Opening study on the development of a new biosensor for metal toxicity based on pseudomonas fluorescens pyoverdine

To date, different kinds of biosensing elements have been used effectively for environmental monitoring. Microbial cells seem to be well-suited for this task: they are cheap, adaptable to variable field conditions and give a measurable response to a broad number of chemicals. Among different pollutants, heavy metals are still a major problem for the environment. A reasonable starting point for the selection of a biorecognition element to develop a biosensor for metals could be that of a microorganism that exhibits good mechanisms to cope with metals. Pseudomonads are characterized by the secretion of siderophores (e.g., pyoverdine), low-molecular weight compounds that chelate Fe3+ during iron starvation. Pyoverdine is easily detected by colorimetric assay, and it is suitable for simple online measurements. In this work, in order to evaluate pyoverdine as a biorecognition element for metal detection, the influence of metal ions (Fe3+, Cu2+, Zn2+), but also of temperature, pH and nutrients, on microbial growth and pyoverdine regulation has been studied in P. fluorescens. Each of these variables has been shown to influence the synthesis of siderophore: for instance, the lower the temperature, the higher the production of pyoverdine. Moreover, the concentration of pyoverdine produced in the presence of metals has been compared with the maximum allowable concentrations indicated in international regulations (e.g., 98/83/EC), and a correlation that could be useful to build a colorimetric biosensor has been observed

Bi2O3/Nylon multilayered nanocomposite membrane for the photocatalytic inactivation of waterborne pathogens and degradation of mixed organic pollutants

Worldwide there is an increasing demand for clean water and sanitation systems and any different solutions are under evaluation, including advanced oxidation processes such as photocatalysis. This work describes the scalable synthesis process of an electrospun composite membrane made of Nylon and embedded α/β-Bi2O3 nanoparticles that can be activated by visible light instead of UV light typically used with other nanomaterials (e.g. TiO2). As a proof of concept, the efficacy of the α/β-Bi2O3 electrospun composite membrane in the visible light inactivation of pollutants and pathogens was demonstrated in a Continuous-flow Photocatalytic Membrane Reactor, highlighting the great potential of this advanced photocatalytic process for clean water and sanitation

Rational modification of estrogen receptor by combination of computational and experimental analysis

In this manuscript, we modulate the binding properties of estrogen receptor protein by rationally modifying the amino acid composition of its ligand binding domain. By combining sequence alignment and structural analysis of known estrogen receptor- ligand complexes with computational analysis, we were able to predict estrogen receptor mutants with altered binding properties. These predictions were experimentally confirmed by producing single point variants with up to an order of magnitude increased binding affinity towards some estrogen disrupting chemicals and reaching an half maximal inhibitory concentration (IC50) value of 2 nM for the 17α- ethinylestradiol ligand. Due to increased affinity and stability, utilizing such mutated estrogen receptor instead of the wild type as bio-recognition element would be beneficial in an assay or biosensor

The importance of molecular biology in development, prognosis, treatment and resistance to targeted therapy in gastrointestinal stromal tumors

Gastrointestinal stromal tumors (GISTs) are the commonest mesenchymal tumors of the gastroenteric tract, and are generally believed to originate from the neoplastic transformation of the interstitial cells of Cajal, the pacemaker structures of the stomach and intestine. Exon and genetic mutations (point/deletions) are fundamental for the development of GISTs: the constitutional characteristic of this neoplasm is the presence of the cell surface Kit receptor. Kit is the product of the proto-oncogene cKit, situated in chromosome 4. Ninety-eight percent of GISTs express mutated isoforms of Kit or of PDGFRA (Platelet growth factor receptor a). Kit mutation is the basic condition for autophosphorylation of tyrosine kinase residues in proteins. Autophosphorylation initiates pathogenetic processes in Cajal cells, toward a neoplastic transformation. Imatinib mesilate and, more recently, sunitinib are tyrosine kinase inhibitors, specific antagonists for Kit and PDGFRA, with good activity against GISTs. Most molecular and clinical data currently available concern imatinib. Exon mutations are strategic as prognostic and as predictive factors. In recent years, much evidence suggests that survival, response to therapy and resistance to imatinib are related to different mutations. In the near future, GIST patients will receive treatment differentiated by expressed Kit and PDGFRA mutations, thus truly individualized therapy

Ultrasensitive Ag-coated TiO2 nanotube arrays for flexible SERS-based optofluidic devices

In this study, a novel SERS sensor has been developed for repeatable detection of organic molecules and biological assays. Vertically oriented titania nanotube (TiO2 NT) arrays were grown by ultra-fast anodic oxidation of flexible titanium foils and then decorated with Ag nanoparticles (NPs) through d.c. sputtering deposition at room temperature. A parametric study was carried out taking into account the effect of sputtering parameters on the Ag NP arrangements on the NT surface. The structure morphology was investigated by means of scanning and transmission electron microscopy, evidencing the formation of hexagonal close-packed TiO2 NTs coated with Ag nanoparticles showing tunable diameter and distribution. The substrates were employed in a SERS optofluidic device, consisting of a polydimethylsiloxane cover irreversibly sealed to the silver-coated TiO2 NTs, able to detect Rhodamine molecules in ethanol over a wide range of concentrations down to 10(-14) M, taking advantage of both electromagnetic and chemical enhancements. In order to evaluate the performances of the SERS substrates in terms of biosensing, an optimized protocol for the immobilization of oligonucleotide probes on the metal-dielectric surfaces was developed for verifying the hybridization events