Cytotoxic effects of ethylene glycol monomethyl ether in the forelimb bud of the mouse embryo

The role of cytotoxicity in digital maldevelopment in CD-1 mouse embryos was examined following dosage with ethylene glycol monomethyl ether (EGME) on gestation day (gd) 11. Patterns of cell necrosis in the forelimb buds of embryos collected from dams given EGME orally at doses of 100, 250 or 350 mg/kg were characterized by staining with Nile blue A. Cell death was induced in the mesenchymal tissue and to some extent in the limb bud ectoderm, including the apical ectodermal ridge in a dose-related manner. The area of preaxial physiological cell necrosis was enlarged by EGME, and the shape of the limb buds was altered 24 hr after treatment. Preaxial tissue and the predigital chondrocyte condensations were reduced or missing following 250 and 350 mg EGME per 1 kg. Light and electron microscope evaluations of forelimb buds revealed the presence of phagocytic vacuoles and condensed, fragmented cytoplasm, which indicate cytotoxicity, as early as 2 hr following EGME, a maximum effect being observed 6 hr after the dose was administered. Although the severity of the cytotoxic response appeared to be dose-related, comparison with the incidence of digital malformations in near-term fetuses indicates that the loss of mesenchymal tissue is partially compensated for as formation of the limb progresses.     

Aerobic biodegradation of propylene glycol by soil bacteria

Propylene glycol (PG) is a main component of aircraft deicing fluids and its extensive use in Northern airports is a source of soil and groundwater contamination. Bacterial consortia able to grow on PG as sole carbon and energy source were selected from soil samples taken along the runways of Oslo Airport Gardermoen site (Norway). DGGE analysis of enrichment cultures showed that PG-degrading populations were mainly composed by Pseudomonas species, although Bacteroidetes were found, as well. Nineteen bacterial strains, able to grow on PG as sole carbon and energy source, were isolated and identified as different Pseudomonas species. Maximum specific growth rate of mixed cultures in the absence of nutrient limitation was 0.014 h^?1 at 4 °C. Substrate C:N:P molar ratios calculated on the basis of measured growth yields are in good agreement with the suggested values for biostimulation reported in literature. Therefore, the addition of nutrients is suggested as a suitable technique to sustain PG aerobic degradation at the maximum rate by autochthonous microorganisms of unsaturated soil profile.     

Electrocardiographic study of rat fetuses exposed to ethylene glycol monomethyl ether (EGME)

The widely used industrial solvent ethylene glycol monomethyl ether (EGME) is teratogenic to rats and mice, inducing a variety of heart and major vessel abnormalities. In the present study, electrocardiography was used to evaluate heart function in day 20 rat (Sprague-Dawley) fetuses from mothers treated on gestation days 7-13 (sperm = day 1) with 0, 25, or 50 mg/kg EGME by gavage in 10 ml/kg water. The increased incidence of fetuses with cardiovascular malformations (primarily right ductus arteriosus and ventricular septal defect) and abnormal electrocardiograms (EKG) was dose dependent. The most prevalent EKG abnormality was a prolonged QRS wave. Mean QRS intervals were not significantly increased by EGME exposure, but there were significantly more litters in the 50-mg/kg EGME group that had one or more fetuses with QRS complexes of 40 msec or longer. The enhanced duration and the appearance of the aberrant QRS's suggested the presence of an intraventricular conduction delay in these fetuses. Heart rate and other EKG characteristics such as the P wave or P-R and Q-T intervals were not significantly affected by exposure to EGME. There did not appear to be an association between abnormal EKG's and fetal heart dysmorphology.     

Stage specific effect during one seminiferous epithelial cycle following ethylene glycol monomethyl ether exposure in rats.

Stage specific effect of single oral dose (500 mg/kg body wt) of ethylene glycol monomethyl ether (EGME) was characterised during one cycle of seminiferous epithelium in rats. Maximum peritubular membrane damage and germinal epithelial distortion were observed at stages IX-XII. Cell death occurred during conversion of zygotene to pachytene spermatocytes (stage XIII) and between dividing spermatocytes and step I spermatids (stage late XIII-XIV). Profound effect was noted during first meiotic division than during second meiotic division. Presence of multinucleated secondary spermatocytes indicated cytokinesis arrest. The spermatogenesis was delayed and consequently frequency of tubules at stages I-VIII was reduced by day 10. Many of the tubules were devoid of round spermatids on day 12. Possibly, EGME (or it's metabolite) distorted the barrier system at stages IX-XIV and damaged the cells mostly at stages XII-early XIV.     

Cometabolic biodegradation of methyl tert-butyl ether by a soil consortium: Effect of components present in gasoline

A soil consortium was tested for its ability to degrade reformulated gasoline, containing methyl tert-butyl ether (MTBE). Reformulated gasoline was rapidly degraded to completion. However, MTBE tested alone was not degraded. A screening was carried out to identify compounds in gasoline that participate in cometabolism with MTBE. Aromatic compounds (benzene, toluene, xylenes) and compounds structurally similar to MTBE (tert-butanol, 2,2-dimethylbutane, 2,2,4-trimethylpentane) were unable to cometabolize MTBE. Cyclohexane was resistant to degradation. However, all n-alkanes tested for cometabolic activity (pentane, hexane, heptane) did enable the biodegradation of MTBE. Among the alkanes tested, pentane was the most efficient (200 &mgr;g/day). Upon the depletion of pentane, the consortium stopped degrading MTBE. When the consortium was spiked with pentane, MTBE degradation continued. When the ratio of MTBE to pentane was increased, the amount of MTBE degraded by the consortium was higher. Finally, diethylether was tested for cometabolic degradation with MTBE. Both compounds were degraded, but the process differed from that observed with pentane.     

Anaerobic biodegradation of no. 2 diesel fuel in soil: a soil column study

Soil and sediments are contaminated with petroleum hydrocarbons in many parts of the world. Anaerobic degradation of petroleum hydrocarbon is very relevant in removing oil spills in the anaerobic zones of soil and sediments. This research investigates the possibility of degrading no. diesel fuel under anaerobic conditions. Anaerobic packed soil columns were used to simulate and study in situ bioremediation of soil contaminated with diesel fuel. Several anaerobic conditions were evaluated in soil columns, including sulfate reducing, nitrate reducing, methanogenic, and mixed electron acceptor conditions. The objectives were to determine the extent of diesel fuel degradation in soil columns under various anaerobic conditions and identify the best conditions for efficient removal of diesel fuel. Diesel fuels were degraded significantly under all conditions compared to no electron supplemented soil column (natural attenuation). However, the rate of diesel degradation was the highest under mixed electron acceptor conditions followed in order by sulfate reducing, nitrate reducing, and methanogenic conditions. Under mixed electron acceptor condition 81% of diesel fuel was degraded within 310 days. While under sulfate reducing condition 54.5% degradation of diesel fuel was observed for the same period. This study showed evidence for diesel fuel metabolism in a mixed microbial population system similar to any contaminated field sites, where heterogeneous microbial population exists.     

表面活性剂TW-80对土壤中多环芳烃生物降解的影响

以表面活性剂TW80为供试物,进行了为期150d的实验研究,并分别在30、60和150d间隔采样监测PAHs降解率。结果表明,30d后,土壤中PAHs的降解率达90%,比对照提高约30%.60d后,浓度为10000mg·kg^-1表面活性剂的土壤和对照中,PAHs降解率从65.1%和60%迅速提高到93.8%和79.2%.其它处理中,PAHs的平均降解率仅比30d的结果提高4%.150d后,所有处理中PAHs的降解率均达到90%以上。可以认为,表面活性剂能提高PAHs的生物可利用性,加快PAHs的降解速率,从而减少污染暴露时间。但表面活性剂浓度过高可抑制微生物活性。研究还发现,TW80土壤中含有优势真菌。经鉴定为常见青霉、蠕形青霉、淡紫青霉和顶孢头孢霉。它们是土壤PAHs迅速降解的动因.     

Effect of ethanol on the biodegradation of gasoline in an unsaturated tropical soil

Leaking underground storage tanks are a worldwide problem nowadays, therefore gasoline degradation and distribution in the subsurface have been widely studied. Brazil is the only country to currently use ethanol as fuel and as an oxygenate additive to gasoline, in amounts varying from 20 to 26% v/v. Consequently, both gasoline and ethanol may contaminate the environment when spills and leaks occur. Some authors suggest that despite the high degradability of gasoline, its degradation in the aquifer is hindered by the preferential biodegradation of ethanol, which would delay gasoline degradation; however, processes in the unsaturated zone are far less understood. The present study concentrates on degradation and distribution processes of ethanol-amended gasoline in tropical soil under unsaturated conditions. A multi-parametrical approach was adopted to assess the effects of ethanol on the fate of gasoline. Undisturbed natural soil was used to evaluate biodegradation processes while tank experiments determined differences in infiltration, distribution and retention of gasoline in unsaturated artificial porous medium. Physical, chemical and microbiological results suggest that ethanol enhances BTEX retention in soil, boosts microbial activity but delays BTEX biodegradation.     

Effect of heat treatments on stability of altemariol, alternariol monomethyl ether and tenuazonic acid in sunflower flour

A study was carried out to evaluate the effect of heat treatment on the stability of alternariol (AOH), alternariol monomethyl ether (AME) and tenuazonic acid (TeA) in sunflower flour and the effectiveness of this treatment by a biological assay in rats. The concentrations of AOH and AME remained constant during heating at 100°C for up to 90 minutes while TeA concentration decreased with time to 50% after 90 minutes. The most effective treatment in reducing AOH and AME levels was heating at 121°C for 60 minutes. Histopathological evaluation in the biological assay in rats fed withAlternaria toxins showed marked atrophy and fusion of villi in the intestines and liver cell damage; these lesions were less severe in rats fed heat-treated sunflower flour in line with the reduced toxin content. However, a lower weight gain and a noticeable renal damage in rats were produced when they fed decontaminated flour.     

Effect of soil/contaminant interactions on the biodegradation of naphthalene in flooded soil under denitrifying conditions

Summary The mineralization of ¹⁴C-labelled naphthalene was studied in pristine and oil-contaminated soil slurry (30% solids) under denitrifying conditions using a range of concentrations from below to above the aqueous phase saturation level. Results from sorption-desorption experiments indicated that naphthalene desorption was highly irreversible and decreased with an increase in the soil organic content, thus influencing the availability for microbial consumption. Under denitrifying conditions, the mineralization of naphthalene to CO₂ occurred in parallel with the consumption of nitrate and an increase in pH from 7.0 to 8.6. When the initial substrate concentration was 50 ppm (i.e. close to the aqueous phase saturation level), about 90% of the total naphthalene was mineralized within 50 days, and a maximum mineralization rate of 1.3 ppm day^–1 was achieved after a lag period of approx. 18 days. When added at concentrations higher than the aqueous phase saturation level (200 and 500 ppm), similar mineralization rates (1.8 ppm day^–1) occurred until about 50 ppm of the naphthalene was mineralized. After that the mineralization rates decreased logarithmically to a minimum of 0.24 ppm day^–1 for the rest of the 160 days of the experiments. For both of these higher concentrations, the reaction kinetics were independent of the concentration, indicating that desorption of the substrate governs the mineralization rate. Other results indicated that pre-exposure of soil to oil contamination did not improve the degradation rates nor reduce the lag periods. This study clearly shows the potential of denitrifying conditions for the biodegradation of low molecular weight PAHs. Offprint requests to: R. Samson     

Light inhibits the production of alternariol and alternariol monomethyl ether in Alternaria alternata

Alternaria alternata (Fr.) Keissler, grown in drop culture, produced alternariol and alternariol monomethyl ether in late growth phase. Production was almost completely inhibited when the fungal cultures were exposed to white light (180 W/m2), although mycelial dry weight was not significantly affected. The fungus was most sensitive to light during the exponential growth phase. Twelve hours of light exposure was sufficient to decrease significantly the production of the secondary metabolites. In light the fungus produced a red-brown pigment of unknown nature.     

Methyl tert-butyl ether biodegradation by microbial consortia obtained from soil samples of gasoline-polluted sites in Mexico

Microbial consortia obtained from soil samples of gasoline-polluted sites were individually enriched with pentane, hexane, isooctane and toluene. Cometabolism with methyl tert-butyl ether, (MTBE), gave maximum degradation rates of 49, 12, 32 and 0 mg g(-1)protein h(-1), respectively. MTBE was fully degraded even when pentane was completely depleted with a cometabolic coefficient of 1 mgMTBE mg(-1)pentane. The analysis of 16S rDNA from isolated microorganisms in the pentane-adapted consortia showed that microorganisms could be assigned to Pseudomonas. This is the first work reporting the cometabolic mineralization of MTBE by consortium of this genus.     

Natural occurrence of alternariol and alternariol monomethyl ether in soya beans

The natural occurrence of alternariol (AOH) and alternariol monomethyl ether (AME) in soya beans harvested in Argentina was evaluated. Both toxins were simultaneously detected by using HPLC analysis coupled with a solid phase extraction column clean-up. Characteristics of this in-house method such as accuracy, precision and detection and quantification limits were defined by means of recovery test with spiked soya bean samples. Out of 50 soya bean samples, 60% showed contamination with the mycotoxins analyzed; among them, 16% were only contaminated with AOH and 14% just with AME. Fifteen of the positive samples showed co-occurrence of both mycotoxins analyzed. AOH was detected in concentrations ranging from 25 to 211?ng/g, whereas AME was found in concentrations ranging from 62 to 1,153?ng/g. Although a limited number of samples were evaluated, this is the first report on the natural occurrence of Alternaria toxins in soya beans and is relevant from the point of view of animal public health.     

Effect of fuel burning on the microbial population of soil

An attempt was made to study the effect of different amount of fuel burning on the microbial populations of forest soil. Maximum effect of fire was observed in the surface layer of soil and not much variation was seen in the distribution of soil microflora. However, with increasing amount of fuel burned, the effect became higher, microorganisms being destroyed to a depth of 70 mm. Qualitatively, there was no significant difference in the composition of fungal species in comparison with the control soil. Similar types of fungal species were isolated from all the types of burned soil,Aspergillus, Penicillium, Trichoderma, Fusarium andPhoma being the predominant genera. This research was supported by the Department of Science and Technology, Government of India, under the Man and Biosphere Programme.     

The effects of carbon sources and micronutrients in fermented whey on the biodegradation of n-hexadecane in diesel fuel contaminated soil

Fermented whey has previously been shown to stimulate biodegradation of n-hexadecane in diesel contaminated soils. The proposed explanation for the stimulatory effect is that fermented whey provides easily accessible carbon and micronutrients, which give rise to an increased degrading biomass.The objective of this work has been to investigate the role of the different carbon sources and vitamins in fermented whey on the microbial degradation of n-hexadecane in soil.The effects of lactose, lactate, vitamins and free amino acids were tested in combinations according to a full factorial design experiment, at concentrations corresponding to those present in fermented whey. The target substance was ¹⁴C-labeled n-hexadecane in nutrient amended soil microcosms contaminated with 5000 mg diesel fuel kg⁻¹ dw. Biodegradation was monitored by determination of evolved ¹⁴CO₂.Significant effects on the biodegradation of n-hexadecane were observed for lactate and amino acids additions in a sandy soil. Lactate showed both an inhibitory effect in the early phase of the experiment and a stimulatory effect in the later phase. The effect of amino acids was slightly stimulatory, mainly evident as a shortening of the lag time.The degree of n-hexadecane degradation at the end of the experiment was correlated with the total concentration of organic compounds added to the soil.Scientific relevanceThere are a handful papers describing the potential of using organic amendments (often industrial by-products) with a content of both easily accessible carbon and micronutrients, to enhance the bioremediation of polluted soils. Enhanced biodegradation is often reported and the proposed explanations are that the combination of easily accessible carbon and micronutrients increases the degrading biomass.In this paper, we examine the effect of fermented whey on the degradation of n-hexadecane and correlate the observed effects on the biodegradation with the main components lactate, amino acids, lactose and B-vitamins. This has to our knowledge never been done before.     

Synthesis, characterization, and biodegradation of novel poly(ether ester amide)s based on L-phenylalanine and oligoethylene glycol

A new family of novel biodegradable poly(ether ester amide)s (PEEAs) consisting of three building blocks (L-phenylalanine, oligoethylene glycol, and aliphatic acid dichloride) were synthesized by solution polycondensation. Using N,N-dimethylacetamide as the solvent, these PEEA polymers were obtained with fairly good yields with reduced viscosity (eta(red)) ranging from 0.13 to 0.61 dL/g. The chemical structures of the PEEAs were confirmed by IR, NMR spectra, and elemental analysis. The PEEAs had Tg values lower than that of the saturated poly(ester amide)s (PEAs) of similar structures due to the incorporation of ether bonds in the backbones. An increase in the number of ether bonds in PEEA resulted in a lower Tg value. The solubility of the PEEA polymers in a wide range of common organic solvents was significantly improved when compared with unsaturated PEAs. The preliminary in vitro biodegradation behaviors of PEEA polymers were investigated in both pure PBS buffer and alpha-chymotrypsin solution of different concentrations. The polymers showed a significantly faster weight loss in an enzyme solution (alpha-chymotrypsin) but a very slow biodegradation rate in pure PBS buffer. The enzymatic hydrolysis rates of PEEAs (in terms of weight loss) were found to be much faster than those of saturated and unsaturated polyesteramides reported in previous studies. The zero-order-like biodegradation kinetics and molecular weight data also suggested surface erosion biodegradation mechanisms for these PEEAs.     

Effect of a non-ionic surfactant added to the soil surface on the biodegradation of aromatic hydrocarbons within the soil

A study was conducted to determine whether a non-ionic surfactant (Novel II 1412-56) added to the surface of Lima silt loam would enhance the biodegradation of phenanthrene and biphenyl present within the soil. Water containing the surfactant at concentrations of 10 and 100 g/ml was pumped through the soil. At 10 g/ml, Novel II 1412-56 markedly enhanced the rate and extent of phenathrene mineralization and the extent but not the initial rate of biphenyl mineralization. The stimulation was less if the water added to the soil surface contained 100 g surfactant/ml. Addition of the surfactant at the two concentrations did not result in leaching of either phenanthrene or biphenyl, but products of the degradation were found in the soil leachate with or without the surfactant. We suggest that surfactants at low concentrations may be useful for in-situ bioremediation of sites contaminated with hydrophobic pollutants without causing movement of the parent compounds to ground-waters.     

Light inhibits the production of alternariol and alternariol monomethyl ether in Alternaria alternata.

Alternaria alternata (Fr.) Keissler, grown in drop culture, produced alternariol and alternariol monomethyl ether in late growth phase. Production was almost completely inhibited when the fungal cultures were exposed to white light (180 W/m2), although mycelial dry weight was not significantly affected. The fungus was most sensitive to light during the exponential growth phase. Twelve hours of light exposure was sufficient to decrease significantly the production of the secondary metabolites. In light the fungus produced a red-brown pigment of unknown nature.     

Effect of protein hydrolysate on the degradation of diesel fuel in soil*

The addition of protein hydrolysate solution to soil contaminated with diesel fuel was investigated for effects on diesel degradation. The application of protein hydrolysate solution led to an increase in the removal of diesel from the soil. At the end of the 21d experimental period the amount of diesel removed from the soil was 21% greater with the addition of protein hydrolysate solution when compared to a control system. This increased removal was linked to increases in both the number of hydrocarbon degrading micro-organisms, and an extension to their period of activity.     

Aerobic biodegradation of methyl tert-butyl ether (MTBE) by pure bacterialcultures isolated from contaminated soil

Summary Methyl tert-Butyl Ether (MTBE) has been used in gasoline as a substitute for lead-based additives, which have been demonstrated to be toxic. MTBE however, is persistent in soil and water, showing high affinity for water and low affinity for soil, and has become an important contaminant. Therefore, the aim of this work was to isolate and identify soil microorganisms capable of degrading MTBE. Two samples were taken from a gasoline-contaminated soil at a service station and 59 different bacterial strains were isolated by enrichment culture with three consecutive selective transfers. Biochemical and morphological characterization of the bacterial isolates classified them into the following groups: Bacillus, Rhodococcus, Micrococcus, Aureobacterium and Proteus. Twelve strains were selected for evaluation of MTBE biodegradation depending on visual growth and biomass production of the isolates in minimal salt broth. Six strains significantly reduced MTBE concentration (22–37%) compared to an abiotic control after 5 days of incubation. Although it has been considered that MTBE is degraded mainly by cometabolism, our results demonstrate that these microorganisms are able to reduce MTBE concentration when MTBE is the sole source of carbon.