Photoinduced millisecond switching kinetics in the GFPMut2 E222Q mutant.

New probes for kinetic intracellular measurements in the millisecond range are desirable to monitor protein biochemical dynamics essential for catalysis, allosteric regulation, and signaling. Good candidates to this aim are the photoswitchable mutants of the green fluorescent protein, whose anionic fluorescence, primed by blue light, is markedly enhanced under an additional excitation at a shorter wavelength and relaxes within a few milliseconds. The aim of this report is to study how the brightness enhancement kinetics depends on the physical-chemical and spectroscopic parameters and to provide proof-of-concept experiments for the use of the fluorescence enhancement in conditions in which the protein diffusion is hindered and thereby photobleaching can be a limiting critical issue. Future, direct applications of photochromic mutants for modulated excitation imaging would in fact require such a detailed knowledge. We present here an extensive study of the photoswitching mechanism of the E222Q mutant of GFPMut2 (Mut2Q), pumped by visible 488 nm light and probed at 400-420 nm, as a function of pH, viscosity, temperature, and light intensity. In solution, two characteristic photoswitching times are found by means of modulated double beam fluorescence correlation spectroscopy in the 1-30 ms range, depending on the solution pH. The photoswitching kinetics is solved in terms of the eigenvalues and the eigenvectors of a specific energy diagram and used directly to fit the data, suggesting that the observed photoswitching amplitudes and kinetics are related to a single three-level transition loop. Finally, we give in vitro examples of the use of modulated excitation microscopy, based on fluorescence enhancement amplitude and kinetics detection, on Mut2Q protein samples immobilized in acrylamide gels.

Environment effects on the oscillatory unfolding kinetics of GFP.

The chromophore of a green fluorescent protein (GFP) mutant engineered to enhance emission and stability is known to display erratic switchings among a few of its chemical substates and, in particular, between the anionic A and the neutral N substates, whose difference is associated with a proton exchange and a consequent conformation rearrangement. However, when close to unfolding, the A-N switchings suddenly become very regular as shown by fluorescence oscillations that have been recently observed for molecules embedded in wet silica gel. In order to establish whether the matrix hosting the protein is responsible for these oscillations, we investigated the effect of another medium (silanized surfaces), of a different denaturant (urea) and of cosolvents (D(2)O and glycerol). The occurrence of periodic A-N switchings, in the last milliseconds before GFP unfolding, is observed under all investigated conditions, together with three specific frequency values that characterize the pre-unfolding fluorescence. Urea and guanidinium, the denaturants employed in order to unfold GFP, do not lead to appreciable differences in the observed switching parameters, whereas the different media embedding the protein give rise only to frequency shifts that scale with the viscosity of the host. The periodicity of the GFP A-N switchings and their dependence on cosolvents suggest that they could be associated with oscillatory motions between meta-stable conformations of the beta-barrel surrounding the chromophore near protein unfolding.

Evidence of discrete substates and unfolding pathways in green fluorescent protein.

We present evidence of conformational substates of a green fluorescent protein mutant, GFPmut2, and of their relationship with the protein behavior during chemical unfolding. The fluorescence of single molecules, excited by two infrared photons from a pulsed laser, was detected in two separate channels that simultaneously collected the blue or the green emission from the protein chromophore chemical states (anionic or neutral, respectively). Time recording of the fluorescence signals from molecules in the native state shows that the chromophore, an intrinsic probe sensitive to conformational changes, switches between the two states with average rates that are found to assume distinct values, thereby suggesting a multiplicity of protein substates. Furthermore, under denaturing conditions, the chromophore switching rate displays different and reproducible time evolutions that are characterized by discrete unfolding times. The correlation that is found between native molecules' switching rate values and unfolding times appears as direct evidence that GFPmut2 can unfold only along distinct paths that are determined by the initial folded substate of the protein.

Pre-unfolding resonant oscillations of single green fluorescent protein molecules.

Fluorescence spectroscopy of a green fluorescent protein mutant at single-molecule resolution has revealed a remarkable oscillatory behavior that can also be driven by applied fields. We show that immediately before unfolding, several periodic oscillations among the chemical substates of the protein chromophore occur. We also show that applied alternating electric or acoustic fields, when tuned to the protein characteristic frequencies, give rise to strong resonance effects.

Dimethyl-pepep: a DNA probe in two-photon excitation cellular imaging.

Dimethyl-pepep (D-pepep), a newly developed and very efficient two-photon absorber, has been tested here for two-photon excitation (TPE) cellular imaging. The spectral characteristics of the dye following one-photon excitation (OPE) and TPE (excitation and emission spectra, fluorescence lifetime, molecular brightness, saturation intensity) are reported. In vitro interaction studies with biomolecules show that dimethyl-pepep has a large affinity for DNA. A comparison with a widely used DNA stainer, 4-6-diamidino-2-phenylindole (DAPI) bound to DNA shows that the D-pepep brightness is one order of magnitude higher than that of DAPI, making this dye suitable for microscopy and imaging applications. TPE images taken from double-stained yeast Saccharomyces cerevisiae cells have revealed that D-pepep localizes mainly in the nucleus, similarly to DAPI, and in mitochondria, although to a minor extent. Preliminary tests have shown that the dye cellular toxicity is negligible.

Porcine beta-lactoglobulin chemical unfolding: identification of a non-native alpha-helical intermediate.

The chemical unfolding behavior of porcine beta-lactoglobulin (PLG) has been followed at pH 2 and 6 in the presence of guanidinium hydrochloride. The PLG unfolding transition, monitored by tryptophan fluorescence, far and near UV circular dichroism and 1D-NMR, can be described by a three-state transition suggesting the presence of at least one intermediate state that appears to display an excess of non-native alpha-helical structures. The thermodynamic parameters, as determined through a global analysis fitting procedure, give estimates of the free energy differences of the transitions connecting the native, the intermediate and the unfolded state: DeltaG(NI) (0) = 2.8 +/- 0.7 kcal mol(-1) (pH 2) and 4.2 +/- 0.5 kcal mol(-1) (pH 6) and DeltaG(NU) (0) = 7.2 +/- 0.6 kcal mol(-1) (pH 2) and 6.9 +/- 0.6 kcal mol(-1) (pH 6). CD unfolding data of the bovine species (BLG) have been collected here under the same experimental conditions of PLG to allow a careful comparison of the two beta-lactoglobulins. Intermediates with different characteristics have been identified for BLG and PLG, and their nature has been discussed on a structural analysis basis. The thermodynamic data reported here for PLG and BLG and the comparative analysis with data reported for equine beta lactoglobulin, show that homologous beta-barrel proteins, belonging to the same family and displaying high sequence identity (52-64%) populate unfolding intermediates to different extents, even though a common tendency to the formation of non-native alpha-helical intermediates, can be envisaged. The present results provide a prerequisite foundation of knowledge for the design and interpretation of future folding kinetic studies.

Fluorescence anisotropy in the frequency domain by an optical microscope.

Fluorescence anisotropy decay spectroscopy is a suitable tool for investigating the size and the shape of biological molecules. We coupled this technique to an optical microscope in order to reduce the excitation volume and to allow its application to spatially inhomogeneous samples. Phase modulated measurements of the fluorescence anisotropy decay were performed by feeding an intensity modulated linearly polarized laser beam to the epifluorescence port of a microscope. Here we report the test of the dynamic response of the microscope by comparing the lifetime and fluorescence polarization anisotropy decays obtained in cuvettes in a standard phase modulation fluorometer and on tiny drops on the microscope stage. We show that once a correction factor for the objective depolarization is introduced in the best-fit functions for the data analysis of the decays, the results obtained on the two setups are comparable. Some applications are reported here on long DNA tracts as well on short DNA fragments containing structural anomalies.

Competitive binding of fatty acids and the fluorescent probe 1-8-anilinonaphthalene sulfonate to bovine beta-lactoglobulin.

The use of spectroscopy in the study of fatty acids binding to bovine beta-lactoglobulin (BLG) appears to be a difficult task, as these acid compounds, assumed as the protein natural ligands, do not exhibit favorable optical response such as, for example, absorption or fluorescence. Therefore, the BLG fatty-acid equilibrium has been tackled by exploiting the competition between fatty acids and ANS, a widely used fluorescent hydrophobic probe, whose binding sites on the protein have been characterized recently. Two lifetime decays of the ANS-BLG complex have been found; the longer one has been attributed to the internal binding site and the shorter one to the external site. At increasing fatty acids concentration, the fractional weight associated with ANS bound to the internal site drops, in agreement with a model describing the competition of the dye with fatty acids, whereas the external site occupancy appears to be unaffected by the fatty acids binding to BLG. This model is supported by docking studies. An estimate of the acid-binding affinities for BLG has been obtained by implementing the fitting of the bound ANS intensities with a competitive binding model. A relevant dependence has been found upon the solution pH, in the range from 6 to 8, which correlates with the calyx accessibility modulated by the conformation of the EF loop. Fatty acids with longer aliphatic chains (palmitate and laurate) are found to display larger affinities for the protein and the interaction free energy nicely correlates with the number of contacts inside the protein calyx, in agreement with docking simulations.

Trehalose influence on beta-lactoglobulin stability and hydration by time resolved fluorescence.

The stabilizing role of the disaccharide trehalose on beta-lactoglobulin (BLG) against its chemical denaturation both at native and acidic pH has been explored by means of time-resolved fluorescence of the probe acrylodan covalently bound to the unique free cysteine of BLG. The changes in acrylodan fluorescence lifetime with guanidinium chloride concentration reveal BLG sigmoidal denaturation profiles which depend upon the amount of trehalose in solution. When adding trehalose the transition midpoint shifts towards higher denaturant concentration. This effect has been measured by fitting the data with a two-state model whose parameters indicate that an almost 60% increase in the denaturation free energy is induced independently of trehalose concentrations and pH values. Fluorescence anisotropy measurements performed in the same conditions reveal that the internal dynamics are largely affected by the sugar, which makes the acrylodan environment more rigid, and by the denaturant that acts in the opposite way. The overall rotational diffusion of BLG suggests that trehalose affects the hydrodynamic properties of the solution in the proximity of the protein; tentative mechanisms are discussed.

Trehalose-induced changes of the ethidium hydration shell detected by time-resolved fluorescence.

The fluorescence lifetime of ethidium bromide (EB), a widely used fluorescent dye, has been monitored in water solution versus trehalose concentration in order to learn how the presence of the disaccharide modifies the hydration of EB, which is used in this study as a model probe. The interest in trehalose, a naturally occurring bioprotector (osmolyte), stems from its ability to stabilize biomolecules under stress situations. The observed effects of trehalose on EB fluorescence properties have been compared with those induced by sucrose and glucose. Lifetime measurements have been performed by frequency domain fluorometry (2-40 MHz), and from the analysis of their changes versus sugar concentration, the EB-sugar interaction parameters have been obtained. The effect of trehalose on the EB decay in glasses has also been studied both by exploring the heterogeneity of lifetime decay and by single-molecule imaging. Trehalose appears to be more efficient in changing the EB fluorescence parameters, such as the emission lifetime, and it leads to a degree of heterogeneity higher than that induced by the other sugars. When EB is embedded in trehalose glasses, the heterogeneity of the emission and of the bleaching time is further enhanced.

Two-photon thermal bleaching of single fluorescent molecules.

We have studied the fluorescence emission by two-photon excitation of four dyes widely used for bioimaging studies, rhodamine 6G, fluorescein, pyrene and indo-1 at the single molecule level. The single dye molecules, spread on a glass substrate by spin coating, show a constant fluorescence output until a sudden transition to a dark state very close to the background. The bleaching time that is found to vary in the series pyrene, indo-1, fluorescein and rhodamine 6G from the fastest to the slowest one respectively, has a Gaussian distribution indicating that the observed behavior is not due to photobleaching. Moreover, the bleaching time decreases with the glass substrate temperature reaching a vanishing nonmeasurable value for a limiting temperature whose value is found in the same series as for the bleaching time, from the lowest to the highest temperature respectively. The observed bleaching shows a clear correlation to the amount of absorbed power not reirradiated as fluorescence and to the complexity of the molecule. These observations are interpreted as thermal bleaching where the temperature increase is induced by the two-photon absorption of the single dyes as confirmed also by numerical simulations.

Probing protein aggregation by time-resolved fluorescence during beta-lactoglobulin crystal growth.

We have used the fluorescence anisotropy (FA) decay of retinol bound to bovine beta-lactoglobulin to monitor the time evolution of protein aggregation during the early stages of crystal growth. With this approach we have followed the formation of aggregates at different concentrations of ammonium sulfate, the precipitant used for crystallization. The average aggregation number is found to depend on precipitant concentration, and to be restricted to small numbers ranging from 2 to 5, also in the presence of visible growing crystals. The effect of particle distribution and of low probe-to-protein saturation on the FA response is also discussed in detail.

Does beta-lactoglobulin denaturation occur via an intermediate state?

The denaturation of beta-lactoglobulin (BLG) in the presence of urea and GuHCl has been investigated at different pH values with various spectroscopic techniques. The equilibrium denaturation free energy values, obtained by linearly extrapolating the data to vanishing denaturant (DeltaG(D)(H2O)), are compared and discussed. The fit of the spectroscopic data monitoring the denaturation of BLG has been approached, at first, with a two-state model that describes the protein transition from the folded state (at each pH and in the absence of denaturant) to the denatured state, but in particular, along the GuHCl denaturation pathway some evidence is found of the presence of an intermediate state. Time-resolved fluorescence experiments performed on the BLG-ANS (1-anilino-8-naphthalenesulfonate) complex help to understand the results. Fluorescence polarization anisotropy (FPA) measurements accompanying the denaturation process show the presence of a fast rotational diffusion of the ANS probe, and the data are interpreted in terms of local fluctuations of a still structured tract of the denatured protein where the probe is bound.

Studies on the mode of Ku interaction with DNA.

The Ku heterodimer plays a central role in non-homologous end-joining. The binding of recombinant Ku to DNA has been investigated by dynamic light scattering, double-filter binding, fluorescence spectroscopy, and band shift assays. The hydrodynamic radius of Ku in solution is 5.2 nm and does not change when a 25-bp double-strand DNA (dsDNA) fragment (D25) is added, indicating that only one Ku molecule binds to a 25-bp fragment. The dissociation constant (k(d)) for the binding to D25 is 3.8 +/- 0.9 nm. If both ends of the substrate are closed with hairpin loops, Ku is still able to bind with little change in the k(d). The k(d) is not affected by ATP, Mg(2+), or ionic strength. However, the addition of bovine serum albumin decreases the k(d) by 2-fold. DNA substrates of 50 bp can bind two Ku molecules, whereas three molecules are bound to a 75-bp substrate. Data analysis with the Hill equation yields a value of the Hill coefficient (n) close to 1, and the k(d) values for the binding of Ku to both ends of these substrates are the same. Thus, we demonstrate that there is no cooperative interaction among the Ku heterodimers binding longer substrates.

Hernia diafragmática de derecha traumática y resección intestinal intratorácica / Diaphragmatic hernia right trauma and resection intestinal intrathoracic

Informar una patología poco común. Descripción de la presentación clínica y del procedimiento utilizando para la resolución del mismo. Unidad de Neumonología y Cirugía de Tórax. Instituto Autónomo Hospital Universitario de Los Andes Mérida. Una hernia diafragmática derecha ocurrió en un paciente 30 años después de haber recibido una herida punzo penetrante en abdomen. La herniación de vísceras abdominales a través del hemidiafragma derecho es muy rara ya que el hígado actúa como barrera y ello puede presentarse aún después de varios años de un trauma abdominal

Síndrome posneumonectomía derecha: presentación de un caso / Right postpneumonectomy syndrome: presentation of the case

Una rara y bien documentada complicación de la neumonectomía derecha, es el síndrome posneumonectomía (1), el cual se caracteriza por presentar síntomas y complicaciones tales como disnea progresiva, estridor e infecciones pulmonares recurrentes. Otras de sus características son el desplazanminto de las estructuras del mediastino hacia el hemitórax evacuado y la rotación de tales estructuras. El tercio distal de la tráquea y el bronquio principal izquierdo, sufren torsión comprensión debido a la rotación que ejerce la arteria pulmonar izquierda por delante y la aorta y las vértebras torácicas por detrás y ocasionan un aplastamiento del bronquio principal izquierdo en sentido anteroposterior y en consecuencia, cambios importantes en el funcionamiento respiratorio