Dmitri B. Papkovsky

New oxygen sensors and their application to biosensing

Abstract Recent developments in quenched-luminescence oxygen sensors based on application of phosphorescent probes are discussed. They include the development of new oxygen probes on the basis of the derivative of platinum octaethylporphine, which have improved working characteristics and high compatibility with light-emitting diode excitation. New oxygen probes make it possible to construct compact, simple and cheap measurement device(s) using customized semiconductor optoelectronics. A working prototype fibre-optic intensity-based oxygen sensor was developed. Creation of such a device and its study proved the possibility of its further transformation into a device realizing the lifetime-based sensing approach. Several new applications of phosphorescent sensing materials are presented. They cover enzymatic systems and a ‘cytosensor’ arrangement on the basis of the lifetime-based fibre-optic oxygen sensor, and long-decay phosphorescent coating for sensing in the low oxygen range. Special emphasis is placed on the development of new phosphorescent Langmuir-Blodgett coatings and their application to sensing of SO 2 and NO χ in the presence of a large excess of oxygen. Practical usefulness and future prospects of this new family of sensors in comparison with alternative systems are discussed.

Intracellular O2 Sensing Probe Based on Cell-Penetrating Phosphorescent Nanoparticles

A new intracellular O(2) (icO(2)) sensing probe is presented, which comprises a nanoparticle (NP) formulation of a cationic polymer Eudragit RL-100 and a hydrophobic phosphorescent dye Pt(II)-tetrakis(pentafluorophenyl)porphyrin (PtPFPP). Using the time-resolved fluorescence (TR-F) plate reader set-up, cell loading was investigated in detail, particularly the effects of probe concentration, loading time, serum content in the medium, cell type, density, etc. The use of a fluorescent analogue of the probe in conjunction with confocal microscopy and flow cytometry analysis, revealed that cellular uptake of the NPs is driven by nonspecific energy-dependent endocytosis and that the probe localizes inside the cell close to the nucleus. Probe calibration in biological environment was performed, which allowed conversion of measured phosphorescence lifetime signals into icO(2) concentration (μM). Its analytical performance in icO(2) sensing experiments was demonstrated by monitoring metabolic responses of mouse embryonic fibroblast cells under ambient and hypoxic macroenvironment. The NP probe was seen to generate stable and reproducible signals in different types of mammalian cells and robust responses to their metabolic stimulation, thus allowing accurate quantitative analysis. High brightness and photostability allow its use in screening experiments with cell populations on a commercial TR-F reader, and for single cell analysis on a fluorescent microscope.

PGC-1α is coupled to HIF-1α-dependent gene expression by increasing mitochondrial oxygen consumption in skeletal muscle cells

Mitochondrial biogenesis occurs in response to increased cellular ATP demand. The mitochondrial electron transport chain requires molecular oxygen to produce ATP. Thus, increased ATP generation after mitochondrial biogenesis results in increased oxygen demand that must be matched by a corresponding increase in oxygen supply. We found that overexpression of peroxisome proliferator-activated receptor-γ coactivator 1α (PGC-1α), which increases mitochondrial biogenesis in primary skeletal muscle cells, leads to increased expression of a cohort of genes known to be regulated by the dimeric hypoxia-inducible factor (HIF), a master regulator of the adaptive response to hypoxia. PGC-1α-dependent induction of HIF target genes under physiologic oxygen concentrations is not through transcriptional coactivation of HIF or up-regulation of HIF-1α mRNA but through HIF-1α protein stabilization. It occurs because of intracellular hypoxia as a result of increased oxygen consumption after mitochondrial biogenesis. Thus, we propose that at physiologic oxygen concentrations, PGC-1α is coupled to HIF signaling through the regulation of intracellular oxygen availability, allowing cells and tissues to match increased oxygen demand after mitochondrial biogenesis with increased oxygen supply.

Emerging Applications of Phosphorescent Metalloporphyrins

The subject of phosphorescent metalloporphyrins is reviewed, focusing mainly on the development and application of Pt- and Pd-porphyrins. A summary of their general chemical and photophysical properties, and guidelines for rational design of the phosphorescent labels, bioconjugates and probes is given. Examples of different detection formats and particular bioanalytical applications developed in recent years are presented. The potential of phosphorescent porphyrin label methodology is discussed and compared to that of the long-decay fluorescent lanthanide chelates and other common fluorophores.

Optical probes and techniques for O2 measurement in live cells and tissue

In recent years, significant progress has been achieved in the sensing and imaging of molecular oxygen (O2) in biological samples containing live cells and tissue. We review recent developments in the measurement of O2 in such samples by optical means, particularly using the phosphorescence quenching technique. The main types of soluble O2 sensors are assessed, including small molecule, supramolecular and particle-based structures used as extracellular or intracellular probes in conjunction with different detection modalities and measurement formats. For the different O2 sensing systems, particular attention is paid to their merits and limitations, analytical performance, general convenience and applicability in specific biological applications. The latter include measurement of O2 consumption rate, sample oxygenation, sensing of intracellular O2, metabolic assessment of cells, and O2 imaging of tissue, vasculature and individual cells. Altogether, this gives the potential user a comprehensive guide for the proper selection of the appropriate optical probe(s) and detection platform to suit their particular biological applications and measurement requirements.

Analysis of mitochondrial function using phosphorescent oxygen-sensitive probes

Mitochondrial dysfunction has been associated with a variety of currently marketed therapeutics and has also been implicated in many disease states. Alterations in the rate of oxygen consumption are an informative indicator of mitochondrial dysfunction, but the use of such assays has been limited by the constraints of traditional measurement approaches. Here, we present a high-throughput, fluorescence-based methodology for the analysis of mitochondrial oxygen consumption using a phosphorescent oxygen-sensitive probe, standard microtitre plates and plate reader detection. The protocol describes the isolation of mitochondria from animal tissue, initial establishment and optimization of the oxygen consumption assay, subsequent screening of compounds for mitochondrial toxicity (uncoupling and inhibition), data analysis and generation of dose-response curves. It allows dozens of compounds (or hundreds of assay points) to be analyzed in a single day, and can be further up-scaled, automated and adapted for other enzyme- and cell-based screening applications.

Metabolic Profiling of Hypoxic Cells Revealed a Catabolic Signature Required for Cell Survival

Hypoxia is one of the features of poorly vascularised areas of solid tumours but cancer cells can survive in these areas despite the low oxygen tension. The adaptation to hypoxia requires both biochemical and genetic responses that culminate in a metabolic rearrangement to counter-balance the decrease in energy supply from mitochondrial respiration. The understanding of metabolic adaptations under hypoxia could reveal novel pathways that, if targeted, would lead to specific death of hypoxic regions. In this study, we developed biochemical and metabolomic analyses to assess the effects of hypoxia on cellular metabolism of HCT116 cancer cell line. We utilized an oxygen fluorescent probe in anaerobic cuvettes to study oxygen consumption rates under hypoxic conditions without the need to re-oxygenate the cells and demonstrated that hypoxic cells can maintain active, though diminished, oxidative phosphorylation even at 1% oxygen. These results were further supported by in situ microscopy analysis of mitochondrial NADH oxidation under hypoxia. We then used metabolomic methodologies, utilizing liquid chromatography–mass spectrometry (LC-MS), to determine the metabolic profile of hypoxic cells. This approach revealed the importance of synchronized and regulated catabolism as a mechanism of adaptation to bioenergetic stress. We then confirmed the presence of autophagy under hypoxic conditions and demonstrated that the inhibition of this catabolic process dramatically reduced the ATP levels in hypoxic cells and stimulated hypoxia-induced cell death. These results suggest that under hypoxia, autophagy is required to support ATP production, in addition to glycolysis, and that the inhibition of autophagy might be used to selectively target hypoxic regions of tumours, the most notoriously resistant areas of solid tumours.

G2019S leucine-rich repeat kinase 2 causes uncoupling protein-mediated mitochondrial depolarization

The G2019S leucine rich repeat kinase 2 (LRRK2) mutation is the most common genetic cause of Parkinsons disease (PD), clinically and pathologically indistinguishable from idiopathic PD. Mitochondrial abnormalities are a common feature in PD pathogenesis and we have investigated the impact of G2019S mutant LRRK2 expression on mitochondrial bioenergetics. LRRK2 protein expression was detected in fibroblasts and lymphoblasts at levels higher than those observed in the mouse brain. The presence of G2019S LRRK2 mutation did not influence LRRK2 expression in fibroblasts. However, the expression of the G2019S LRRK2 mutation in both fibroblast and neuroblastoma cells was associated with mitochondrial uncoupling. This was characterized by decreased mitochondrial membrane potential and increased oxygen utilization under basal and oligomycin-inhibited conditions. This resulted in a decrease in cellular ATP levels consistent with compromised cellular function. This uncoupling of mitochondrial oxidative phosphorylation was associated with a cell-specific increase in uncoupling protein (UCP) 2 and 4 expression. Restoration of mitochondrial membrane potential by the UCP inhibitor genipin confirmed the role of UCPs in this mechanism. The G2019S LRRK2-induced mitochondrial uncoupling and UCP4 mRNA up-regulation were LRRK2 kinase-dependent, whereas endogenous LRRK2 levels were required for constitutive UCP expression. We propose that normal mitochondrial function was deregulated by the expression of G2019S LRRK2 in a kinase-dependent mechanism that is a modification of the normal LRRK2 function, and this leads to the vulnerability of selected neuronal populations in PD.

Methods in optical oxygen sensing: protocols and critical analyses.

Publisher Summary This chapter discusses the protocols for different methods in optical oxygen sensing. It focuses on basic principles of quenched-luminescence oxygen sensing and provides general strategies for the selection of the appropriate oxygen probe, detection principle, assay format, and experimental setups. Several typical applications and assay protocols have high practical utility and employ commercial instrumentation, materials, and accessory tools— namely, (1) noninvasive measurement of the oxygen concentration in a sealed vessel, (2) monitoring of oxygen uptake rates by living organisms and cells, and (3) microplate-based screening assays for cell viability and effector action on cells. These systems are then analyzed critically to outline their characteristics features, performance characteristics, advantages and limitations, and potential biolanalytical uses. Principles of quenched-luminescence oxygen sensing and protocol on contactless monitoring of oxygen concentration in a sealed vessel using the phase-fluorimetric oxygen sensor system are also discussed.

Fluorescence-Based Cell Viability Screening Assays Using Water-Soluble Oxygen Probes

A simple luminescence-based assay for screening the viability of mammalian cells is described, based on the monitoring of cell respiration by means of a phosphorescent water-soluble oxygen probe that responds to changes in the concentration of dissolved oxygen by changing its emission intensity and lifetime. The probe was added at low concentrations (0.3 μM to 0.5 nM) to each sample containing a culture of cells in the wells of a standard 96-well plate. Analysis of oxygen consumption was initiated by applying a layer of mineral oil on top of each sample followed by monitoring of the phosphorescent signal on a prompt or time-resolved fluorescence plate reader. Rates of oxygen uptake could be determined on the basis of kinetic changes of the phosphorescence (initial slopes) and correlated with cell numbers (105 to 107 cells/mL for FL5.12 lymphoblastic cell line), cell viability, or drug/effector action using appropriate control samples. The assay is cell noninvasive, more simple, robust, and cost-effective than existing microplate-based cell viability assays; is compatible with existing instrumentation; and allows for high-throughput analysis of cell viability. (Journal of Biomolecular Screening 2003:264-272)