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Molecular fingerprints revealed by Raman techniques show great potential for biomedical applications, like disease diagnostic through Raman detection of tumor markers and other molecules in the cell membrane. However, SERS substrates used in membrane molecule studies produce enhanced Raman spectra of high variability and challenging band assignments that limit their application. In this work, these drawbacks are addressed to detect membrane-associated hemoglobin (Hbm) in human erythrocytes through Raman spectroscopy. These cells are incubated with silver nanoparticles (AgNPs) in PBS before Raman measurements. Our results showed that AgNPs form large aggregates in PBS that adhered to the erythrocyte membrane, which enhances Raman scattering by molecules around the membrane, like Hbm. Also, deoxyHb markers may allow Hbmdetection in Raman spectra of oxygenated erythrocytes (oxyRBCs). Raman spectra of oxyRBCs incubated with AgNPs showed enhanced deoxyHb signals with good spectral reproducibility, supporting the Hbmdetection through deoxyHb markers. Instead, Raman spectra of oxyRBCs showed oxyHb bands associated with free cytoplasmic hemoglobin. Other factors influencing Raman detection of membrane proteins are discussed, like bothz-position and dimension of the sample volume. The results encourage membrane protein studies in living cells using Raman spectroscopy, leading to the characterization and diagnostic of different pathologies through a non-invasive technique.

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It has been demonstrated that proteases play crucial roles in Plasmodium falciparum infection and therefore have been considered as targets for the development of new therapeutic drugs. The aim of this study was to describe the specific proteolytic activity profile in all blood stages of P. falciparum isolated parasites in order to explore new antimalarial options. For this purpose, we used the fluorogenic substrate Z-Phe-Arg-MCA (Z: carbobenzoxy, MCA: 7-amino-4-methyl coumarine) and classic inhibitors for the different classes of proteolytic enzymes, such as phenylmethylsulfonyl fluoride (PMSF), 1.10-phenantroline, pepstatin A and E64 to study the inhibition profiles. As expected, due to the high metabolic activity in mature stages, the substrate was mostly degraded in the trophozoite and schizont, with specific activities ~ 20 times higher than in early stages (merozoite/rings). The major actors in substrate hydrolysis were cysteine proteases, as confirmed by the complete hydrolysis inhibition with E64 addition. Proteolytic activity was also inhibited in the presence of PMSF in all but the schizont stage. However, PMSF inhibition was the result of unspecific interaction with cysteine proteases as demonstrated by reversion of inhibition by dithiotreitol (DTT), indicating that serine protease activity is very low or null. To our knowledge, this is the first report aiming to describe the proteolytic profile of P. falciparum isolated parasites at all the erythrocytic cycle stages. The results and protocol described herein can be useful in the elucidation of stage specific action of proteolysis-inhibiting drugs and aid in the development of antimalarial compounds with protease inhibitory activity(AU)

e ha demostrado que las proteasas desempeñan funciones vitales en la infección por Plasmodium falciparum, y por lo tanto se consideran dianas en la elaboración de nuevos medicamentos terapéuticos. El objetivo del estudio era describir el perfil de actividad proteolítica específica de todas las etapas sanguíneas de parásitos aislados de P. falciparum con vistas a explorar nuevas opciones antimaláricas. Con ese propósito, utilizamos el sustrato fluorogénico Z-Phe-Arg-AMC (Z: carbobenzoxi, AMC: 7-amino-4-metilcumarina) e inhibidores clásicos para las diferentes clases de enzimas proteolíticas, tales como el fluoruro de fenilmetilsulfonilo (PMSF), 1,10-fenantrolina, pepstatina A y E64 para estudiar los perfiles de inhibición. Como se esperaba, debido a la elevada actividad metabólica de las etapas de madurez, el sustrato fue degradado mayormente en el trofozoíto y el esquizonte, con actividad específica ~ 20 veces superior a la de las etapas tempranas (merozoíto/ anillos). Los principales actores en la hidrólisis del sustrato fueron las cisteínas proteasas, lo que fue confirmado por la inhibición completa de la hidrólisis con la adición de E64. La actividad proteolítica también fue inhibida en presencia de PMSF en todas las etapas excepto el esquizonte. Sin embargo, la inhibición del PMSF fue resultado de una interacción inespecífica con las cisteínas proteasas, según lo demuestra la reversión de la inhibición con el ditiotreitol (DTT), lo que indica que la actividad de la serina proteasa es muy baja o inexistente. Que sepamos, este es el primer informe dirigido a describir el perfil proteolítico de parásitos aislados de P. falciparum en todas las etapas del ciclo eritrocítico. Los resultados y el protocolo que aquí se describen pueden ser útiles para dilucidar la acción específica de los medicamentos inhibidores de proteólisis en cada etapa, así como contribuir al desarrollo de compuestos antimaláricos con actividad inhibidora de la proteasa(AU)

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Aerobic metabolism brings inexorably the production of reactive oxygen species (ROS), which are counterbalanced by intrinsic antioxidant defenses avoiding deleterious intracellular effects. Redox balance is the resultant of metabolic functioning under environmental inputs (i.e. diet, pollution) and the activity of intrinsic antioxidant machinery. Monitoring of intracellular hydrogen peroxide has been successfully achieved by redox biosensor advent; however, to track the intrinsic disulfide bond reduction capacity represents a fundamental piece to understand better how redox homeostasis is maintained in living cells. In the present work, we compared the informative value of steady-state measurements and the kinetics of HyPer, a H2O2-sensitive fluorescent biosensor, targeted at the cytosol, mitochondrion and endoplasmic reticulum. From this set of data, biosensor signal recovery from an oxidized state raised as a suitable parameter to discriminate reducing capacity of a close environment. Biosensor recovery was pH-independent, condition demonstrated by experiments on pH-clamped cells, and sensitive to pharmacological perturbations of enzymatic disulfide reduction. Also, ten human cell lines were characterized according their H2O2-pulse responses, including their capacity to reduce disulfide bonds evaluated in terms of their migratory capacity. Finally, cellular migration experiments were conducted to study whether migratory efficiency was associated with the disulfide reduction activity. The migration efficiency of each cell type correlates with the rate of signal recovery measured from the oxidized biosensor. In addition, HyPer-expressing cells treated with N-acetyl-cysteine had accelerated recovery rates and major migratory capacities, both reversible effects upon treatment removal. Our data demonstrate that the HyPer signal recovery offers a novel methodological tool to track the cellular impact of redox active biomolecules.

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Microtubules are filamentous biopolymers involved in essential biological processes. They form key structures in eukaryotic cells, and thus it is very important to determine the mechanisms involved in the formation and maintenance of the microtubule network. Microtubule bucklings are transient and localized events commonly observed in living cells and characterized by a fast bending and its posterior relaxation. Active forces provided by molecular motors have been indicated as responsible for most of these rapid deformations. However, the factors that control the shape amplitude and the time scales of the rising and release stages remain unexplored. In this work, we study microtubule buckling in living cells using Xenopus laevis melanophores as a model system. We tracked single fluorescent microtubules from high temporal resolution (0.3-2 s) confocal movies. We recovered the center coordinates of the filaments with 10-nm precision and analyzed the amplitude of the deformation as a function of time. Using numerical simulations, we explored different force mechanisms resulting in microtubule bending. The simulated events reproduce many features observed for microtubules, suggesting that a mechanistic model captures the essential processes underlying microtubule buckling. Also, we studied the interplay between actively transported vesicles and the microtubule network using a two-color technique. Our results suggest that microtubules may affect transport indirectly besides serving as tracks of motor-driven organelles. For example, they could obstruct organelles at microtubule intersections or push them during filament mechanical relaxation.

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