citric acid production from sugar cane molasses by 2-deoxyglucose-resistant mutant strain ofAspergillus niger

Citric acid production from sugar cane molasses byAspergillus niger NIAB 280 was studied in a batch cultivation process. A maximum of 90 g/L total sugar was utilized in citric acid production medium. From the parental strainA. niger, mutant strains showing resistance to 2-deoxyglucose in Vogal's medium containing molasses as a carbon source were induced by γ-irradiation. Among the new series of mutant strains, strain RP7 produced 120 g/L while the parental strain produced 80 g/L citric acid (1.5-fold improvement) from 150 g/L of molasses sugars. The period of citric acid production was shortened from 10 d for the wild-type strain to 6–7 d for the mutant strain. The efficiency of substrate uptake rate with respect to total volume substrate consumption rate,Q _s (g per L per h) and specific substrate consumption rate,q _s (g substrate per g cells per h) revealed that the mutant grew faster than its parent. This indicated that the selected mutant is insensitive to catabolite repression by higher concentrations of sugars for citric acid production. With respect to the product yield coefficient (Y _p/x), volume productivity (Q _p) and specific product yields (q _p), the mutant strain is significantly (p≤0.05) improved over the parental strain.     

Production of high-fructose syrup from date by-products in a packed bed bioreactor using a novel thermostable invertase from Aspergillus awamori

Abstract

Dates by-products (discarded dates) from the sucrose-rich variety of ‘Deglet Nour’ were used as starting biomass to produce high-fructose syrup (HFS) based on an immobilized invertase process. A novel extracellular thermostable invertase obtained from Aspergillus awamori cultivated in submerged medium was induced with sucrose at 1% and used for this purpose. A zymogram of the crude extract showed the presence of a unique enzyme form that was optimally produced on the 5^th day. This enzyme preparation was biochemically characterized and immobilized on acetic acid-solubilized chitosan by covalent binding using glutaraldehyde (Yi = 88%, Ya = 54% and 15.53 U/g). When deployed in a packed bed reactor (PBR), HFS was efficiently and continuously produced from sucrose derived from aqueous date extracts. Feeding with an extract initially containing 139.2 g/L total sugar with 78.6 g/L sucrose at a flow rate of 17 ml/h, 50°C and pH 6 resulted in a conversion factor of 0.95 and a final fructose content in the syrup of 69 g/L.     

Utilization of keratin-containing biowaste to produce biohydrogen

A two-stage fermentation system was constructed to test and demonstrate the feasibility of biohydrogen generation from keratin-rich biowaste. We isolated a novel aerobic Bacillus strain (Bacillus licheniformis KK1) that displays outstanding keratinolytic activity. The isolated strain was employed to convert keratin-containing biowaste into a fermentation product that is rich in amino acids and peptides. The process was optimized for the second fermentation step, in which the product of keratin fermentation—supplemented with essential minerals—was metabolized by Thermococcus litoralis, an anaerobic hyperthermophilic archaeon. T. litoralis grew on the keratin hydrolysate and produced hydrogen gas as a physiological fermentation byproduct. Hyperthermophilic cells utilized the keratin hydrolysate in a similar way as their standard nutrient, i.e., bacto-peptone. The generalization of the findings to protein-rich waste treatment and production of biohydrogen is discussed and possible means of further improvements are listed.The principle, the strain and the results presented in the article together with the potential applications have been submitted for patenting to the Hungarian Patent Office (Ref. No. P0203998)     

Anaerobic degradation of biphenyl by the facultative anaerobic strain Citrobacter freundi BS2211

Using a synthetic medium supplemented with biphenyl (a polycyclic aromatic hydrocarbon), a new bacterial strain of Citrobacter freundii was isolated from enrichment cultures containing soil and industrial wastewater samples of the Serpukhov Condenser Factory. This strain was found to be capable of degrading biphenyl under anaerobic conditions in the course of nitrate reduction. When the initial concentration of biphenyl in culture medium equaled 150 mg/l, the culture with a titer of 10(9) cells/ml degraded up to 26-28% of biphenyl in 3 days (28 degrees C). At 250 mg/l, the culture with a titer of 10(7) cells/ml degraded 15% of biphenyl in 21 days. Approximately 10% of the substrate consumed was utilized completely, whereas the remainder underwent transformation.     

Growth kinetics ofSaccharomyces cerevisiae in batch and fedbatch cultivation using sugarcane molasses and glucose syrup from cassava starch

Growth kinetics ofSaccharomyces cerevisiae in glucose syrup from cassava starch and sugarcane molasses were studied using batch and fed-batch cultivation. The optimum temperature and pH required for growth were 30°C and pH 5.5, respectively. In batch culture the productivity and overall cell yield were 0.31 g L^–1 h^–1 and 0.23 g cells g^–1 sugar, respectively, on glucose syrup and 0.22 g L^–1 h^–1 and 0.18 g cells g^–1 sugar, respectively, on molasses. In fed-batch cultivation, a productivity of 3.12 g L^–1 h^–1 and an overall cell yield of 0.52 g cells g^–1 sugar in glucose syrup cultivation and a productivity of 2.33 g L^–1 h^–1 and an overall cell yield of 0.46 g cells g^–1 sugar were achieved in molasses cultivation by controlling the reducing sugar concentration at its optimum level obtained from the fermentation model. By using an on-line ethanol sensor combined with a porous Teflon^® tubing method in automating the feeding of substrate in the fed-batch culture, a productivity of 2.15 g L^–1 h^–1 with a yield of 0.47 g cells g^–1 sugar was achieved using glucose syrup as substrate when ethanol concentration was kept at a constant level by automatic control.     

Preparation of Radioactive Gibberellins A20, A5 and A8

Many yeasts were isolated from natural sources in the tropics and subtropics by enrichment culture technique, using medium which contained a surfactant. The medium was acidified with citric acid. A strain S–10 belonging to the genus Candida was found to produce itaconic acid. Under suitable conditions in shake culture, a mutant derived from this strain produced the acid at about 35 % yield on the basis of glucose supplied.     

Enzyme recovery in high-solids enzymatic hydrolysis of steam-pretreated willow: Requirements for the enzyme composition

In order to reduce the total enzyme consumption in high-solids static hydrolysis of nonwashed steam-exploded willowSalix caprea by mixed cellulase ofTrichoderma reesei + Aspergillus foetidus, two different approaches were proposed. In the first case, the enzyme activity adsorbed on residual solids after extended hydrolysis was used for hydrolysis of the newly added substrate. The initial mixing of fresh and hydrolyzed substrates was sufficient for the adsorbed enzyme redistribution and conversion of the new substrate portion, and constant mechanical stirring was not required. Feeding of two additional portions of the exploded hardwood adjusted to pH 4 with dry caustic into the reactor with simultaneous replacement of accumulated sugars with fresh buffer (pH 4.5) resulted, on average, in a 90% conversion of cellulose at the final enzyme loading of 8 IFPU per g ODM substrate, an average sugar concentration of 12%, and a glucose/xylose ratio of 5 : 1. In the second approach, weakly adsorbed cellulase fractions were used for static high-solids hydrolysis followed by their ultrafiltration recovery from the resultant sugar syrup. In contrast to the initial cellulase mixture whose residual activity in a syrup did not exceed 5–10% at the end of hydrolysis (48 h), up to 60% of weakly adsorbed enzyme fraction could be separated from sugar syrups by ultrafiltration and then reused. Weakly adsorbed enzymes displayed a hydrolysis efficiency of not less than 80% per IFPU enzyme consumed in extended hydrolysis of pretreated willow as compared to the original enzyme mixture. An electrophoretic study of the weakly adsorbed enzyme fraction identifiedT. reesei cellobiohydrolase II as the predominant component, whereas clear domination ofT. reesei cellobiohydrolase I was found by electrophoresis of proteins tightly bound to residual hydrolysis solids. Deceased     

Cadmium-Resistance Plasmid Affected Cd+2 Uptake More Than Cd+2 Adsorption in Klebsiella oxytoca

A bacterial strain was isolated from Petra City Wastewater Treatment Plant. This isolate was identified as Klebsiella oxytoca based on 16S rDNA analysis. A single plasmid (> 23 kb) was detected in this strain and transformed into Esherichia coli JM83. The transformed E. coli cells exhibited elevated resistance to cadmium as compared to parental plasmid-free cells. The sodium dodecyl sulfate (SDS)-treated cells showed higher efficiency in plasmid curing than the ethidium bromide–treated cells. The ethidium bromide–cured cells grew only in a 10 μ g/ml Cd^{+ 2} minimal tolerable concentration, whereas the SDS-treated cells had no growth in any of the Cd concentrations tested (2, 5, 10, 20, 30, 40, and 50 ppm). Contrary to the Freundlich model, the Langmuir model gave a good fit to the Cd biosorption data by K. oxytoca cells. Plasmid curing caused 80%, 82%, and 70% inhibition in the Cd biosorption, adsorption, and uptake, respectively. Furthermore, the absence of lysine decarboxylase (LDC) activity in the cured strain strongly implies that the structural gene-encoding LDC in this bacterium is plasmid encoded. After curing of the plasmid, 100% of the antibiotic-resistant loci were observed as chromosomal encoded. All of the results shown above indicated that the Cd resistance is plasmid mediated.     

Isolation of infective and effective Frankia strains from root nodules of Alnus acuminata (Betulaceae)

Two Frankia strains were isolated from root nodules of Alnus acuminata collected in the Tucumano-oranense forest, Argentina. Monosporal cultures were obtained by plating a spore suspension of each strain and isolating a single colony. The strains (named AacI and AacIII) showed branched mycelia with polymorphic sporangia and NIR-vesicles. They differed in their ability to use carbon sources: the AacI strain grew well on pyruvate, while the AacIII strain grew on mineral medium supplemented with glucose or, alternatively, with sucrose. The two strains were sensitive to oleandomycin, erythromycin, kanamycin, penicillin G, streptomycin and chloramphenicol at 5 μg/ml. The AcIII strain exhibited a moderate resistance to rifampicin, ampicillin and vancomycin. The nitrogenase activity in vitro of the strains was significantly higher in basal medium without nitrogen than that determined in the presence of ammonium chloride. Both strains were infective on seedlings of Alnus glutinosa, inducing an approximately similar percentage of nodulated plants (80%), although strain AacIII produced a higher number of nodules per plant (≤15) than strain AacI (≤6). They were also effective for nitrogen fixation in planta, determined by the acetylene reduction assay. This revised version was published online in July 2006 with corrections to the Cover Date.     

Use of agarose-entrapped Aspergillus niger cells for the production of citric acid from soy whey

Aspergillus niger cells immobilized in agarose beads were utilized for the productin of citric acid from soy whey, a by-product generated during the tofu-making process. Soy when samples supplemented with 10% sucrose were inoculated with 10% (w/v) free and immobilized cells and incubated at 30°C in a shaker water bath at a speed of 200–220 rpm. Maximal citric acid yields of 21 g/l and 27 g/l with free and immobilized cells, respectively, were recorded on the 10th day under repeated batch conditions.