Physiological Changes in Rhizobia after Growth in Peat Extract May Be Related to Improved Desiccation Tolerance

Improved survival of peat-cultured rhizobia compared to survival of liquid-cultured cells has been attributed to cellular adaptations during solid-state fermentation in moist peat. We have observed improved desiccation tolerance of Rhizobium leguminosarum bv. trifolii TA1 and Bradyrhizobium japonicum CB1809 after aerobic growth in water extracts of peat. Survival of TA1 grown in crude peat extract was 18-fold greater than that of cells grown in a defined liquid medium but was diminished when cells were grown in different-sized colloidal fractions of peat extract. Survival of CB1809 was generally better when grown in crude peat extract than in the control but was not statistically significant (P > 0.05) and was strongly dependent on peat extract concentration. Accumulation of intracellular trehalose by both TA1 and CB1809 was higher after growth in peat extract than in the defined medium control. Cells grown in water extracts of peat exhibit morphological changes similar to those observed after growth in moist peat. Electron microscopy revealed thickened plasma membranes, with an electron-dense material occupying the periplasmic space in both TA1 and CB1809. Growth in peat extract also resulted in changes to polypeptide expression in both strains, and peptide analysis by liquid chromatography-mass spectrometry indicated increased expression of stress response proteins. Our results suggest that increased capacity for desiccation tolerance in rhizobia is multifactorial, involving the accumulation of trehalose together with increased expression of proteins involved in protection of the cell envelope, repair of DNA damage, oxidative stress responses, and maintenance of stability and integrity of proteins.     

Peat Hydrolysate Medium Optimization for Pullulan Production

Peat hydrolysate, a diluted acid-autoclaved extract of peat, was used as a substrate for the production of the extracellular polysaccharide pullulan by three strains of Aureobasidium pullulans, 140B, 142, and 2552. It was found that the addition of (NH₄)₂SO₄ and K₂HPO₄ as sources of nitrogen and phosphate, respectively, is not necessary for the polysaccharide production. The economically optimized culture medium for large-scale production of pullulan contains peat hydrolysate, 0.05% NaCl, 0.02% MgSO₄, and 0.01% antifoam FG-10. The initial pH of peat hydrolysate medium is adjusted to its optimum value of 6.0 with Ca(OH)₂. The total ingredient cost for the production of each kilogram of pullulan with optimized medium is only 1/10 of that with the nonoptimized medium. In this study, a zero cost for peat hydrolysate was assumed, since it is an effluent of the peat and peat processing industries.     

Inoculant Production with Diluted Liquid Cultures of Rhizobium spp. and Autoclaved Peat: Evaluation of Diluents, Rhizobium spp., Peats, Sterility Requirements, Storage, and Plant Effectiveness

Fully grown broth cultures of various fast- and slow-growing rhizobia were deliberately diluted with various diluents before their aseptic incorporation into autoclaved peat in polypropylene bags (aseptic method) or mixed with the peat autoclaved in trays (tray method). In a factorial experiment with the aseptic method, autoclaved and irradiated peat samples from five countries were used to prepare inoculants with water-diluted cultures of three Rhizobium spp. When distilled water was used as the diluent, the multiplication and survival of rhizobia in the peat was similar to that with diluents having a high nutrient status when the aseptic method was used. In the factorial experiment, the mean viable counts per gram of inoculant were log 9.23 (strain TAL 102) > log 8.92 (strain TAL 82) > log 7.89 (strain TAL 182) after 24 weeks of storage at 28°C. The peat from Argentina was the most superior for the three Rhizobium spp., with a mean viable count of log 9.0 per g at the end of the storage period. The quality of inoculants produced with diluted cultures was significantly (P = 0.05) better with irradiated than with autoclaved peat, as shown from the factorial experiment. With the tray method, rhizobia in cultures diluted 1,000-fold or less multiplied and stored satisfactorily in the presence of postinoculation contaminants, as determined by plate counts, membrane filter immunofluorescence, and plant infection procedures. All strains of rhizobia used in both the methods showed various degrees of population decline in the inoculants when stored at 28°C. Fast- and slow-growing rhizobia in matured inoculants produced by the two methods showed significant (P < 0.01) decline in viability when stored at 4°C, whereas the viability of some strains increased significantly (P < 0.01) at the same temperature. The plant effectiveness of inoculants produced with diluted cultures and autoclaved peat did not differ significantly from that of inoculants produced with undiluted cultures and gamma-irradiated peat.     

Spent mushroom substrates as component of growing media for germination and growth of horticultural plants

This research work was conducted in order to investigate the possibility of using spent mushroom substrate (SMS) in the production of horticultural seedlings replacing part of the peat in the growing media. Three vegetable species with different salt sensitivities, the less sensitive being tomato (Lycopersicon esculentum var. Muchamiel), the moderately salt-sensitive being courgette (Cucurbita pepo L. var. Afrodite F1) and the most salt-sensitive being pepper (Capsicum annum L. var. Lamuyo F1) were grown in 12 media containing SMS of two types of mushroom (Agaricus bisporus (SMS-AB) and Pleurotus ostreatus (SMS-PO)) or a mixture of both 50% (v/v) (SMS-50), as well as peat in various ratios. The proportions of each residue in the mixtures elaborated with peat were 25%, 50%, 75% and 100% v/v residue. A substrate of 100% peat was used as control. The experiment was arranged in a completely-randomised design with two replicates per treatment under greenhouse conditions. Prior to sowing, some physical, physico-chemical and chemical properties of the growing media were determined and seed germination and fresh weight of seedling were also measured. In most of the cases, the addition of SMS to the growing media produced an increase in the pH values, salt contents, macro and micronutrient concentrations and a decrease in the water holding capacity contents in comparison to peat, whereas great differences were found in the air capacity values between SMS-based substrates and peat. Up to 75% SMS can be used in mixtures with peat for seed germination of the plant species studied. Regarding the most suitable SMS-based substrates for plant growth, any substrate could be used for tomato seedling production. However, all SMS-AB-based substrates and the media containing low dose of SMS-PO and SMS-50 were adequate for growth of courgette and pepper.     

The influence of the initial humidity of balneological peat on its pharmacological features]

The viscosity of balneological peat got special meaning according to its thermical features. Until now, there has been no answer on the question in how far balneological peat, which is prepared with different degrees of humidity, can vary the pharmacological character. Aim of this work was, on the one hand, to examine which initial degree of peat-humidity is necessary to get the wished viscosity in therapy when diluted with water. On the other hand, how far the pharmacological character of balneological is influenced by the initial degree of humidity. From peat, with initial different degrees of humidity, balneological peat is prepared, fulfilling the demands of the Quentin-Test and therefore the necessary consistence for therapy. Here in this work the in-vitro effect of aqueous peat extract (APE) on the spontaneous contractile activity of the smooth muscle fibres of guinea-pig stomachs was examined. The APE used got initial different degrees of humidity. It was found out, that the ability of peat according to a new water-uptake, with a initial humidity under 60%, was clearly reduced. Because of the reduced water content of balneological peat its thermical features were deteriorated. This goes for peat with a humidity factor < 60%. First, with the Quentin-Test, showing the optimal viscosity of peat before medical use, you can also make statements according its ability of maximum uptake of water, meaning the ability taking up water until it becomes gel-like. Second, the results show that the initial humidity of peat got no influence on the pharmacological features.     

Studies on the production of Scytalidium acidophilum biomass

Summary The conversion of nutrient-supplemented and non-supplemented acid-extracts from peat to biomass of the acid-resistant fungus Scytalidium acidophilum is described. Yeast extract and several inorganic salts were tested as nutrient supplement to the peat extract in shake-flask experiments and in an agitated and aerated fermentor. The best results were obtained in the fermentor, with 0.3% yeast extract, which produced 6.2 g dry biomass/1 with a yield of 41% and an efficiency of 30%, at 200 rpm and 1.75 vvm in 8 days. Although higher agitation speeds appeared detrimental to the mycelial physiology, it was detected that the dissolved oxygen concentration at 200 rpm could limit the growth of S. acidophilum if higher biomass concentrations are obtained. The potential for utilizing the residual fermentation medium as a plant liquid fertilizer is reported.     

Pressate from Peat Dewatering as a Substrate for Bacterial Growth

This study considered the possibility of using water expressed during the drying of fuel-grade peat as a substrate for microbial growth. Highly humified peat pressed for 2.5 min at 1.96 MPa produced water with a chemical oxygen demand of 690 mg/liter. Several biological compounds could be produced by using the organic matter in expressed peat water as a substrate. These included polymers such as chitosan, contained in the cell wall of Rhizopus arrhizus, and two extracellular polysaccharides, xanthan gum and pullulan, produced by Xanthomonas campestris and Aureobasidium pullulans, respectively. A very effective surfactant was produced by Bacillus subtilis grown in the expressed water. Small additions of nutrients to the peat pressate were necessary to obtain substantial yields of products. The addition of peptone, yeast extract, and glucose improved production of the various compounds. Biological treatment improved the quality of the expressed water to the extent that in an industrial process it could be returned to the environment.     

Composted Green Waste as a Substitute for Peat in Growth Media: Effects on Growth and Nutrition of Calathea insignis

Peat mined from endangered wetland ecosystems is generally used as a component in soilless potting media in horticulture but is a costly and non-renewable natural resource. The objective of this work was to study the feasibility of replacing peat with different percentages (0, 10, 30, 50, 70, 90, and 100%) of composted green waste (CGW) as growth media for the production of the ornamental plant Calathea insignis. Compared with 100% peat media, media containing CGW had improved physical and chemical characteristics to achieve the acceptable ranges. Moreover, CGW addition had increased the stability (i.e., reduced the decomposition rates) of growth media mixtures, as indicated by comparison of particle-size distribution at the start and end of a 7-month greenhouse experiment. Addition of CGW also supported increased plant growth (biomass production, root morphology, nutrient contents, and photosynthetic pigment contents). The physical and chemical characteristics of growth media and plant growth were best with a medium containing 70% CGW and were better in a medium with 100% CGW than in one with 100% peat media. These results indicate that CGW is a viable alternative to peat for the cultivation of Calathea insignis.     

Oral bioavailability of silymarin phytocomplex formulated as self-emulsifying pellets

The objective of this study was to develop new solid self-emulsifying pellets to deliver milk thistle extract (silymarin). These pellets were prepared via extrusion/spheronisation procedure, using a self-emulsifying system or SES (Akoline MCM^®, Miglyol^®, Tween 80^®, soy lecithin and propylene glycol), microcrystalline cellulose and lactose monohydrate. To select the most suitable formulations for extrusion and spheronisation, an experimental design of experiences was adopted. The screening amongst formulations (13 different blends) was performed preparing pellets and evaluating extrusion profiles and quality of the spheronised extrudates. The pellets were characterised for size and shape, density, force required to crush them. Although more than one type of pellets demonstrated adequate morphological and technological characteristics, pellets prepared from formulation 7 revealed the best properties and were selected for further biopharmaceutical investigations, including in vitro dissolution and in vivo trials on rats to study serum and lymph levels after oral administration of the pellets. These preliminary technological and pharmacokinetic data demonstrated that extrusion/spheronisation is a viable technology to produce self-emulsifying pellets of good quality and able to improve in vivo oral bioavailability of main components of a phytotherapeutic extract of more than 100 times by enhancing the lymphatic route of absorption.     

High Survivability of Cheese Whey-Grown Rhizobium meliloti Cells upon Exposure to Physical Stress

Whey, a by-product of the dairy industry, has been found to protect the rhizobia cells during freezing and thawing. Cells of rhizobia grown on whey sustained freezing better at −18°C than did cells grown on mannitol or sucrose. Suspensions of cells grown on whey or mannitol that were suspended in whey performed equally well at −18 and −80°C, with 94 and 100% survival, respectively. Whey-grown rhizobia in pellets withstood desiccation better than did their mannitol-grown equivalents. Rhizobia that were grown on whey and then inoculated onto commercial peat showed a survival rate of 100% after 23 weeks at −4°C. Whey-grown cells in peat performed better at various temperatures during storage, even when they were exposed to desiccation, than did mannitol-grown cells in peat. Whey, therefore, offers interesting possibilities as a Rhizobium protectant for the inoculum industry.     

Acidophilic Methanotrophic Communities from Sphagnum Peat Bogs

Highly enriched methanotrophic communities (>25 serial transfers) were obtained from acidic ombrotrophic peat bogs from four boreal forest sites. The enrichment strategy involved using media conditions that were associated with the highest rates of methane uptake by the original peat samples, namely, the use of diluted mineral medium of low buffering capacity, moderate incubation temperature (20°C), and pH values of 3 to 6. Enriched communities contained a mixture of rod-shaped bacteria arranged in aggregates with a minor contribution of Hyphomicrobium-like cells. The growth stoichiometry of isolates was characteristic of methanotrophic bacteria (CH₄/O₂/CO₂=1:1.1:0.59), with an average apparent yield of 0.41 ± 0.03 g of biomass C/g of CH₄-C. DNA from each enrichment yielded a PCR product of the expected size with primers for both mmoX and mmoY genes of soluble methane monooxygenase. Two types of sequences were obtained for PCR-amplified fragments of mmoX. One of them exhibited high identity to the mmoX protein of the Methylocystis-Methylosinus group, whereas the other showed an equal level of divergence from both the Methylosinus-Methylocystis group and Methylococcus capsulatus (Bath) and formed a distinct branch. The pH optimum for growth and for CH₄ uptake was 4.5 to 5.5, which is very similar to that for the optimum CH₄ uptake observed in the original peat samples. These methanotrophs are moderate acidophiles rather than acidotolerant organisms, since their growth rate and methane uptake were much lower at neutral pH. The growth of the methanotrophic community was enhanced by using media with a very low salt content (20 to 200 mg/liter), more typical of their natural environment. All four enriched communities grew on N-free medium.     

Abundance and diversity of methanotrophic Gammaproteobacteria in northern wetlands

Numeric abundance, identity, and pH preferences of methanotrophic Gammaproteobacteria (type I methanotrophs) inhabiting the northern acidic wetlands were studied. The rates of methane oxidation by peat samples from six wetlands of European Northern Russia (pH 3.9–4.7) varied from 0.04 to 0.60 μg CH₄ g^?1 peat h^?1. The number of cells revealed by hybridization with fluorochrome labeled probes M84 + M705 specific for type I methanotrophs was 0.05–2.16 × 10⁵ cells g^?1 dry peat, i.e., 0.4–12.5% of the total number of methanotrophs and 0.004–0.39% of the total number of bacteria. Analysis of the fragments of the pmoA gene encoding particulate methane monooxygenase revealed predominance of the genus Methylocystis (92% of the clones) in the studied sample of acidic peat, while the proportion of the pmoA sequences of type I methanotrophs was insignificant (8%). PCR amplification of the 16S rRNA gene fragments of type I methanotrophs with TypeIF-Type IR primers had low specificity, since only three sequences out of 53 analyzed belonged to methanotrophs and exhibited 93–99% similarity to those of Methylovulum, Methylomonas, and Methylobacter species. Isolates of type I methanotrophs obtained from peat (strains SH10 and 83A5) were identified as members of the species Methylomonas paludis and Methylovulum miyakonense, respectively. Only Methylomonas paludis SH10 was capable of growth in acidic media (pH range for growth 3.8–7.2 with the optimum at pH 5.8–6.2), while Methylovulum miyakonense 83A5 exhibited the typical growth characteristics of neutrophilic methanotrophs (pH range for growth 5.5–8.0 with the optimum at pH 6.5–7.5).     

Non-Ligninolytic TNT Mineralization in Contaminated Soil by Phanerochaete chrysosporium

The explosive 2,4,6-trinitrotoluene (TNT) is widely used and results in widespread soil contamination. The white-rot fungus Phanerochaete chrysosporium has been shown to degrade TNT, using the peroxidase enzyme. In this study, we report peroxidase-independent degradation of TNT by non-ligninolytic P. chrysosporium. Significant disappearance of TNT from highly contaminated soil using P. chrysosporium has been observed. Soil highly contaminated with TNT (2270 ppm [10 mM]) was diluted to 100 ppm (0.44 mM) with malt extract medium. Pregrown (48 hours) mycelial pellets of P. chrysosporium were added in 100 mL malt extract medium and incubated in Gledhill flasks. Analysis by high-performance liquid chromatography (HPLC) was conducted on soil extracts at specific time points to estimate the disappearance of TNT from contaminated soil incubated with P. chrysosporium. When the pregrown mycelial pellets were added, TNT disappeared within 48 hours. The dissolved concentration of 2-amino-4,6-dinitrotoluene (2Am-DNT) increased up to the third day, then declined before its final disappearance by day 10. Results show that the pregrown mycelial pellets of P. chrysosporium mineralized up to 17.3±6.3% [¹⁴C]-TNT within 30 days.     

The effect of spent mushroom compost on Lecanicillium fungicola in vivo and in vitro

Leached spent mushroom compost (SMC) and its extract were tested to suppress Lecanicillium fungicola in white button mushroom. Sterile and non-sterile mixture of SMC and peat were used to assess suppressiveness against L. fungicola in greenhouse experiments. The extract of SMC was prepared with sterile, non-sterile, filtered, supplied with nystatin, streptomycin and penicillin antibiotics to evaluate their effect in suppression of pathogen in vitro. Isolated bacteria from SMC extract were tested for antagonism rate against Lecanicillium fungicola. The results of the experiments showed that all applications rate of none-sterile SMC were effective in control of pathogen. However, the sterile SMC amendments did not have a positive effect on the pathogen suppression in vitro or in vivo, as was expected. The treatments amended with SMC 100% and 60% showed the most suppressive effect in the control of pathogen. Using of non-sterile SMC 20%, 40%, 60% and peat soil were most effective in mushroom yield. The extract of leached SMC showed inhibition of L. fungicola in petri dishes. Three bacteria isolated from extract, Bacillus subtilis, Bacillus licheniformis and Bacillus amyloliquefacien identified using 16s rRNA, showed an antagonistic effect with the fungal growth.     

Dilution of Liquid Rhizobium Cultures To Increase Production Capacity of Inoculant Plants

Experiments were undertaken to test whether peat-based legume seed inoculants, which are prepared with liquid cultures that have been deliberately diluted, can attain and sustain acceptable numbers of viable rhizobia. Liquid cultures of Rhizobium japonicum and Rhizobium phaseoli were diluted to give 10⁸, 10⁷, or 10⁶ cells per ml, using either deionized water, quarter-strength yeast-mannitol broth, yeast-sucrose broth, or yeast-water. The variously diluted cultures were incorporated into gamma-irradiated peat, and the numbers of viable rhizobia were determined at intervals. In all of the inoculant formulations, the numbers of rhizobia reached similarly high ceiling values by 1 week after incorporation, irrespective not only of the number of cells added initially but also of the nature of the diluent. During week 1 of growth, similar multiplication patterns of the diluted liquid cultures were observed in two different peats. Numbers of rhizobia surviving in the various inoculant formulations were not markedly different after 6 months of storage at 28°C. The method of inoculant preparation did not affect the nitrogen fixation effectiveness of the Rhizobium strains.     

Isomaltulose production from sucrose by Protaminobacter rubrum immobilized in calcium alginate

Different culture conditions for Protaminobacter rubrum and enzymatic reaction parameters were evaluated with the goal of improving isomaltulose production. P. rubrum was grown in a medium with 1% (w/v) cane molasses and 0.5% yeast extract and achieved a maximum cell yield Y_x/s of 0.295 g of cells/g sucrose and a specific growth rate (μ) of 0.192 h⁻¹. The immobilization of P. rubrum cells was carried out with calcium alginate, glutaraldehyde and polyethyleneimine. Stabile immobilized cell pellets were obtained and used 24 times in batch processes. Enzymatic conversion was carried out at different sucrose concentrations and in pH 6 medium with 70% (w/v) sucrose at 30 °C an isomaltulose yield of 89–94% (w/v) was obtained. The specific activity of the P. rubrum immobilized pellets in calcium alginate at 30 °C ranged from 1.6 to 4.0 g isomaltulose g⁻¹ pellet h⁻¹, respectively with 70% and 65% sucrose solution, while in lower sucrose concentration had higher specific activities presumably due to substrate inhibition of the isomaltulose synthase in higher sucrose concentrations.     

Environmental implications of the organic matter structure for white-rot fungus Pleurotus eryngii growth in a tropical climate

White-rot fungi (Pleurotus eryngii) are decomposers of lignocellulosic substrates. The relationship between the structure of humified organic matter and P. eryngii growth, is poorly understood. This study aimed to evaluate the relationship between the growth and development of white-rot fungi (P. eryngii) in two structurally different sources of humified organic matter. Fungus growth and development (mycelium diameter, fresh and dry mycelium mass, mycelium density, and biological yield) were evaluated in experiments with the application of humic substances (HS) extracted from vermicompost (VC) and peat. Both HS were characterized by CP/MAS 13C NMR spectroscopy associated with chemometrics analysis. The HS present different structural characteristics, with those extracted from VC having a predominance of functionalized C-aliphatics (carbohydrates), low hydrophobicity, and a 90% proportion of cellulose/hemicellulose carbon in the composition. HS extracted from peat have a predominance of C-aromatics (lignin fragments), higher hydrophobicity, and a proportion of lignin carbon of up to 80%. The results showed that P. eryngii growth is dependent on the C-cellulosic and C-lignin balance. HS extracted from lignin-rich peat regulates the fungus growth at initial times and sometimes inhibits the biological performance. The highly cellulosic HS from VC regulate the fungus growth at later times and its biological performance.     

澳洲坚果根系溶提物对AM真菌孢子萌发和菌丝生长的影响

澳洲坚果(Macadamia integrifolia)根系甲醇溶提物影响离体培养条件下丛枝菌根真菌孢子生长发育的试验结果表明,澳洲坚果根系甲醇溶提物对离体条件下丛枝菌根真菌(Glomus mosseae和Gigaspora margarita)孢子生长发育有明显的促进作用,能显著提高孢子萌发率,增加菌丝长度。浓度为20%~100%的甲醇溶提物均可显著促进丛枝菌根真菌孢子的生长发育,其孢子萌发率和菌丝长度均显著高于对照,60%的甲醇溶提物效果最明显。Glomus mosseae和Gigaspora margarita孢子萌发率随着甲醇溶提物浓度的升高而增加,60%甲醇溶提物孢子萌发率达到最高,分别为81.7%和76.0%。Glomus mosseae和Gigaspora margarita孢子菌丝长度也表现为随洗脱剂浓度的升高,菌丝生长呈先增强后减弱趋势,洗脱剂浓度为60%时菌丝长度达最长,分别为31.2和28.0 mm。澳洲坚果根系甲醇溶提物中含丰富的黄酮类物质,其含量与甲醇洗脱剂的浓度有关,当浓度为60%时,黄酮类物质含量最高。通过对澳洲坚果根系甲醇溶提物中黄酮类物质含量与丛枝菌根真菌孢子生长发育的相关性分析发现,甲醇溶提物中黄酮类物质含量与离体条件下丛枝菌根真菌孢子的生长发育表现为极显著的正相关。甲醇溶提物中黄酮类物质含量越高,其对丛枝菌根真菌孢子的生长发育促进作用越大。     

Method To Enhance Growth and Sporulation of Pelletized Biocontrol Fungi

The biocontrol fungi Trichoderma harzianum, used to control soilborne plant pathogens, and Beauveria bassiana, used to control insect pests, were formulated as mycelial biomass in alginate pellets with wheat bran added. After drying for 0, 4, or 16 h, pellets were placed in water or in aqueous solutions of polyethylene glycol (PEG) 8000 for 4 to 24 h and then allowed to continue drying. PEG-treated pellets containing T. harzianum showed significantly greater proliferation of hyphae in soil than untreated pellets or pellets treated with water. Production of conidia of T. harzianum from PEG-treated pellets was lower than production from untreated pellets after 4 days, although rates were equivalent after 7 days. In contrast, production of conidia of B. bassiana was significantly more rapid from PEG-treated pellets than from untreated pellets. Biocontrol of soilborne plant pathogens or insect pests may be enhanced by rapid hyphal growth of T. harzianum in soil or rapid sporulation of B. bassiana on foliage, respectively. Therefore, PEG treatment may improve the efficacy of these biocontrol agents.