Rachel Jane Errington

Characteristics of a novel deep red/infrared fluorescent cell-permeant DNA probe, DRAQ5, in intact human cells analyzed by flow cytometry, confocal and multiphoton microscopy.

BACKGROUNDnThe multiparameter fluorometric analysis of intact and fixed cells often requires the use of a nuclear DNA discrimination signal with spectral separation from visible range fluorochromes. We have developed a novel deep red fluorescing bisalkylaminoanthraquinone, DRAQ5 (Ex(lambdamax) 646 nm; Em(lambdamax) 681 nm; Em(lambdarange) 665->800 nm), with high affinity for DNA and a high capacity to enter living cells. We describe here the spectral characteristics and applications of this synthetic compound, particularly in relation to cytometric analysis of the cell cycle.nnnMETHODSnCultured human tumor cells were examined for the ability to nuclear locate DRAQ5 using single and multiphoton laser scanning microscopy (LSM) and multiparameter flow cytometry.nnnRESULTSnMultiparameter flow cytometry shows that the dye can rapidly report the cellular DNA content of live and fixed cells at a resolution level adequate for cell cycle analysis and the cycle-specific expression of cellular proteins (e.g., cyclin B1). The preferential excitation of DRAQ5 by laser red lines (633/647 nm) was found to offer a means of fluorescence signal discrimination by selective excitation, with greatly reduced emission overlap with UV-excitable and visible range fluophors as compared with propidium iodide. LSM reveals nuclear architecture and clearly defines chromosomal elements in live cells. DRAQ5 was found to permit multiphoton imaging of nuclei using a 1,047-nm emitting mode-locked YLF laser. The unusual spectral properties of DRAQ5 also permit live cell DNA analysis using conventional 488 nm excitation and the single-photon imaging of nuclear fluorescence using laser excitation between 488 nm and low infrared (IR; 780 nm) wavelengths. Single and multiphoton microscopy studies revealed the ability of DRAQ5 to report three-dimensional nuclear structure and location in live cells expressing endoplasmic reticulum targeted-GFP, MitoTracker-stained mitochondria, or a vital cell probe for free zinc (Zinquin).nnnCONCLUSIONnThe fluorescence excitation and emission characteristics of DRAQ5 in living and fixed cells permit the incorporation of the measurement of cellular DNA content into a variety of multiparameter cytometric analyses.

Statistical analysis of nanoparticle dosing in a dynamic cellular system

The delivery of nanoparticles into cells is important in therapeutic applications and in nanotoxicology. Nanoparticles are generally targeted to receptors on the surfaces of cells and internalized into endosomes by endocytosis, but the kinetics of the process and the way in which cell division redistributes the particles remain unclear. Here we show that the chance of success or failure of nanoparticle uptake and inheritance is random. Statistical analysis of nanoparticle-loaded endosomes indicates that particle capture is described by an over-dispersed Poisson probability distribution that is consistent with heterogeneous adsorption and internalization. Partitioning of nanoparticles in cell division is random and asymmetric, following a binomial distribution with mean probability of 0.52-0.72. These results show that cellular targeting of nanoparticles is inherently imprecise due to the randomness of nature at the molecular scale, and the statistical framework offers a way to predict nanoparticle dosage for therapy and for the study of nanotoxins.

Gap junction intercellular communication during lymphocyte transendothelial migration

Migration of lymphocytes across the endothelium of central or peripheral tissues, a process occurring following activation or differentiation, involves cell to cell interactions featuring adhesion and heterotypic signalling ‘cross‐talk’. Since lymphocytes and endothelial cells express connexins, the subunit proteins of gap junction intercellular channels, we investigated whether these channels feature in heterotypic signalling during transendothelial migration of lymphocytes. We show, using FACS analysis, that calcein, a gap junction permeant fluorescent dye, was transferred from endothelial cell layers to lymphocytes. The gap junction involvement in intercellular dye transfer was reinforced by studies showing that the process was inhibited by connexin mimetic peptides, a new class of reagents shown to block gap junction communication. Further evidence for the involvement of lymphocyte gap junctions in intercellular communication during transendothelial migration was obtained by two‐photon laser scanning microscopy. Although gap junctional communication was inhibited by connexin mimetic peptides, they had little influence on the transmigration process.

A mathematical model predicts that calreticulin interacts with the endoplasmic reticulum Ca2+-ATPase

A robust mathematical model developed from single cell calcium (Ca(2+)) dynamics has enabled us to predict the consequences of over-expression of endoplasmic reticulum-located chaperones. Model predictions concluded that calreticulin interacts with the lumenal domain of the sarcoplasmic and endoplasmic reticulum Ca(2+)-activated ATPase (SERCA) pump, altering pump affinity for Ca(2+) (K(1/2) switches from 247 to 431 nM) and hence generating Ca(2+) oscillations. Expression of calreticulin in the ER generated an average of six transient-decline oscillations during the Ca(2+) recovery phase, upon exposure to maximal levels of the agonist ATP. In contrast, normal cells produced a single Ca(2+) transient with few or no oscillations. By conditioning the model to experimental data, parameters for generation and decay of IP(3) and SERCA pump kinetics were determined. To elucidate the possible source of the oscillatory behavior three possible oscillators, 1) IP(3), 2) IP(3)R, and 3) SERCA pump, were investigated and parameters constrained by experimental data to produce the best candidate. Each of the three oscillators generated very good fits with experimental data. However, converting a normal exponential recovery to a transient-decline oscillator predicted that the SERCA pump is the most likely candidate for calreticulin-mediated Ca(2+) release, highlighting the role of this chaperone as a signal protein within the endoplasmic reticulum.

DRAQ5 labeling of nuclear DNA in live and fixed cells.

This unit describes the use of a novel DNA‐detecting far‐red‐fluorescing dye, DRAQ5, a modified anthraquinone, which has a unique combination of properties exploitable by cytometry. These include a high capacity to permeate the cell membrane, a high DNA binding affinity and selectivity, a fluorescence emission spectrum beyond that of fluorescein, phycoerythrin, Texas Red, Cy3, and EGFP, and excitation characteristics separate from those of propidium iodide. In this unit, methods are presented for preparation and analysis of both live and fixed cells stained with DRAQ5. While the focus is on flow cytometric assays, typical imaging applications are also indicated because the staining protocols share the same essential features.

Identification of sequences required for the import of human protoporphyrinogen oxidase to mitochondria.

Protoporphyrinogen oxidase (PPOX; EC 1.3.3.4), the penultimate enzyme of haem biosynthesis, is a nucleus-encoded flavoprotein strongly associated with the outer surface of the inner mitochondrial membrane. It is attached to this membrane by an unknown mechanism that appears not to involve a membrane-spanning domain. The pathway for its import to mitochondria and insertion into the inner membrane has not been established. We have fused human PPOXs containing N-terminal deletions, C-terminal deletions or missense mutations to yellow fluorescent protein (YFP) and have used these constructs to investigate the mitochondrial import of PPOX in human cells. We show that all the information required for efficient import is contained within the first 250 amino acid residues of human PPOX and that targeting to mitochondria is prevented by fusion of YFP to the N-terminus. Deletion of between 151 and 175 residues from the N-terminus is required to abolish import, whereas shorter deletions impair its efficiency. Fully efficient targeting appears to require both a major targeting signal, the whole or part of which is contained between residues 151 and 175, and which may be involved in anchoring to the inner mitochondrial membrane, together with interaction between this region and a sequence(s) within the first 150 residues. These features suggest that the mechanism for import of human PPOX to mitochondria differs from those identified for the translocation of nucleus-encoded, membrane-spanning, inner membrane proteins. In addition, a missense mutation outside this region (Val(335)-->Gly) prevented targeting to mitochondria and delayed the appearance of YFP fluorescence. This mutation appeared to prevent import by a direct effect on protein folding rather than by altering a sequence required for targeting. It may lead to sequestration of the PPOX-YFP construct in an unfolded conformation, followed by proteolytic degradation, possibly through enhanced binding to a cytosolic chaperone protein.

Gap Junction Assembly: Multiple Connexin Fluorophores Identify Complex Trafficking Pathways

The assembly of gap junction channels was studied using mammalian cells expressing connexin (Cx) 26, 32 and 43 in which the carboxyl terminus was fused to green, yellow or cyan fluorescent proteins (GFP, YFP, CFP). Intracellular targeting of Cx32-CFP and 43-GFP to gap junctions was disrupted by brefeldin A treatment and resulted in a severe loss of gap junctional intercellular communication reflected by low intercellular dye transfer. Cells expressing Cx43-GFP exposed to nocodazole showed normal targeting to gap junctions and dye transfer. Cx32 and 43 thus appear to be transported and assembled into gap junctions via the classical secretory pathway. In contrast, we found that assembly of Cx26-GFP into functional gap junctions was relatively unaffected by treatment of cells with brefeldin A, but was extremely sensitive to nocodazole treatment. Coexpression of Cx26-YFP and Cx32-CFP indicated a different intracellular distribution that was accentuated in the presence of brefeldin A, with the gap junctions in these cells constructed predominantly of Cx26-YFP. A site specific mutation in the first transmembrane domain that distinguished Cx32 from Cx26 (Cx32128L) resulted in the adoption of the trafficking properties of Cx26 as well as its unusual post-translational membrane integration characteristics. The results indicate that multiple intracellular connexin trafficking routes exist and provide a further mechanism for regulating the connexin composition of gap junctions and thus specificity in intercellular signalling.

Kinetic modelling of the role of the aldehyde dehydrogenase enzyme and the breast cancer resistance protein in drug resistance and transport

A compartmental model for the in vitro uptake kinetics of the anti-cancer agent topotecan (TPT) has been extended from a previously published model. The extended model describes the drug activity and delivery of the pharmacologically active form to the DNA target as well as the catalysis of the aldehyde dehydrogenase (ALDH) enzyme and the elimination of drug from the cytoplasm via the efflux pump. Verification of the proposed model is achieved using scanning-laser microscopy data from live human breast cancer cells. Before estimating the unknown model parameters from the experimental in vitro data it is essential to determine parameter uniqueness (or otherwise) from this imposed output structure. This is formally performed as a structural identifiability analysis, which demonstrates that all of the unknown model parameters are uniquely determined by the output structure corresponding to the experiment.

Live Cell DNA Labeling and Multiphoton/Confocal Microscopy

Publisher Summary Techniques for the discrimination and location of DNA, chromatin architecture, chromosomes, nuclear superstructures, and cell nuclei in their various forms through the cell cycle are of increasing interest in the biosciences and the generation of automated screening systems. Advanced microscopy methods such as multiphoton excitation laser scanning (MPLSM) are now becoming more generally accessible, as they provide significant advantages in the live cell research. The technique of multiphoton excitation of a fluorophore, using a pulsed laser light source, provides solutions to several problems associated with continuous wave excitation via single photon absorption. Multiphoton excitation at wavelengths between 720 and 980 nm uses a laser-scanning microscope comprising a 1024 MP scanning unit controlled by LaserSharp software (Bio-Rad Cell Science Division) attached to a Zeiss Axiovert 135. When considering live cell labeling, the performance status of the cell is the most critical issue for achieving optimal staining. There is a subtle shift in the violet to red bias in the emission spectrum of Hoechst 33342 upon DNA binding.

Time-Resolved Measurements Using Stroboscopic Excitation

We describe the development of a novel stroboscopic excitation technique for performing time-resolved fluorescence measurements on an optical biochip format, where the time-resolution is provided by the variable repetition rate of a self-pulsing laser.