A novel live-cell imaging assay reveals regulation of endosome maturation

Cell-cell communication is an essential process in life, with endosomes acting as key organelles for regulating uptake and secretion of signaling molecules. Endocytosed material is accepted by the sorting endosome where it either is sorted for recycling or remains in the endosome as it matures to be degraded in the lysosome. Investigation of the endosome maturation process has been hampered by the small size and rapid movement of endosomes in most cellular systems. Here, we report an easy versatile live-cell imaging assay to monitor endosome maturation kinetics, which can be applied to a variety of mammalian cell types. Acute ionophore treatment led to enlarged early endosomal compartments that matured into late endosomes and fused with lysosomes to form endolysosomes. Rab5-to-Rab7 conversion and PI(3)P formation and turn over were recapitulated with this assay and could be observed with a standard widefield microscope. We used this approach to show that Snx1 and Rab11-positive recycling endosome recruitment occurred throughout endosome maturation and was uncoupled from Rab conversion. In contrast, efficient endosomal acidification was dependent on Rab conversion. The assay provides a powerful tool to further unravel various aspects of endosome maturation

Monitoring intracellular labile iron pools: A novel fluorescent iron(III) sensor as a potential non-invasive diagnosis tool.

The physiological and pathophysiological importance of intracellular redox active "labile" iron has created a significant need for improved noninvasive diagnostic tools to reliably monitor iron metabolism in living cells. In this context, fluorescent iron-sensitive chemosensors in combination with digital fluorescence spectroscopic methods have proven to be highly sensitive and indispensable tools to determine cellular iron homeostasis. Recently, application of fluorescent iron sensors has led to the identification of a complex sub-cellular iron compartmentation. Cell organelle-specific iron sensors will significantly contribute to enhance fundamental knowledge of cellular iron trafficking, representing a crucial prerequisite for the future development of therapeutic strategies in iron dysregulatory diseases. Here we present physicochemical characterization and functional investigation of a new 3-hydroxypyridin-4-one based fluorescent iron(III) sensor, exclusively monitoring labile iron pools in the endosomal/lysosomal compartments. In vitro studies of the fluorescein labeled probe were carried out in murine bone marrow derived macrophages. Endosomal/lysosomal accumulation of the probe was revealed by confocal microscopy. Flow cytometry analyses demonstrated high sensitivity of the probe towards exogenous alterations of intracellular iron concentrations as well as in response to the chelation potency of iron chelators, clinically approved for treatment of iron-overload related diseases

Leishmania and the macrophage: a multifaceted interaction.

International audienceABSTRACT Leishmania, the causative agent of leishmaniases, is an intracellular parasite of macrophages, transmitted to humans via the bite of its sand fly vector. This protozoan organism has evolved strategies for efficient uptake into macrophages and is able to regulate phagosome maturation in order to make the phagosome more hospitable for parasite growth and to avoid destruction. As a result, macrophage defenses such as oxidative damage, antigen presentation, immune activation and apoptosis are compromised whereas nutrient availability is improved. Many Leishmania survival factors are involved in shaping the phagosome and reprogramming the macrophage to promote infection. This review details the complexity of the host-parasite interactions and summarizes our latest understanding of key events that make Leishmania such a successful intracellular parasite

A novel live cell imaging assay reveals regulation of endosome maturation

Cell-cell communication is an essential process in life, with endosomes acting as key organelles for regulating uptake and secretion of signaling molecules. Endocytosed material is accepted by the sorting endosome where it either is sorted for recycling or remains in the endosome as it matures to be degraded in the lysosome. Investigation of the endosome maturation process has been hampered by the small size and rapid movement of endosomes in most cellular systems. Here, we report an easy versatile live-cell imaging assay to monitor endosome maturation kinetics, which can be applied to a variety of mammalian cell types. Acute ionophore treatment led to enlarged early endosomal compartments that matured into late endosomes and fused with lysosomes to form endolysosomes. Rab5-to-Rab7 conversion and PI(3)P formation and turn over were recapitulated with this assay and could be observed with a standard widefield microscope. We used this approach to show that Snx1- and Rab11-dependent endosomal recycling occurred throughout endosome maturation and was uncoupled from Rab conversion. In contrast, efficient endosomal acidification was dependent on Rab conversion. The assay provides a powerful tool to further unravel various aspects of endosome maturation

Targeting the lysosome: fluorescent iron(III) chelators to selectively monitor endosomal/lysosomal labile iron pools.

Iron-sensitive fluorescent chemosensors in combination with digital fluorescence spectroscopy have led to the identification of a distinct subcellular compartmentation of intracellular redox-active "labile" iron. To investigate the distribution of labile iron, our research has been focused on the development of fluorescent iron sensors targeting the endosomal/lysosomal system. Following the recent introduction of a series of 3-hydroxypyridin-4-one (HPO) based fluorescent probes we present here two novel HPO sensors capable of accumulating and monitoring iron exclusively in endosomal/lysosomal compartments. Flow cytometric and confocal microscopy studies in murine macrophages revealed endosomal/lysosomal sequestration of the probes and high responsiveness toward alterations of vesicular labile iron concentrations. This allowed assessment of cellular iron status with high sensitivity in response to the clinically applied medications desferrioxamine, deferiprone, and deferasirox. The probes represent a powerful class of sensors for quantitative iron detection and clinical real-time monitoring of subcellular labile iron levels in health and disease

A novel method for non-transferrin-bound iron quantification by chelatable fluorescent beads based on flow cytometry.

The reliable measurement of non-transferrin-bound iron (NTBI) in serum has proved to be difficult and generally time consuming. We have sought a simple and fast method for such a determination. We adopted a fluorescence assay and designed a fluorescent dye with a chelating agent attached to sense iron. To avoid autofluorescence from serum samples, the iron probes were linked to beads and the autofluorescence could be separated and excluded from the measurement by flow cytometry due to the size difference between beads and serum proteins. Fluorescent beads containing both fluorescent and chelating moieties have been synthesized. The nature of the chelating function has been systematically investigated using four different chelators: bidentate hydroxypyranone, bidentate hydroxypyridinone, hexadentate hydroxypyranone and hexadentate hydroxypyridinone, each with different iron affinity constants. Competition studies demonstrate that the hexadentate hydroxypyridinone-based beads are capable of scavenging most of low molecular mass and albumin-bound iron but negligible amounts of iron from transferrin and ferritin. Serum samples from 30 patients with different types of disease and normal volunteers were measured. The concentrations of NTBI fall in the range -0.41 to +6.5 μM. The data have been compared with those obtained from the traditional 'NTA' method

Dynamic quantitative assays of phagosomal function

Much of the activity of the macrophage as an effector cell is performed within its phagocytic compartment. This ranges from the degradation of tissue debris as part of its homeostatic function, to the generation of the superoxide burst as part of its microbicidal response to infection. We have developed a range of real-time readouts of phagosomal function that enables these activities to be rigorously quantified. This chapter contains the description of several of these assays assessed by different methods of quantitation; including a Fluorescence Resonance Emission Transfer (FRET) assay for phagosome/lysosome fusion measured by spectrofluorometer, a fluorogenic assay for the superoxide burst measured by flow cytometry, and a fluorogenic assay for bulk proteolysis measure by confocal microscope. These assays illustrate both the range parameters that can be quantified as well as the flexibility of instrumentation that can be exploited for their quantitation