Biological treatment specific for an industrial wastewater containing s-triazines

Mixed cultures of bacteria grew in medium containing real s-triazine wastes as nitrogen source. About 80% of the s-triazine waste could be degraded as determined by HPLC and by measurements of dissolved nitrogen. The culture required an added carbon source in order to degrade s-triazines. A temperature optimum near 40 degrees C was observed and a salt concentration above about 4% markedly retarded growth and the degradation of s-triazines. This system was examined as a biological treatment for wastes from syntheses of s-triazines.     

Graded potential of neural crest to form cornea, sensory neurons and cartilage along the rostrocaudal axis

Neural crest cells arising from different rostrocaudal axial levels form different sets of derivatives as diverse as ganglia, cartilage and cornea. These variations may be due to intrinsic properties of the cell populations, different environmental factors encountered during migration or some combination thereof. We test the relative roles of intrinsic versus extrinsic factors by challenging the developmental potential of cardiac and trunk neural crest cells via transplantation into an ectopic midbrain environment. We then assess long-term survival and differentiation into diverse derivatives, including cornea, trigeminal ganglion and branchial arch cartilage. Despite their ability to migrate to the periocular region, neither cardiac nor trunk neural crest contribute appropriately to the cornea, with cardiac crest cells often forming ectopic masses on the corneal surface. Similarly, the potential of trunk and cardiac neural crest to form somatosensory neurons in the trigeminal ganglion was significantly reduced compared with control midbrain grafts. Cardiac neural crest exhibited a reduced capacity to form cartilage, contributing only nominally to Meckle's cartilage, whereas trunk neural crest formed no cartilage after transplantation, even when grafted directly into the first branchial arch. These results suggest that neural crest cells along the rostrocaudal axis display a graded loss in developmental potential to form somatosensory neurons and cartilage even after transplantation to a permissive environment. Hox gene expression was transiently maintained in the cardiac neural tube and neural crest at 12 hours post-transplantation to the midbrain, but was subsequently downregulated. This suggests that long-term differences in Hox gene expression cannot account for rostrocaudal differences in developmental potential of neural crest populations in this case.     

High-throughput and multiplexed regeneration buffer scouting for affinity-based interactions

Affinity-based analyses on biosensors depend partly on regeneration between measurements. Regeneration is performed with a buffer that efficiently breaks all interactions between ligand and analyte while maintaining the active binding site of the ligand. We demonstrated a regeneration buffer scouting using the combination of a continuous flow microspotter with a surface plasmon resonance imaging platform to simultaneously test 48 different regeneration buffers on a single biosensor. Optimal regeneration conditions are found within hours and consume little amounts of buffers, analyte, and ligand. This workflow can be applied to any ligand that is coupled through amine, thiol, or streptavidin immobilization.     

A resazurin-based biosensor for organic pollutants

A new rapid biosensor method employing the dye resazurin as an indicator of bacterial respiration has been developed to provide a rapid, facile and specific biosensor for environmental contaminants that does not rely on genetic modification techniques, is suitable for a high-throughput multiwell format, and is ideally suited to resource-constrained environmental monitoring situations. This whole-cell biosensor has been applied to the test analyte toluene using natural toluene-degrading bacteria as the biological component and is competitive with more complex recombinant approaches. The redox-driven biosensor is dependent on the catabolism of a specific compound, concomitantly reducing the redox indicator resazurin to provide the analytical signal in a whole-cell biosensor assay.     

Photosystem II Inhibition by s-Triazines Having Hydrophilic Amino Groups

Photosystem II inhibition by s-triazines having hydrophilic amino groups was examined in isolated spinach chloroplasts. Among them, the hydroxyalkyl- and alkoxyalkylamino derivatives were potent inhibitors. The hydroxyalkylamino-s-triazines seemed to interact with the binding site in a manner different from that of other triazines, since they needed a time to build up to constant inhibition and showed a different thermoluminescence glow peak.     

Neural network optimization for E. coli promoter prediction.

Methods for optimizing the prediction of Escherichia coli RNA polymerase promoter sequences by neural networks are presented. A neural network was trained on a set of 80 known promoter sequences combined with different numbers of random sequences. The conserved -10 region and -35 region of the promoter sequences and a combination of these regions were used in three independent training sets. The prediction accuracy of the resulting weight matrix was tested against a separate set of 30 known promoter sequences and 1500 random sequences. The effects of the network's topology, the extent of training, the number of random sequences in the training set and the effects of different data representations were examined and optimized. Accuracies of 100% on the promoter test set and 98.4% on the random test set were achieved with the optimal parameters.     

Biotreatment of s-triazine-containing wastewater in a fluidized bed reactor

Mixed cultures of microorganisms immobilized on sand were used to degrade s-triazine-containing industrial wastewater in a fluidized bed reactor. Immobilized cell concentrations of up to 18 g/L volatile suspended solids could be achieved with the s-triazines as sole nitrogen source for growth and carbon sources added at a C--N ratio of about 12. Maximal removal efficiencies of 80% of the s-triazines could be maintained only if (a) the bio-film thickness was limited to avoid oxygen deficiency and (b) the carbon source and complete wastewater (/=20-25 h.     

Mineralization of the herbicide atrazine as a carbon source by a Pseudomonas strain.

Strain YAYA6 was isolated from a mixed microbial community that was growing on atrazine as a sole carbon source and formed quantitative amounts of chloride and nitrate. This strain was identified as a member of the true pseudomonad group (RNA group I) and was given the designation DMS 93-99. The growth yield when atrazine was the sole carbon and nitrogen source was 80 g (dry weight) of cells per mol of atrazine, and the cell doubling time was around 11 h. Approximately 20% of [U-ring 14C]atrazine was mineralized during primary degradation of atrazine. After atrazine disappeared from the culture supernatant, mineralization continued until the level of mineralization was more than 50%. Under different experimental conditions 10% of the atrazine supplied initially was converted to cyanuric acid and < 1% was converted to other s-triazines after prolonged incubation. Degradation proceeded via dechlorination and N-dealkylation. Atrazine was degraded until the concentration was circa 0.1 milligrams/liter. We obtained evidence showing that strain YAYA6 has specific uptake mechanisms for atrazine but less specific degradation mechanisms for s-triazines.     

GDH biosensor based off-line capillary immunoassay for alkylphenols and their ethoxylates

The application of a quinoprotein glucose dehydrogenase modified thick-film sensor as label detector in a capillary immunoassay (CIA) for xenoestrogens is presented. The detection of the alkylphenols and their ethoxylates is based on the competition between the analyte and tracer molecules for the binding sites of anti-alkylphenol ethoxylate antibodies. This assay is performed off-line in small disposable PVC capillaries coated with immobilized antibodies. This format allows the combination of the assay with a small portable device potentially useful for on-site environmental monitoring. Beside high amplification the utilization of beta-galactosidase as enzyme label allows the direct combination with a GDH biosensor at optimal pH conditions. The bioelectrocatalytic properties of this biosensor offer an additional amplification and thus allow a very sensitive quantification of 4-aminophenol, generated by the beta-galactosidase. Detection limits of the analytes in the microg/l range were obtained, while other phenolics and surfactants showed no or very little cross reactivity.     

Evaluation of a compact bench top immunoassay analyzer for automatic and near continuous monitoring of a sample for environmental contaminants

A compact bench top immunoassay analyzer is evaluated and shown to possess sufficient automation to allow continuous unattended sampling and measuring while still achieving the theoretical (antibody affinity based) detection limit for analyte. The system is comprised of antigen coated particles in a disposable flow cell held at the focus of a filter fluorometer. Capture of fluorescently labeled antibody from the flow stream is inhibited by analyte in the sample, allowing analyte concentrations to be determined from the fluorescent intensity. The disposable cell was designed to allow easy end user changing of test specificity, e.g. for selection of any member of a panel of environmental contaminants. Standard curves are shown for six analytes of environmental interest, dioxin F114 (2,3,4,7,8-PeCDF), the pesticide Fenitrothion, three coplanar PCBs, including the most toxic, PCB 126, and estradiol. In each case the curves are constructed using antibody concentrations at or below the Kd of the antibody, assuring that the sensitivity shown is limited by the antibody itself rather than the analyzer. The dynamic range for the six analytes investigated ranged from a low of 5 to 340 pM for fenitrothion to a high of 0.8 to 59 nM for dioxin F114, and is correlated to the antibody Kd in every case. Data is also shown for 17 consecutive samples, including both high and low values, measured completely automatically over a period of hours. With further development and characterization, the bench top analyzer is expected to fill an important niche in environmental testing.     

Real-time aptamer quantum dot fluorescent flow sensor

The goal of this work was to develop and test a novel real-time biosensing approach which can be adapted to either environmental or clinical monitoring of biological pathogens. We have developed a working prototype of a real-time aptamer-based fluorescent flow sensor. The sensor utilizes a competitive displacement approach to measure the binding of the analyte, which keeps the nonspecific binding below detectable levels. The complex of surface-immobilized DNA aptamer with fluorescent complementary oligonucleotide releases the oligonucleotide upon binding with a specific target, which is translated by a decrease in fluorescence. Bright and stable fluorescence of quantum dots is utilized for prolonged detection of the analyte in flow conditions. The real-time sensor prototype is developed with previously characterized ATP-specific aptamer and is capable of specifically detecting 0.1 mM of ATP in biological buffer, with a quantitative response up to 5 mM. The developed prototype is portable and easy to use and its design allows further miniaturization and multiplexing. The developed real-time sensing approach can be adapted to a variety of targets of environmental and clinical significance.     

A portable surface plasmon resonance sensor system for real-time monitoring of small to large analytes

Many environmental applications exist for biosensors capable of providing real-time analyses. One pressing current need is monitoring for agents of chemical- and bio-terrorism. These applications require systems that can rapidly detect small organics including nerve agents, toxic proteins, viruses, spores and whole microbes. A second area of application is monitoring for environmental pollutants. Processing of grab samples through chemical laboratories requires significant time delays in the analyses, preventing the rapid mapping and cleanup of chemical spills. The current state of development of miniaturized, integrated surface plasmon resonance (SPR) sensor elements has allowed for the development of inexpensive, portable biosensor systems capable of the simultaneous analysis of multiple analytes. Most of the detection protocols make use of antibodies immobilized on the sensor surface. The Spreeta 2000 SPR biosensor elements manufactured by Texas Instruments provide three channels for each sensor element in the system. A temperature-controlled two-element system that monitors for six analytes is currently in use, and development of an eight element sensor system capable of monitoring up to 24 different analytes will be completed in the near future. Protein toxins can be directly detected and quantified in the low picomolar range. Elimination of false positives and increased sensitivity is provided by secondary antibodies with specificity for different target epitopes, and by sensor element redundancy. Inclusion of more than a single amplification step can push the sensitivity of toxic protein detection to femtomolar levels. The same types of direct detection and amplification protocols are used to monitor for viruses and whole bacteria or spores. Special protocols are required for the detection of small molecules. Either a competition type assay where the presence of analyte inhibits the binding of antibodies to surface-immobilized analyte, or a displacement assay, where antibodies bound to analyte on the sensor surface are displaced by free analyte, can be used. The small molecule detection assays vary in sensitivity from the low micromolar range to the high picomolar.

     

A portable surface plasmon resonance sensor system for real-time monitoring of small to large analytes

Many environmental applications exist for biosensors capable of providing real-time analyses. One pressing current need is monitoring for agents of chemical- and bio-terrorism. These applications require systems that can rapidly detect small organics including nerve agents, toxic proteins, viruses, spores and whole microbes. A second area of application is monitoring for environmental pollutants. Processing of grab samples through chemical laboratories requires significant time delays in the analyses, preventing the rapid mapping and cleanup of chemical spills. The current state of development of miniaturized, integrated surface plasmon resonance (SPR) sensor elements has allowed for the development of inexpensive, portable biosensor systems capable of the simultaneous analysis of multiple analytes. Most of the detection protocols make use of antibodies immobilized on the sensor surface. The Spreeta 2000 SPR biosensor elements manufactured by Texas Instruments provide three channels for each sensor element in the system. A temperature-controlled two-element system that monitors for six analytes is currently in use, and development of an eight element sensor system capable of monitoring up to 24 different analytes will be completed in the near future. Protein toxins can be directly detected and quantified in the low picomolar range. Elimination of false positives and increased sensitivity is provided by secondary antibodies with specificity for different target epitopes, and by sensor element redundancy. Inclusion of more than a single amplification step can push the sensitivity of toxic protein detection to femtomolar levels. The same types of direct detection and amplification protocols are used to monitor for viruses and whole bacteria or spores. Special protocols are required for the detection of small molecules. Either a competition type assay where the presence of analyte inhibits the binding of antibodies to surface-immobilized analyte, or a displacement assay, where antibodies bound to analyte on the sensor surface are displaced by free analyte, can be used. The small molecule detection assays vary in sensitivity from the low micromolar range to the high picomolar.     

The Te-Assay: a black and white method for environmental sample pre-screening exploiting tellurite reduction

We present the tellurite bioassay (Te-Assay) as an alternative approach for quantification of cell viability. The Te-Assay was developed to pre-screen environmental samples for potential bacterial toxicants in which the reduction of tellurite to tellurium is used as a metabolic marker; black phenotype development only occurs in metabolically competent bacteria capable of reducing tellurite (TeO(3)(2-)) to elemental tellurium. The black and white phenotypes equate to nonsignificant or significant impediment of normal metabolic processes, thus permitting the rapid visual assessment of the relative toxicity of environmental samples. Bacterial inocula were exposed in 96-well plates to arrays of diluted analytes or environmental samples before addition of a tellurite to assess cell health/viability. Toxicity was quantified as the analyte concentration at which a 50% reduction in blackness occurred (IC(50)) compared to control wells containing no added analyte. No proprietary strains or reagents are required for Te-Assay, in which characterised strains or recent environmental isolates performed equally well. Strain selection was independent of tellurite-resistance provided that tellurite was reduced intracellularly by active non-growing cells.     

Differentiation of probiotic and environmental Saccharomyces cerevisiae strains in animal feed

Aims: To establish an identification system for probiotic Saccharomyces cerevisiae strains based on artificial neural network (ANN)–assisted Fourier‐transform infrared (FTIR) spectroscopy to improve quality control of animal feed. Methods and Results: The ANN‐based system for differentiating environmental from probiotic S. cerevisiae strains comprises five authorized feed additive strains plus environmental strains isolated from different habitats. A total of 108 isolates were used as reference strains to create the ANN. DHPLC analysis and δ‐PCR were used as reference methods to type probiotic yeast isolates. The performance of the FTIR‐ANN was tested in an internal validation using unknown spectra of each reference strain. This validation step yielded a classification rate of 99·1 %. For an external validation, a test data set comprising 965 spectra of 63 probiotic and environmental S. cerevisiae isolates unknown to the ANN was used, resulting in a classification rate of 98·2 %. Conclusions: Our results demonstrate that probiotic S. cerevisiae strains in feed can be differentiated successfully from environmental isolates using both genotypic approaches and ANN‐based FTIR spectroscopy. Significance and Impact of the Study: FTIR‐based artificial neural network analysis provides a rapid and inexpensive technique for yeast identification both at the species and at the strain level in routine diagnostic laboratories, using a single sample preparation.     

Performance characteristics of a reversible immunosensor with a heterobifunctional enzyme conjugate as signal generator

Factors that control the performance of a reversible immunosensor with an analyte (progesterone)-enzyme (horseradish peroxidase) conjugate as signal generator have been investigated. The conjugate is used in conjunction with two antibodies, which are specific to progesterone and to horseradish peroxidase, immobilized on two spatially separated polypropylene mesh discs. The conjugate and two antibodies are confined to an internal compartment of a microdialyzer by a semipermeable membrane. The small analyte from an external medium permeates across the membrane into the internal compartment where the analyte concentration determines the relative amounts of the bound conjugate on the two solid surfaces. By measuring two signals from the conjugate bound at two separate sites, we experimentally obtained time-response curves to a concentration pulse of the external analyte. A mathematical (kinetic) model describing the sensor system was developed and used for the determination of rate-limiting factors. In semicontinuous monitoring of the analyte concentrations, operation of the immunosensor with the enzyme conjugate as signal generator required special attention to (a) enzyme stability, (b) analyte permeation (dependence on medium components), and (c) kinetics related to the different accessibility to the same antibody of the small analyte (to be measured) vs. the larger counterpart on the enzyme conjugate (for signal generation). (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 56: 221-231, 1997.     

The use of hydrocarbon analyses for environmental assessment and remediation

Battelle Ocean Sciences has developed an analytical approach to identify and’ quantify petroleum products, coal products, and individual hydrocarbon components at trace levels in complex environmental matrices. The hydrocarbon analysis strategy uses capillary gas chromatography/flame ionization detection for alkane and total oil analysis, combined with gas chromatography/mass spectrometry for polynuclear aromatic hydrocarbon analysis. The method provides environmentally realistic analyte detection limits (parts per trillion in water, parts per billion in sediments) and an analyte list that is designed specifically for petroleum and coal‐based products. Results are compared to a detailed computerized library of total, water‐soluble, and degraded hydrocarbon products. The systematic data interpretation strategy maximizes the accuracy of petroleum and coal product identification in environmental matrices and represents a vast improvement over standard EPA methodology.     

Neurorestorative effect of erythropoietin and environmental enrichment in the early stage of stroke recovery

The purpose of this study was to investigate whether erythropoietin (EPO) and environmental enrichment (EE) after hypoxic ischemic insult can prevent brain damage, improve neuronal plasticity, and reduce sensorimotor deficits and whether the combination of EPO and EE has a synergistic effect. Sixty Sprague-Dawley rats were used for this study. The rats were divided into three groups: middle cerebral artery occlusion (MCAO) without treatment, MACO?+?EPO, and MCAO?+?EPO?+?EE. For the behavior test, the foot-fault test and measurement of the crossing time in the parallel bars were used. Infarct volume measurement, Neuronal nuclei (NeuN) immunohistochemistry, western blot of the synaptophysin (SYP), and Growth-Associated protein 43 (GAP-43) were used. On postoperative days (POD) at 1 week and 4 weeks, group of EPO and EE increased the recovery as seen in the behavior test. The infarct volume of the EPO group was 32.4%, the EPO?+?EE group was 28.5%, and the control group was 44.0% on POD 4 weeks. The SYP and GAP-43 expression showed an increase in the EPO and EPO?+?EE group compared with the MCAO group. EPO and EPO?+?EE treatment creates a neurorestorative effect, improved neural plasticity, and reduced sensorimotor deficits. But the synergistic effect of the combination of EPO and EE was significantly not proved. In the results of this study, we suggest that EPO and EE treatment may offer a neruorestoration, which can improve the functional brain disturbance of stroke patients.     

不同浓度的添加剂 N2和 B27对神经干细胞增殖的影响

目的：通过比较添加不同浓度的无血清培养添加剂N2、B27对神经干细胞增殖的影响,探讨一种最优的体外培养大鼠胚胎神经干细胞的方法。方法：分离培养胚胎13．5dSD大鼠的神经干细胞,采用CCK-8细胞计数、BrdU掺入、测量神经球直径的方法,比较不同浓度N2、B27对神经干细胞增殖的影响。结果：N2与B27合用对神经干细胞增殖和成球的作用最为明显,单独添加2％B27的作用优于1％B27和N2组。结论：1％N2和1％B27同时添加更有利于神经干细胞的增殖和自我更新,此方法为神经干细胞的应用提供了实验依据。     

Plasticity in mouse neural crest cells reveals a new patterning role for cranial mesoderm

The anteroposterior identity of cranial neural crest cells is thought to be preprogrammed before these cells emigrate from the neural tube. Here we test this assumption by developing techniques for transposing cells in the hindbrain of mouse embryos, using small numbers of cells in combination with genetic and lineage markers. This technique has uncovered a surprising degree of plasticity with respect to the expression of Hox genes, which can be used as markers of different hindbrain segments and cells, in both hindbrain tissue and cranial neural crest cells. Our analysis shows that the patterning of cranial neural crest cells relies on a balance between permissive and instructive signals, and underscores the importance of cell-community effects. These results reveal a new role for the cranial mesoderm in patterning facial tissues. Furthermore, our findings argue against a permanently fixed prepatterning of the cranial neural crest that is maintained by passive transfer of positional information from the hindbrain to the periphery.