368 research outputs found
Monitoring drug stability by label-free fluorescence lifetime imaging: a case study on liposomal doxorubicin
In a previous report, we demonstrated that Doxorubicin (DOX) intrinsic
fluorescence can be exploited in combination with the phasor approach to fluorescence lifetime
imaging microscopy (FLIM) and quantitative absorption/fluorescence spectroscopy to resolve
the supramolecular organization of the drug within its FDA-approved nanoformulation,
Doxil®. The resulting ‘synthetic identity’ comprises three co-existing physical states of the
drug within Doxil®: a dominating fraction of crystallized DOX (DOXc >98%), and two minor
fractions of free DOX (DOXf ~1%), and DOX associated with the liposomal membrane (DOXb
<1%). This result serves as a benchmark here to address the time evolution of Doxil® synthetic
identity. We probe the effect of temperature for a total duration of 6 months in a non-invasive
way by FLIM. We confirm Doxil® stability if stored at 4°C, while we detect marked changes
in its synthetic identity at 37°C: crystallized DOX gets progressively disassembled in time, in
favor of the other two physical states, free and membrane-associated DOX. Our phasor-FLIM-
based approach paves the way to time-resolved biochemical assays on the supramolecular
organization of encapsulated fluorescent drugs potentially all the way from the production
phase to their state within living matt
Phasor identifier : a cloud-based analysis of Phasor-FLIM data on Python notebooks
This paper introduces an innovative approach utilizing Google Colaboratory (Colab) for the versatile analysis of phasor Fluorescence Lifetime Imaging Microscopy (FLIM) data collected from various samples (e.g., cuvette, cells, tissues) and in various input file formats. In fact, phasor-FLIM widespread adoption has been hampered by complex instrumentation and data analysis requirements. We mean to make advanced FLIM analysis more accessible to researchers through a cloud-based solution that i) harnesses robust computational resources, ii) eliminates hardware limitations, iii) supports both CPU and GPU processing, We envision a paradigm shift in FLIM data accessibility and potential, aligning with the evolving field of AI-driven FLIM analysis. This approach simplifies FLIM data handling and opens doors for diverse applications, from studying cellular metabolism to investigating drug encapsulation, benefiting researchers across multiple domains. The comparative analysis of freely distributed FLIM tools highlights the unique advantages of this approach in terms of adaptability, scalability, and open-source nature
Use of the KlADH3 promoter for the quantitative production of the murine PDE5A isoforms in the yeast Kluyveromyces lactis
Background: Phosphodiesterases (PDE) are a superfamily of enzymes that hydrolyse cyclic nucleotides (cAMP/
cGMP), signal molecules in transduction pathways regulating crucial aspects of cell life. PDEs regulate the intensity
and duration of the cyclic nucleotides signal modulating the downstream biological efect. Due to this critical role
associated with the extensive distribution and multiplicity of isozymes, the 11 mammalian families (PDE1 to PDE11)
constitute key therapeutic targets. PDE5, one of these cGMP-specifc hydrolysing families, is the molecular target of
several well known drugs used to treat erectile dysfunction and pulmonary hypertension. Kluyveromyces lactis, one of
the few yeasts capable of utilizing lactose, is an attractive host alternative to Saccharomyces cerevisiae for heterologous
protein production. Here we established K. lactis as a powerful host for the quantitative production of the murine
PDE5 isoforms.
Results: Using the promoter of the highly expressed KlADH3 gene, multicopy plasmids were engineered to produce
the native and recombinant Mus musculus PDE5 in K. lactis. Yeast cells produced large amounts of the purifed A1, A2
and A3 isoforms displaying Km, Vmax and Sildenafl inhibition values similar to those of the native murine enzymes.
PDE5 whose yield was nearly 1 mg/g wet weight biomass for all three isozymes (30 mg/L culture), is well tolerated by
K. lactis cells without major growth defciencies and interferences with the endogenous cAMP/cGMP signal transduction
pathways.
Conclusions: To our knowledge, this is the frst time that the entire PDE5 isozymes family containing both regulatory
and catalytic domains has been produced at high levels in a heterologous eukaryotic organism. K. lactis has been
shown to be a very promising host platform for large scale production of mammalian PDEs for biochemical and structural
studies and for the development of new specifc PDE inhibitors for therapeutic applications in many pathologies
In Vivo Imaging of Single-Molecule Translocation Through Nuclear Pore Complexes by Pair Correlation Functions
BACKGROUND: Nuclear pore complexes (NPCs) mediate bidirectional transport of proteins, RNAs, and ribonucleoproteins across the double-membrane nuclear envelope. Although there are many studies that look at the traffic in the nucleus and through the nuclear envelope we propose a method to detect the nucleocytoplasmic transport kinetics in an unperturbed cell, with no requirement for specific labeling of isolated molecules and, most important, in the presence of the cell milieu. METHODOLOGY: The pair correlation function method (pCF) measures the time a molecule takes to migrate from one location to another within the cell in the presence of many molecules of the same kind. The spatial and temporal correlation among two arbitrary points in the cell provides a local map of molecular transport, and also highlights the presence of barriers to diffusion with millisecond time resolution and spatial resolution limited by diffraction. We use the pair correlation method to monitor a model protein substrate undergoing transport through NPCs in living cells, a biological problem in which single particle tracking (SPT) has given results that cannot be confirmed by traditional single-point FCS measurements because of the lack of spatial resolution. CONCLUSIONS: We show that obstacles to molecular flow can be detected and that the pCF algorithm can recognize the heterogeneity of protein intra-compartment diffusion as well as the presence of barriers to transport across NE
The influence of protein corona on Graphene Oxide: implications for biomedical theranostics
: Graphene-based nanomaterials have attracted significant attention in the field of nanomedicine due to their unique atomic arrangement which allows for manifold applications. However, their inherent high hydrophobicity poses challenges in biological systems, thereby limiting their usage in biomedical areas. To address this limitation, one approach involves introducing oxygen functional groups on graphene surfaces, resulting in the formation of graphene oxide (GO). This modification enables improved dispersion, enhanced stability, reduced toxicity, and tunable surface properties. In this review, we aim to explore the interactions between GO and the biological fluids in the context of theranostics, shedding light on the formation of the "protein corona" (PC) i.e., the protein-enriched layer that formed around nanosystems when exposed to blood. The presence of the PC alters the surface properties and biological identity of GO, thus influencing its behavior and performance in various applications. By investigating this phenomenon, we gain insights into the bio-nano interactions that occur and their biological implications for different intents such as nucleic acid and drug delivery, active cell targeting, and modulation of cell signalling pathways. Additionally, we discuss diagnostic applications utilizing biocoronated GO and personalized PC analysis, with a particular focus on the detection of cancer biomarkers. By exploring these cutting-edge advancements, this comprehensive review provides valuable insights into the rapidly evolving field of GO-based nanomedicine for theranostic applications
Nanowire-Intensified MEF in Hybrid Polymer-Plasmonic Electrospun Filaments
Hybrid polymer-plasmonic nanostructures might combine high enhancement of
localized fields from metal nanoparticles with light confinement and long-range
transport in subwavelength dielectric structures. Here we report on the complex
behavior of fluorophores coupling to Au nanoparticles within polymer nanowires,
which features localized metal-enhanced fluorescence (MEF) with unique
characteristics compared to conventional structures. The intensification effect
when the particle is placed in the organic filaments is remarkably higher with
respect to thin films of comparable thickness, thus highlighting a specific,
nanowire-related enhancement of MEF effects. A dependence on the confinement
volume in the dielectric nanowire is also evidenced, with MEF significantly
increasing upon reducing the wire diameter. These findings are rationalized by
finite element simulations, predicting a position-dependent enhancement of the
quantum yield of fluorophores embedded in the fibers. Calculation of the
ensemble-averaged fluorescence enhancement unveils the possibility of strongly
enhancing the overall emission intensity for structures with size twice the
diameter of the embedded metal particles. These new, hybrid fluorescent systems
with localized enhanced emission, as well as the general Nanowire-Intensified
MEF effect associated to them, are highly relevant for developing nanoscale
light-emitting devices with high efficiency and inter-coupled through nanofiber
networks, highly sensitive optical sensors, and novel laser architectures.Comment: 29 pages, 12 figures, Small (2018
Spatiotemporal Fluctuation Analysis: A Powerful Tool for the Future Nanoscopy of Molecular Processes
AbstractThe enormous wealth of information available today from optical microscopy measurements on living samples is often underexploited. We argue that spatiotemporal analysis of fluorescence fluctuations using multiple detection channels can enhance the performance of current nanoscopy methods and provide further insight into dynamic molecular processes of high biological relevance
Effects of vegetal- versus animal-derived protein hydrolysate on sweet basil morpho-physiological and metabolic traits
Despite scientific evidence supporting the biostimulant activity of protein hydrolysates (PHs) derived from vegetal or animal sources, the morpho-physiological and biochemical mechanisms underlying the biostimulant action of PHs from plant biomass or animal by-products are still poorly explored. Accordingly, we performed a greenhouse experiment for assessing the morphological, physiological and biochemical responses of sweet basil (Ocimum basilicum L.) to three nitrogen equivalent rates (0.05, 0.15, and 0.25 g N/kg) of an animal-derived protein hydrolysate (A-PH) and a vegetal-derived protein hydrolysate (V-PH). The V-PH and A-PH applications determined a quadratic-dose response regarding the number and area of leaves and the shoot fresh and dry weight, with the best results obtained using V-PH at the N equivalent rates of 0.05 and 0.15 g N/kg. Improvement of shoot fresh weight with V-PH foliar application at the rate of 0.15 g N/kg was associated with a higher leaf CO2 assimilation and water use efficiency, with a concomitant higher uptake and translocation of K, Mg, and S in leaf tissue. The excessive accumulation of Na, Cl, and some amino acids (e.g., proline) under A-PH applications above 0.05 g N/kg induced a rapid decrease in plant photosynthetic performance, growth, and biomass production. The plants treated with A-PH at a higher dosage appeared to activate an alternative pathway involving the synthesis of alanine and GABA for storing excess ammonia, buffering cytoplasmic acidosis, and counteracting the negative effects of Na and Cl at toxic levels. The above findings demonstrated the potential benefits of protein hydrolysate application in agriculture, especially of vegetal-derived PHs, and highlighted the need to understand dose-dependent effects in order to optimize crop response
Probing the role of nuclear-envelope invaginations in the nuclear-entry route of lipofected DNA by multi-channel 3D confocal microscopy.
Nuclear breakdown was found to be the dominant route for DNA entry into the nucleus in actively dividing cells. The possibility that alternative routes contribute to DNA entry into the nucleus, however, cannot be ruled out. Here we address the process of lipofection by monitoring the localization of fluorescently-labelled DNA plasmids at the single-cell level by confocal imaging in living interphase cells. As test formulation we choose the cationic 3β-[N-(N,N-dimethylaminoethane)-carbamoyl] cholesterol (DC-Chol) and the zwitterionic helper lipid dioleoylphosphatidylethanolamine (DOPE) with plasmidic DNA pre-condensed by means of protamine. By exploiting the spectral shift of the fluorescent dye FM4-64 (N-(3-triethylammoniumpropyl)-4-(p-diethylaminophenylhexatrienyl)-pyridinium 2Br) we monitor the position of the nuclear envelope (NE), while concomitantly imaging the whole nucleus (by Hoechst) and the DNA (by Cy3 fluorophore) in a multi-channel 3D confocal imaging experiment. Reported results show that DNA clusters are typically associated with the NE membrane in the form of tubular invaginations spanning the nuclear environment, but not completely trapped within the NE invaginations, i.e. the DNA may use these NE regions as entry-points towards the nucleus. These observations pave the way to investigating the molecular details of the postulated processes for a better exploitation of gene-delivery vectors, particularly for applications in non-dividing cells
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