The fluorescent monomeric protein Kusabira Orange. Pressure effect on its structure and stability.

The structure and stability of the fluorescent protein monomeric Kusabira Orange (mKO), a GFP-like protein, was studied under different pressure levels and in different chemical environments. At different pH values (between pH 7.4 and pH 4.0) and under a pressure up to 600 MPa (at 25 °C), mKO did not show significant fluorescence spectral changes, indicating a structural stability of the protein. In more extreme chemical conditions (at pH 4.0 in the presence of 0.8 M guanidine hydrochloride), a marked reduction of mKO fluorescence intensity emission was observed at pressures above 300 MPa. This fluorescence emission quenching may be due to the loss of the intermolecular bonds and, consequently, to the destructuration of the mKO chromophore structure. Since the electrostatic and hydrophobic interactions as well as the salt bridges present in proteins are usually perturbed under high pressure, the reduction of mKO fluorescence intensity emission is associated to the perturbation of the protein salt bridges network.

A surface acoustic wave bio-electronic nose for detection of volatile odorant molecules.

In this work, a "bio-electronic nose" for vapour phase detection of odorant molecules based on surface acoustic wave (SAW) resonators is presented. The biosensor system is composed of an array of five SAW resonators coated with three types of odorant-binding proteins (OBPs): the wild-type OBP from bovine (wtbOBP), a double-mutant of the OBP from bovine (dmbOBP), and the wild-type OBP from pig (wtpOBP). High resolution deposition of OBPs onto the active area of SAW resonators was implemented through laser-induced forward transfer (LIFT). The resonant frequency shifts of the SAW resonators after the deposition of the biomolecules confirmed the immobilisation of the proteins onto the Al/Au inter-digital transducers (IDTs). In addition, a low increase of insertion losses with a limited degradation of Q-factors is reported. The "bio-electronic nose" fabricated by LIFT is tested in nitrogen upon exposure to separated concentrations of R-(-)-1-octen-3-ol (octenol) and R-(-)-carvone (carvone) vapours. The "bio-electronic nose" showed low detection limits for the tested compounds (i.e. 0.48 ppm for the detection of octenol, and 0.74 ppm for the detection of carvone). In addition, the bio-sensing system was able to discriminate the octenol molecules from the carvone molecules, making it pertinent for the assessment of food contamination by moulds, or for the evaluation of indoor air quality in buildings.

Correlation between fluorescence and structure in the orange-emitting GFP-like protein, monomeric Kusabira Orange.

The mKO is the monomeric version of Kusabira Orange, a GFP-like protein emitting bright orange fluorescence at 559 nm. This protein shows the characteristic ß-barrel motif typical of the fluorescent protein family which it belongs to, similar spectral properties to the tetrameric form and an exceptional photo-stability to pH changes. Here, we demonstrate that mKO in solution at physiological pH exhibits a secondary structure analogue to that of the crystal. Moreover, we describe the thermal unfolding, revealing an outstanding structural stability with a denaturation temperature close to 90 °C and identifying the existence of a thermodynamic intermediate. The denaturation process of mKO results to be absolutely irreversible because of the complete lost of the native structure and the consequent aggregation, while the presence of the intermediate state is most likely due to coexistence of two different species of mKO, with protonated and deprotonated chromophore respectively, that affects the fluorescence properties and the structural stability of the protein.

Detection of odorant molecules via surface acoustic wave biosensor array based on odorant-binding proteins.

In this paper, we present an array of biosensors for vapour phase detection of odorant molecules based on surface acoustic wave (SAW) resonators coated with odorant-binding proteins (OBPs). For the first time, the sensing capabilities of three different OBPs, as sensitive layers for SAW devices, are studied and compared. The SAW biosensor array is composed of three SAW devices coated by the droplet method with the wild-type OBP from cow (wtbOBP), a double mutant of the OBP from cow (dmbOBP) and the wild-type OBP from pig (wtpOBP). An uncoated device is used to compensate the variations of the environmental parameters. The SAW devices consist of two-port resonators fabricated on quartz (ST-cut, x propagation) with electrodes made of aluminium covered with a thin gold film (2 nm thick). The obtained surface densities of OBP layers are between 1.18×10(-6) kg/m(2) and 2.31×10(-6) kg/m(2) and were calculated measuring the resonant frequency shift of the SAW devices after the coating. The SAW biosensor array was tested in nitrogen upon exposure to vapours of R-(-)-1-octen-3-ol (octenol), in the range of concentration between 13 and 61 ppm, and R-(-)-carvone (carvone), in the range between 9 and 80 ppm. The highest sensitivity for detection of octenol (25.9 Hz/ppm) was obtained using the wtpOBP-based SAW biosensor, while the highest sensitivity for detection of carvone (9.2 Hz/ppm) was obtained using the dmbOBP-based SAW biosensor.

Amino acid transport in thermophiles: characterization of an arginine-binding protein from Thermotoga maritima. 3. Conformational dynamics and stability.

Arginine-binding protein from Thermotoga maritima (TmArgBP) is a 27.7 kDa protein possessing the typical two domain structure of the periplasmic binding protein family. The protein is characterized by high specificity and affinity for binding a single molecule of l-arginine. In this work, the effect of temperature and/or guanidine hydrochloride on structure and stability of the protein in the absence and in the presence of l-arginine has been investigated by differential scanning calorimetry, far-UV circular dichroism and intrinsic tryptophan phosphorescence and fluorescence. The results revealed that TmArgBP undergoes an irreversible one-step thermal unfolding process in a cooperative mode. The TmArgBP melting temperature was recorded at 115 °C. The presence of l-arginine did not change the protein secondary structure content as well as the intrinsic phosphorescence and fluorescence protein properties, even if it increases the structural stability of the protein. The obtained results are discussed in combination with a detailed inspection of the three-dimensional structure of the protein.

New trends in bio/nanotechnology: stable proteins as advanced molecular tools for health and environment.

In this work the thermophilic trehalose/maltose-binding protein from Thermococcus litoralis is presented as a probe for the design of a high stable fluorescence biosensor for glucose. In particular, we show the possibility of modulating the protein specificity by changing temperature. In addition to glucose sensing, we also report on the possibility of utilizing odorant-binding proteins as a probe for the development of optical sensors for analytes of environmental interests.

[The structure and stability of the glutamine-binding protein from Escherichia coli and its complex with glutamine].

A study was made of the conformational changes in the Escherichia coli glutamine-binding potein (GlnBP) induced by GdnHCl, and of the effect of glutamine (Gln) binding on these processes. Intrinsic fluorescence, ANS emission fluorescence, and far- and near-UV circular dichroism spectroscopy were used. The obtained experimental data were interpreted, taking into the account results of the analysis of tryptophan and tyrosine residues microenvironments. This enabled us to explain the negligible contribution of Tyr residues to the bulk fluorescence of the native protein, the similarity of fluorescence characteristics of GlnBP and GlnBP/Gln, and an uncommon effect of the excess of fluorescence intensity at 365 nm (Trp emission) upon excitation at 297 nm compared to the excitation at 280 nm. The latter effect is explained by the spectral dependence of Trp 32 and Trp 220 contributions to protein absorption. The dependence of Trp fluorescence of protein on the excitation wavelength must be taken into account for the evaluation of Tyr residues contribution to the bulk fluorescence of protein, and in principle, it may also be used for the development of an approach to decomposition of multi-component protein fluorescence spectrum. The parametric presentation of fluorescence data showed that both GlnBP unfolding and GlnBP/Gln unfolding are three-step processes (N-->I1-->I2-->U), though in the case of the GlnBP/Gln complex these stages essentially overlap. Despite its complex character, GlnBP unfolding is completely reversible. In comparison with GlnBP, in the case of GlnBP/Gln the dramatic shift of N-->I1 process to higher GdHCl concentrations is shown.

Temperature effects on the structural and functional properties of GPI-anchored and anchor-less bull seminal plasma ecto-5'-nucleotidase.

The effects of temperature on the three-dimensional organization and on the secondary structure of GPI-anchored 5'-nucleotidase from bull seminal plasma and of its anchor-less form (solubilized ecto-5'-nucleotidase), obtained after GPI anchor removal by phosphatidylinositol-specific phospholipase C were investigated in parallel by circular dichroism and fluorescence spectroscopy. The structural features of the two enzymes were correlated to their functional properties in the temperature range of 25-90 degrees C. The kinetic data indicated that the enzyme activities were temperature dependent, showing the maximal values at 60 degrees C. The relevant Arrhenius plots were linear in the temperature range of 20-60 degrees C and the activation energies were 44.4 and 51.8 kJ/mol for the solubilized and GPI-anchored 5'-nucleotidase, respectively. The time-course measurements of enzyme activity, in the temperature range of 25-55 degrees C, revealed that the two enzymes were of different thermal stability, the solubilized ectoenzyme showing lower thermal deactivation constants and longer half lives. Fluorescence and near UV circular dichroism spectroscopy showed that temperature increases induced remarkable changes in the protein tertiary structure of the two enzymes, whereas far-UV circular dichroism analysis revealed only a small temperature effect on the protein secondary structure content.