Carmen Sanges

Porous Silicon Based Resonant Mirrors for Biochemical Sensing

We report on our preliminary results in the realization and characterization of a porous silicon (PSi) resonant mirror (RM) for optical biosensing. We have numerically and experimentally studied the coupling between the electromagnetic field, totally reflected at the base of a high refractive index prism, and the optical modes of a PSi waveguide. This configuration is very sensitive to changes in the refractive index and/or in thickness of the sensor surface. Due to the high specific area of the PSi waveguide, very low DNA concentrations can be detected confirming that the RM could be a very sensitive and label-free optical biosensor.

Porous silicon-based optical biochips

In this paper, we present our work on an optical biosensor for the detection of the interaction between a DNA single strand and its complementary oligonucleotide, based on the porous silicon (PSi) microtechnology. The crucial point in this sensing device is how to make a stable and repeatable link between the DNA probe and the PSi surface. We have experimentally compared some functionalization processes which modify the PSi surface in order to covalently fix the DNA probe on it: a pure chemical passivation procedure, a photochemical functionalization process, and a chemical modification during the electrochemical etching of the PSi. We have quantitatively measured the efficiency of the chemical bond between the DNA and the porous silicon surface using Fourier transform infrared spectroscopy (FT-IR) and light induced photoluminescence emission. From the results and for its intrinsic simplicity, photochemical passivation seems to be the most promising method. The interaction between a label-free 50 µM DNA probe with complementary and non-complementary oligonucleotides sequences has been also successfully monitored by means of optical reflectivity measurements.

Improved procedure for protein binder analysis in mural painting by LC-ESI/Q-q-TOF mass spectrometry: detection of different milk species by casein proteotypic peptides

Diagnostic techniques applied to the field of cultural heritage represent a very important aspect of scientific investigation. Recently, proteomic approaches based on mass spectrometry coupled with traditional spectroscopic methods have been used for painting analysis, generating promising results for binder’s protein identification. In the present work, an improved procedure based on LC-ESI/Q-q-TOF tandem mass spectrometry for the identification of protein binders has been developed for the molecular characterization of samples from an early-twentieth-century mural painting from the St. Dimitar Cathedral in Vidin, Bulgaria. The proteomic investigation has led to the identification of both egg white and egg yolk proteins, according to traditional old recipes for tempera paintings. In addition, beyond the egg components, the presence of caseins was also revealed, thus suggesting the use of milk as binding medium, fixative or stabilising agent. Furthermore, for the first time, the capability to discriminate the milk origin on the basis of alpha casein proteotypic peptides is reported, that are diagnostic for a given species, thus opening interesting perspectives in art and archaeological fields.

Polar and non-polar organic binder characterization in Pompeian wall paintings: comparison to a simulated painting mimicking an "a secco" technique.

The use of Fourier transform infrared spectromicroscopy and mass spectrometry (MS) allowed us to characterize the composition of polar and non-polar binders present in sporadic wall paint fragments taken from Pompeii’s archaeological excavation. The analyses of the polar and non-polar binder components extracted from paint powder layer showed the presence of amino acids, sugars, and fatty acids but the absence of proteinaceous material. These results are consistent with a water tempera painting mixture composed of pigments, flours, gums, and oils and are in agreement with those obtained from a simulated wall paint sample made for mimicking an ancient “a secco” technique. Notably, for the first time, we report the capability to discriminate by tandem MS the presence of free amino acids in the paint layer.

Analysis of interaction partners for eukaryotic translation elongation factor 1A M-domain by functional proteomics

The eukaryotic translation elongation factor 1A (eEF1A), besides to its canonical role in protein synthesis, is also involved in several other cellular processes, depending on changes in cellular location, cell type, concentration of ligands, substrates or cofactors. Therefore eEF1A is a moonlighting protein that participates to a network of molecular interactions involving its structural domains. Since the identification of novel protein-protein interactions represents important tasks in post-genomic era, the interactome of eEF1A1 M-domain was investigated by using a proteomic approach. To this purpose, the eEF1A1 M-domain was fused with glutathione-S-transferase (GST) and Strep-tag (ST) at its N- and C-terminal, respectively. The recombinant protein (GST-M-ST) was purified and incubated with a mouse embryo lysate by applying an affinity chromatography strategy. The interacting proteins were separated by SDS-PAGE and identified by peptide mass fingerprinting using MALDI-TOF mass spectrometry. Besides the known partners, the pool of interacting proteins contained sorbin, a polypeptide of 153 amino acids present in SH3 domain-containing adaptor proteins, such as SORBS2. This interaction was also assessed by Western blot on immunoprecipitate from mouse embryo or H1355 cell lysates with anti-eEF1A or anti-SORBS2 antibodies and on eEF1A1-His pull-down from H1355 cell lysate with antibody anti-SORBS2. Furthermore, the interaction between eEF1A and SORBS2 was also confirmed by confocal microscopy and FRET analysis. Interestingly, a co-localization of SORBS2 and eEF1A was evidenced at level of plasma membrane, thus suggesting the involvement of eEF1A1 in novel key signal transduction complexes.

FT-IR spectromicroscopy of mammalian cell cultures during necrosis and apoptosis induced by drugs

FT-IR is used in the field of biology and medicine to detect bimolecular changes in disordered cells and tissues. In this report, using FT-IR microscopy, we characterize changes in apoptotic and necrotic Jurkat cells with respect to normal cells. The analysis of deconvoluted regions of the FT-IR spectra showed significant differences compared to the controls in three spectral regions. In particular, the apoptotic cells were characterized by an increase in the absorption at 2925 cm −1 , due to the asymmetric CH2-stretching (νasCH2) of membrane lipids whereas the spectral areas ratio (A1654/A1629) of the amide I region indicated an increase in apoptotic cells of more α-helical structures with respect to of β-sheet content. Interestingly, apoptotic cells showed the appearance of a peak around 1743 cm −1 , ν(C=O) assigned to acid ester. Because no other similar increase for lipid bands was observed, the increase of A1745 is not simply due to an increase in the number of lipid molecules or their density but could also be indicative as marker of apoptosis. These spectral changes were not observed in necrotic Jurkat cells.

Ser/Thr kinases and polyamines in the regulation of non-canonical functions of elongation factor 1A

The link between eukaryotic translation elongation factor 1A (eEF1A) and signal transduction pathways through the regulatory mechanism of phosphorylation has never been considered. In this review, we focus on the different kinases that recognize the Ser and Thr residues of the eEF1A1 and eEF1A2 isoforms and regulate their involvement in different cellular processes like cell survival and apoptosis. In this context, polyamines seem to play a role in the regulation of the translation elongation process by modulating the Ser/Thr kinases involved in the phosphorylation of translation elongation factors.

Silicon-Based Technology for Ligand-Receptor Molecular Identification

One of the most important goals in the fields of biology and medicine is the possibility to dispose of efficient tools for the characterization of the extraordinary complexity of ligand-receptor interactions. To approach this theme, we explored the use of crystalline silicon (cSi) technology for the realization of a biotechnological device in which the ligand-receptor interactions are revealed by means of optical measurements. Here, we describe a chemical procedure for the functionalization of microwell etched on silicon wafers, and the subsequent anchoring of biological molecules like an antibody anti-A20 murine lymphoma cell line. The optical analysis of the interaction on the biochips between the bound biomolecule and their corresponding ligand indicated that the functionalized cSi is suitable for this application.

Analysis of Nickel-Binding Peptides in a Human Hepidermoid Cancer Cell Line by Ni-NTA Affinity Chromatography and Mass Spectrometry

To elucidate whether eukaryotic elongation factor 1A (eEF-1A) in a human hepidermoid cancer cell line (H1355) belonged to the family of the Ni-interacting protein, we analyzed the sequence of peptides obtained by on-Ni-NTA-agarose tryptic digestion of proteins from H1355 cell extract. LC/MS analysis showed the presence of several peptides mainly from abundant cellular proteins corresponding to eEF-1A, tubulin and actin. The results indicated that F-actin strongly binds to Ni-NTA-agarose whereas the other proteins are indirectly bound to the resin because of the formation of a protein-protein complex with actin.

Raf kinases in signal transduction and interaction with translation machinery

Abstract In recent years, a large amount of evidence has given a central role to translational control in diseases such as cancer, tissue hypertrophy and neurodegeneration. Its deregulation can directly modulate cell cycling, transformation and survival response. The aim of this review is to describe the interaction between Raf activation and the main characters of the translational machinery, such as the elongation factor 1A (eEF1A), which has been recognized in recent years as one of the most interesting putative oncogenes. A particular emphasis is given to an intriguing non-canonical role that eEF1A can play in the relationship between the Ras→Raf-1→MEK1→ERK-1/2 and PI3K→Akt signaling pathways. Recently, our group has described a C-Raf kinase-mediated phosphorylation of eEF1A triggered by a survival pathway induced upon interferon alpha (IFNα) treatment in the human epidermoid cancer cell line (H1355). This phosphorylation seems to be the center of the survival pathway that counteracts the well-known pro-apoptotic function of IFNα. Furthermore, we have identified two new phosphorylation sites on eEF1A (Ser21 and Thr88) that are substrates for Raf kinases in vitro and, likely, in vivo as well. These residues seem to have a significant functional role in the control of cellular processes, such as cell proliferation and survival. In fact, overexpression of eEF1A2 in gemcitabine-treated cancer cells caused the upregulation of phosphoAkt and an increase in cell viability, thereby suggesting that eEF1A2 could exert its oncogenic behavior by participating in the regulation of PI3K pathway.