Single cell protein production from bagasse pith pretreated with sodium hydroxide at room temperature

Summary Previous publications have revealed that a pretreatment of lignocellulosic wastes is necessary if they are to be employed as the hydrocarbon source of single cell protein production. A hot alkaline treatment is the most common.We have treated sugar cane bagasse pith with 1% NaOH solution at room temperature, at a NaOH/pith ratio of 10%. Different contact times were used in the experiments. The shortest contact period required for maximum protein production was 24 h at 25° C. A mixed culture of Cellulomonas sp. and Bacillus subtilis was used in the experiments. The values obtained for hemicellulose and cellulose in the treated pith did not differ greatly from those of untreated pith, in contrast the amount of lignin was 33% lower in the treated pith. The effect of reutilization of the alkaline liquor used for the pretreatment of pith upon protein production was also investigated. With four recyclings, there was a NaOH saving of 34.4 kg per 100 kg produced protein as compared to when the liquor was only used once.The quality of the resulting effluents, as measured by the chemical oxygen demand (COD), proved to be very similar for both types of treatment.     

Thermophilic methanogenesis from gelatin by a mixed defined bacterial culture

Summary The fermentation of gelatin by different associations of bacteria, including Thermobacteroides proteolyticus, Methanobacterium sp. and Methanosarcina MP was studied. Experimental vessels were incubated at 55°C. T. proteolyticus growing axenically produced acetate, isovalerate, H₂ and CO₂. Traces of propionate and isobutyrate were detected. Cocultures of T. proteolyticus and Methanobacterium sp. showed an increase in propionate and isobutyrate production. The Thermobacteroides-Methanosarcina association had no effect on metabolism of T. proteolyticus, and acetate was not used.In triculture, growth of Methanosarcina MP occurred on acetate in coculture with T. proteolyticus and Methanobacterium sp. Utilization of H₂ by Methanobacterium sp. in the triculture lowered the H₂ concentration sufficiently to permit acetate utilization by Methanosarcina. Maximum methane production was obtained with the triculture system.     

Thermophilic methanogenesis from pectin by a mixed defined bacterial culture

Thermophilic degradation of pectin was studied in batch cultures at 55°C by different associations of anaerobic bacteria, includingClostridium thermocellum, Methanobacterium sp., andMethanosarcina sp.Clostridium thermocellum alone produced large amounts of methanol along with some isopropanol and H₂. The inoculation ofMethanobacterium sp. in the culture did not affect the metabolism ofC. thermocellum; this demonstrates the absence of interspecies hydrogen transfer. In the presence of the methylotrophicMethanosarcina sp., methanol was reduced to methane without effect on pectin hydrolysis; a small amount of the H₂ produced was also used to reduce methanol.     

Cellulose degradation by a mixed bacterial culture

Summary An integrated mixed bacterial culture consisting of four strains has been isolated by a batch enrichment technique. The cellulolytic member (strain D) is aCellulomonas sp. and the others are non-cellulolytic. The interaction between strains D and C is pronounced and appears to involve an exchange of reducing sugars and growth factors. The symbiotic relationship of this naturally occurring mixed culture is therefore one of mutualism. The filter paper cellulase and carboxymethyl cellulase activities in extracellular fluid are high, while -glucosidase activity is low. The mixed culture digests a variety of lignocellulosics efficiently and is of fundamental interest in the study of microbial interrelationships.     

Thermophilic methanogenesis from sugar beet pulp by a defined mixed bacterial culture

Summary Thermophilic degradation of sugar beet pulp was studied in batch cultures at 55°C by different associations of bacteria, includingClostridium thermocellum,Methanobacterium sp. andMethanosarcina MP.C. thermocellum produced acetate, succinate, methanol, ethanol, H₂ and CO₂. The coculture ofC. thermocellum andMethanobacterium sp. produced trace amounts of ethanol and succinate; acetate concentration was about three times higher than in theC. thermocellum monoculture. The association of this coculture withMethanosarcina MP produced 5.5 mmol CH₄/g dry weight sugar beet pulp.     

Effect of oxygen and air flow on xylanolytic and cellulolytic activity from bacterial cultures grown on bagasse pith

Summary The xylanolytic and cellulolytic activity fromCellulomanas were reduced by high O₂ concentrations in continous culture as well as by an air flow passed trough the samples, suggesting an inhibition or inactivation of enzymes in such conditions.     

Catabolism of terbuthylazine by mixed bacterial culture originating from s-triazine-contaminated soil

The s-triazine herbicide terbuthylazine (TERB) has been used as the main substitute of atrazine in many EU countries for more than 10 years. However, the ecological consequences of this substitution are still not fully understood. Since the fate of triazine herbicides is primarily dependent on microbial degradation, in this paper, we investigated the ability of a mixed bacterial culture, M3-T, originating from s-triazine-contaminated soil, to degrade TERB in liquid culture and soil microcosms. The M3-T culture grown in mineral medium with TERB as the N source and citrate as the C source degraded 50 mg L^?1 of TERB within 3 days of incubation. The culture was capable of degrading TERB as the sole C and N source, though at slower degradation kinetics. A thorough LC-MS analysis of the biodegradation media showed the formation of hydroxyterbuthylazine (TERB-OH) and N-t-butylammelide (TBA) as major metabolites, and desethylterbuthylazine (DET), hydroxydesethylterbuthylazine (DET-OH) and cyanuric acid (CA) as minor metabolites in the TERB degradation pathway. TBA was identified as a bottleneck in the catabolic pathway leading to its transient accumulation in culture media. The supplementation of glucose as the exogenous C source had no effect on TBA degradation, whereas citrate inhibited its disappearance. The addition of M3-T to sterile soil artificially contaminated with TERB at 3 mg kg^?1 of soil resulted in an accelerated TERB degradation with t _1/2 value being about 40 times shorter than that achieved by the native microbial community. Catabolic versatility of M3-T culture makes it a promising seed culture for accelerating biotransformation processes in s-triazine-contaminated environment.     

Characterization of the cellulase complex from Cellulomonas grown on bagasse pith

Summary The effect of physico-chemical parameters on the cellulolytic activity of Cellulomonas sp. IIbc grown on sugarcane bagasse pith was investigated, and the optimum ranges for enzyme activity were established. The cellulases were more stable when incubated at the optimum growth temperature (32°C) than under optimum activity conditions (45°C for -glucosidases and 50°C for CMC- and FP-cellulases). The -glucosidases were the thermostability-limiting enzymes of the complex. Two types of endoglucanases could be recognized according to their adsorption properties on bagasse: one weakly-bound and one tightly-bound type, the latter constituting approximately 73% of the extracellular endoglucanases at exponential growth phase. Four forms active on filter paper and three active on CMC were obtained by HPLC separation of the extracellular fraction of the culture at stationary phase.Abbreviations CMC carboxymethylcellulose - FP filter paper     

甘蔗渣和糖蜜混合发酵制备燃料丁醇

以抗逆突变株Clostridium beijerinckii IB4为研究对象,葡萄糖为C源,对其进行补料分批发酵过程的优化,同时将该优化工艺应用于甘蔗渣和糖蜜混合发酵制备燃料丁醇。结果表明:在5 L发酵罐中,先加入作为还原糖的甘蔗渣酸解糖液10 g/L,16 h后补加甘蔗糖蜜30 g/L,于35℃、100 r/min发酵50 h,丁醇和总溶剂产量分别达到11.1和15.3 g/L,丁醇比例高达72.5%。     

Removal of phenanthrene from soil by co-cultures of bacteria and fungi pregrown on sugarcane bagasse pith

Sixteen co-cultures composed of four bacteria and four fungi grown on sugarcane bagasse pith were tested for phenanthrene degradation in soil. The four bacteria were identified as Pseudomonas aeruginose, Ralstonia pickettii, Pseudomonas sp. and Pseudomonas cepacea. The four fungi were identified as: Penicillium sp., Trichoderma viride, Alternaria tenuis and Aspergillus terrus that were previously isolated from different hydrocarbon-contaminated soils. Fungi had a statistically significant positive (0.0001相似文献   

Primary biodegradation of a series of alkyl sulfosuccinates by mixed bacterial culture

A mixed bacterial culture capable of primary biodegradation of sodium alkyl sulfosuccinates R¹-OOC−CH(SO₃Na)−CH₂−COO−R² was obtained from soil microorganisms by enrichment cultivation and adaptation in the presence of mono-n-dodecyl sulfosuccinate. Gram-negative psychrophilic bacteria with proteolytic, lipolytic and ammonifying activities were prevalent in the culture. The process of primary biodegradation of alkyl sulfosuccinates can be described by firstorder reaction kinetics. The rate constants for linear esters were ascending in the order C₄<C₅<C₆ (45 μmol/min per g cell protein) and further descending with increasing length of the carbon chain C₆>C₈>=C₁₃. Substitution of cyclohexyl for n-hexyl group resulted in fourfold decrease in biodegradation rate. Terminal branching of alkyl chain does not affect the rate of primary biodegradation.     

Degradation and mineralization of 3-chlorobiphenyl by a mixed aerobic bacterial culture

Summary A mixed bacterial culture obtained from polychlorinated-biphenyl-contaminated river sediments proved capable of degrading 3-chlorobiphenyl (3-CB) under aerobic laboratory conditions. Almost total mineralization of 150 mg/l of 3-CB occurred when, after 3 days of incubation, the mineral medium was supplied with benzoic acid as a carbon source. Two strains of Pseudomonas capable of degrading the substrate to 3-chlorobenzoic acid and a strain of Pseudomonas fluorescens capable of co-metabolizing this metabolite were selected from the mixed culture. A nearly stoichiometric amount of chloride, which defines the percentage of total mineralization, was eliminated during mixed culture growth. Offprint requests to: F. Fava     

Biodegradation of two tetrameric lignin model compounds by a mixed bacterial culture

Summary The ability of a mixed bacterial culture to decompose two tetrameric lignin model com-pounds as a sole source of carbon and energy was investigated. The mixed bacterial culture con-sisted mainly of Gram negative rods. The tetram-ers contained two types of lignin substructures, namely the most abundant β-O-4 ether structure in lignin and also the 5-5 biphenyl structure. The tetramer (MW 638) containing two phe-nolic hydroxyls was decomposed readily; after 13 days of incubation, all intermediate products formed were almost totally decomposed. The non-phenolic tetramer (MW 666) was decom-posed much more slowly; after 53 days of incuba-tion, 5% of the substrate was unchanged. When both tetramers were degraded simultaneously, the non-phenolic tetramer was decomposed similarly to the phenolic tetramer. Determination of molecular weights of cata-bolic products showed that the degradation of the non-phenolic tetramer had proceeded at least to dimer level. SKF 525A, inhibitor of cytochrome P-450, caused one catabolic product to accumulate in the culture medium. This indicates involvement of cy-tochrome P-450 in the degradation pathway of the model compounds used. We conclude that this mixed bacterial culture was able to degrade the lignin model compounds used and that free phenolic groups seem to in-crease the biodegradability significantly.     

Aerobic mineralization of chlorobenzoates by a natural polychlorinated biphenyl-degrading mixed bacterial culture

A natural mixed aerobic bacterial culture, designated MIXE1, was found to be capable of degrading several low-chlorinated biphenyls when 4-chlorobiphenyl was used as a co-substrate. MIXE1 was capable of using all the three monochlorobenzoate (CBA) isomers tested as well as 2,5-, 3,4- and 3,5-dichlorobenzoate (dCBA) as the sole carbon and energy source. During MIXE1 growth on these substrates, a nearly stoichiometric amount of chloride was released: 0.5 g/l of each chlorobenzoate was completely mineralized by MIXE1 after 2 or 3 days of culture incubation. Two strains, namely CPE2 and CPE3, were selected from MIXE1: CPE2, referred to the Pseudomonas genus, was found to be capable of totally degrading both 2-CBA and 2,5-dCBA, whereas Alcaligenes strain CPE3 was capable of mineralizing 3-, 4-CBA and 3,4-dCBA. Substrate uptake studies carried out with whole cells of strain CPE2 suggested that 2-CBA was metabolized through catechol, while 2,5-dCBA was degraded via 4-chlorocatechol. 3-CBA, 4-CBA, and 3,4-dCBA appeared to be degraded through 3,4-dihydroxybenzoate by the CPE3 strain. MIXE1, which is capable of degrading several chlorobenzoates, should therefore be able to mineralize a number of low-chlorinated congeners of simple and complex polychlorinated biphenyl mixtures. Correspondence to: F. Fava     

Production of cellulase on sugar cane bagasse by fungal mixed culture solid substrate fermentation

Trichoderma reesei LM-UC4 and its mutant LM-UC4E1 were co-cultured with Aspergillus phoenicis QM329 for cellu-lase production on bagasse by mixed culture solid substrate fermentation. A mutual synergism was observed between the parent Trichoderma strain and the Aspergillus, resulting in enhanced combined biomass production and corresponding increased in cellulase, endoglucanase and b-glucosidase activities. Such synergism was absent with the mutant Trichoderma strain suggesting that in the hypermutation the ability for cooperative interaction with other microbes was lost.     

Proteomic tracking and analysis of a bacterial mixed culture

To improve the understanding of microbial behaviors in communities, proteomic tracking, an approach for relative quantification of species-specific population dynamics of mixed cultures, was developed. Therefore, a bacterial mixed culture was analyzed during batch cultivations with and without addition of the antibiotic Ceftazidime. The community was composed of Burkholderia cepacia, Pseudomonas aeruginosa, and Staphylococcus aureus, pathogens causing infections in cystic fibrosis patients. Gel-based proteomics and mass spectrometry were used to obtain qualitative and quantitative proteomic data. During cultivation, P. aeruginosa became dominant within the mixed culture while S. aureus was inhibited in growth. Analysis of samples - taken along cultivation - revealed about 270 differentially expressed proteins. Some of those proteins are related to bacterial interactions, response to antibiotic treatment or metabolic shifts. For instance, the enzymes PhzS(flavin-containing monooxygenase), PhzD (phenazine biosynthesis protein), and PhzG2 (pyridoxamine 5'-phosphate oxidase) indicated the production of the antibiotic pigment pyocyanine by P. aeruginosa that is related to oxidative stress and therefore, might inhibit growth of S. aureus. Overall, the strategy applied not only allows species-specific tracking of the community composition but also provides valuable insights into the behavior of mixed cultures.     

Biostimulation of micro-organisms from sugarcane bagasse pith for the removal of weathered hydrocarbon from soil

AIMS: In this study we studied the biostimulation of micro-organisms associated with sugarcane bagasse pith for the removal of total petroleum hydrocarbon from a soil contaminated with weathered hydrocarbon. METHODS AND RESULTS: Carbon, nitrogen and phosphorus were added at a ratio of 100 : 10 : 1, water content of 40%, and soil : bagasse ratio of 49 : 1. A significant positive difference (P < 0.05) was observed in total petroleum hydrocarbon removal (38 and 48%) by micro-organisms associated with bagasse and native soil micro-organisms, respectively. In addition, total petroleum hydrocarbon removal increased to 60% in a system where both autochthonous soil and bagasse micro-organisms were present. CONCLUSIONS: Micro-organisms from sugarcane bagasse pith can be stimulated for removal of weathered hydrocarbon from contaminated tropical soils, without they being inhibited by indigenous soil micro-organisms. SIGNIFICANCE AND IMPACT OF THE STUDY: Soil of with hydrocarbons can be diminished by stimulation of autochthonous microflora present in soil and agricultural residues. This work contributes to the microbiology of composting, as low amounts of bulking agents for hydrocarbon removal from soil, can be used.     

Biodegradation of dissolved jet fuel in chemostat by a mixed bacterial culture isolated from a heavily polluted site

A mixed bacterial culture capable of biodegrading of jet fuel was isolated from a heavily polluted site in Tapa, Estonia. Residual concentrations of pollutants in the chemostat culture were determined. The total residual concentrations of dissolved jet fuel in culture medium were 0.42 and 2.1 μg l^-1 at the dilution rates 0.1 and 0.17 h^-1respectively. Benzene, toluene, ethylbenzene, and xylenes were completely degraded and thus not detected in culture broth (detection limit 0.1 μg l^-1)at the dilution rates 0.1 and 0.17 h^-1. The values of apparent substrate saturation constant(K_Sapp) in multisubstrate growth conditions were estimated from the experimental data. The residual concentrations satisfy the regulations in the Republic of Estonia for petroleum hydrocarbons (0.00 mg l^-1 – ‘very good’). Results obtained indicate that use of the biodegradation could be sufficient for the treatment of polluted with kerosene-type jet fuel groundwater up to the acceptable quality. This revised version was published online in August 2006 with corrections to the Cover Date.     

Reduction of nucleic acid content in cell biomass of methanol-utilizing mixed bacterial culture by heat treatment

Summary A heat treatment method to reduce nucleic acid content in cell biomass of a mixed methanol-utilizing bacterial culture was studied. Maximum nucleic acid reduction in the bacterial cells was achieved by using heat shock at 65°C for 5–10 min followed by 2 h incubation at 55°C and 7.2±0.2 pH. In this treatment, 81–85% nucleic acid content was removed from the cells without affecting their true protein content and essential amino acids profile.