Multichannel microspectrofluorometry for topographic and spectral analysis of NAD(P)H fluorescence in single living cells

Structural properties of chimeric peptides containing a T-cell epitope linked to a fusion peptide and their importance for in vivo induction of cytotoxic T-cell responses

We have previously shown that when administered to mice without adjuvant, a chimeric peptide consisting of the fusion peptide F from measles virus protein linked at the C-terminus of a cytotoxic T-cell epitope from the M2 protein of respiratory syncytial virus efficiently primes for an major histocompatibility complex (MHC) class-I restricted cytotoxic T lymphocyte (CTL) response. In this report, we demonstrated by microspectrofluorometry that the fusion-peptide moiety bound to the plasma membrane of living cells. When the fusion peptide was linked to the C-terminus of the CTL epitope, the chimeric peptide (M2-F) adopted a marked beta-sheet conformation. In contrast, when the fusion peptide was linked to the N-terminus of the T-cell epitope (F-M2), the chimeric peptide adopted an alpha-helical conformation in the presence of trifluoroethanol. The immunogenicity of the two chimeric peptides for class-I restricted CTL was also significantly different, the one adopting the alpha-helical conformation being more immunogenic. Probably due to its obvious conversion to an alpha-helical conformation, the F-M2 peptide could have a higher propensity to insert into membranes, as shown by microspectrofluorometry, with a resultant better immunogenicity than the M2-F peptide.

Analysis of enzyme reactions in situ

Estimations of metabolic rates in cells and tissues and their regulation on the basis of kinetic properties of enzymes in diluted solutions may not be applicable to intact living cells or tissues. Enzymes often behave differently in living cells because of the high cellular protein content that can lead to homologous and heterologous associations of protein molecules. These associations often change the kinetics of enzymes as part of post-translational regulation mechanisms. An overview is given of these interactions between enzyme molecules or between enzyme molecules and structural elements in the cell, such as the cytoskeleton. Biochemical and histochemical methods are discussed that have been developed for in vivo and in situ analyses of enzyme reactions, particularly for the study of effects of molecular interactions. Quantitative (histochemical) analysis of local enzyme reactions or fluxes of metabolites has become increasingly important. At present, it is possible to calculate local concentrations of substrates in cells or tissue compartments and to express local kinetic parameters in units that are directly comparable with those obtained by biochemical assays of enzymes in suspensions. In situ analysis of the activities of a number of enzymes have revealed variations in their kinetic properties (Km and Vmax) in different tissue compartments. This stresses the importance of in vivo or in situ analyses of cellular metabolism. Finally, histochemical determinations of enzyme activity in parallel with immunohistochemistry for the detection of the total number of enzyme molecules and in situ hybridization of its messenger RNA allow the analysis of regulation mechanisms at all levels between transcription of the gene and post-translational activity modulation.

Fluorescence ratio imaging microscopy: temporal and spatial measurements of cytoplasmic pH

Fluorescence ratio imaging microscopy (Tanasugarn, L., P. McNeil, G. Reynolds, and D. L. Taylor, 1984, J. Cell Biol., 98:717-724) has been used to measure the spatial variations in cytoplasmic pH of individual quiescent and nonquiescent Swiss 3T3 cells. Fundamental issues of ratio imaging that permit precise and accurate temporal and spatial measurements have been addressed including: excitation light levels, lamp operation, intracellular probe concentrations, methods of threshold selection, photobleaching, and spatial signal-to-noise ratio measurements. Subcellular measurements can be measured accurately (less than 3% coefficient of variation) in an area of 3.65 microns 2 with the present imaging system. Quiescent Swiss 3T3 cells have a measured cytoplasmic pH of 7.09 (0.01 SEM), whereas nonquiescent cells have a pH of 7.35 (0.01 SEM) in the presence of bicarbonate buffer. A unimodal distribution of mean cytoplasmic pH in both quiescent and nonquiescent cells was identified from populations of cells measured on a cell by cell basis. Therefore, unlike earlier studies based on cell population averages, it can be stated that cells in each population exhibit a narrow range of cytoplasmic pH. However, the mean cytoplasmic pH can change based on the physiological state of the cells. In addition, there appears to be little, if any, spatial variation in cytoplasmic pH in either quiescent or nonquiescent Swiss 3T3 cells. The pH within the nucleus was always the same as the surrounding cytoplasm. These values will serve as a reference point for investigating the role of temporal and spatial variations in cytoplasmic pH in a variety of cellular processes including growth control and cell movement.

Multichannel analysis of intracellular control and intercellular transfer of molecules

The metabolic regulation and exchanges within intracellular organelles or a cell cluster are studied by multichannel microfluorometry and microinjection of metabolites or tracers. The determination of structure-function relationships relies on the retrieval of cells after microfluorometry, for subsequent morphological evaluation. Rate constants of coenzyme reduction-reoxidation were deduced from a mathematical model of NAD(P) in equilibrium with NAD(P)H transients due to microinjection of metabolites into cultured cells belonging to a variety of normal or malignant lines. Nuclear and cytoplasmic sites operate synchronously or not, depending upon metabolic demand or pathological alterations. Intercellular transit times are determined for tracers and metabolites. Within cell clusters 'communicating territories' are described, which can show metabolically a multicellular integrated state. Microfluorometry in conjunction with ultrastructural and other studies can be used to develop a cybernetic model of the living cell, also yielding dynamic models of cooperative and regulatory interactions between different kinds of specialised cells within a cell cluster.

Intercellular communication in pancreatic islet monolayer cultures: a microfluorometric study

Single islet cells in monolayer cultures of neonatal rat pancreas were microinjected with fluorescein and scanned topographically by microfluorometry. Fluorescein spread from an injected islet cell directly into neighboring islet cells, and, in the presence of 16.7 millimolar glucose, significantly more islet cells communicated with the injected cell than in glucose-free medium. Islet cells were also microinjected with glycolytic substrates and activators that produced transient changes in cellular levels of reduced pyridine nucleotides-nicotinamide adenine dinucleotide and nicotinamide adenine dinucleotide phosphate [NAD(P)H]. Changes in NAD(P)H fluorescence were observed in islet cells incubated first for 18 hours in very low glucose concentrations and then in a glucose-free medium and injected with glycolytic substrates and activators; however, little change of fluorescence occurred in adjacent islet cells. In contrast, after adding 16.7 millimolar glucose to the medium, injection of glycolytic substrates and activators produced transient changes in NAD(P)H fluorescence in the injected cell and in neighboring cells.

The effect of atebrine and an acridine analog (BCMA) on the coenzyme fluorescence spectra of cultured melanoma and Ehrlich ascites (EL2) cells

Coenzyme fluorescence spectra of single living cells are due to free pyridine nucleotides (folded configuration), bound pyridine nucleotides (unfolded configuration) and a third component, possibly a mixture or flavins. Such spectra can be used to recognize possible differences in coenzyme composition between cell lines or changes of metabolic pathways due to chemicals acting at levels below or above cytotoxicity, by high resolution spectrofluorometry. A study of spectra recorded from cultured Ehrlich ascites (EL2), and Harding Passey melanoma cells (HPM-67 and HPM-73 line) grown under comparable conditions, shows that free NAD(P)H predominates in HPM-67 and EL2, while this coenzyme is bound in HPM-73. The free/bound ratio may be profoundly modifed by chemicals, e.g. in the HPM-73 increase of free and decrease of bound NAD(P)H occurred upon treatment with 10(-6) oligomycin. When atebrine at levels (10(-6) M) below cytotoxicity was added, there was a decrease of the free NAD(P)H spectrum possibly through energy transfer from NAD(P)H to atebrine. Consideration of long range energy transfer i.e., excitation of atebrine by fluorescence of NAD(P)H vs. short range transfer of excitation energy from free NAD(P)H to atebrine, favors the latter mechanism. A transient (reversible) increase in atebrine fluorescence is seen following intracellular microinjection of substrate (e.g. glucose-6-P) leading to an increase in free NAD(P)H. At cytotoxic levels of atebrine (e.g 2 x 10(-5) M) an irreversible increase of atebrine fluorescence is seen. The microspectrofluorometric technique appears therefore well suited to study physiological processes at the level of intracellular coenzymes, as well as possible processes of intermolecular energy transfer in the microenvironment.

Rapid microspectrofluorometric studies in EL2 cells following intracellular accumulation of dibenzocarbazoles

Microspectrofluorometric observations were carried out in EL2 ascites cancer cells and dibenzo(a,e)fluoranthene (diB(a,e)F)-grown EL2 cells, following treatment (5 min) with three dibenzocarbazoles (1,2,7,8; 1,2,5,6 and 3,4,5,6). After microinjection of glucose-6-P leading to reduction of NAD(P), a sequence of difference spectra (after substrate minus before) is recorded. In dibenzocarbazole-untreated cells, maximum (NAD(P) reduction (emission maximum at 465-475 nm) is attained within 5 s, followed by a gradual return to initial fluorescence within 20 to 200 s (faster in the diB(a,e)F-grown). In dibenzocarbazole-treated cells there is a rather regular increase in the intensity of the difference spectrum up to approximately 300-500 s. Initially the increase is more predominant in the region around 460-470 nm, but it gains later prominence in the shorter wavelength region (420-430 nm) characteristic of the hydrocarbon (higher and steadier increase in the 3,4,5,6, dibenzocarbazole-treated diB(a,e)F-grown). Subsequently there is a gradual decrease of fluorescence which may or may or not return to initial level. The observed increase spectra require evaluation in terms of possible components (e.g. a mixture of NAD(P)H and hydrocarbon, binding changes, succession of fluorescent metabolites).

A preliminary microspectrofluorometric study of NAD(P) reduction in dibenzo(a, e) fluoranthene-treated single living cells

The fluorescence increase, due to NAD(P) reduction, following microelectrophoretic injection of glucose 6-P (G6P) into EL2 and NCTC 8739 single living cells treated with diBenzo(ae) Fluoranthene (diB(ae)F) and non-treated, has been studied with a rapid microspectrofluorometer. This study shows the enhanced capacity of treated cells to utilize larger doses (6-10 times more) of G6P than control cells. The time course of the return to the initial fluorescence level is essentially related to the magnitude of the injection dose. There are alterations (e.g. red & blue shifts) in the fluorescence spectrum of diB(ae)F-treated cells before injection and in the increase spectrum after injection of G6P, as compared to the same spectra in the diB(ae)F-untreated cells. This is discussed in reference to the metabolization of diB(ae)F as an alternative pathway for the reoxidation of NAD(P)H.

The UV fading of hydrocarbon fluorescence and its prevention for observations in single living cells

Excitation intensities used for standard microspectrofluorometric observations of natural cell fluorescence, i.e. NAD(P)H, lead to fading of hydrocarbon (polycyclic aromatic, heterocyclic) fluorescence in EL2 cells incubated with such compounds. The disappearance of hydrocarbon fluorescence under excitation at 366 nm seems to be an exponential function of time. The fading prevents studies on hydrocarbon metabolization in correlation with intracellular microelectrophoretic injection of substrate, e.g. glucose-6-P. A return to 8-10 times less intense excitation conditions used in an earlier prototype microspectrofluorometer, has allowed the observation of sequential changes in the difference spectra (after glucose-6-P minus before) of hydrocarbon-treated cells (e.g. benzo(a)pyrene, dibenzocarbazols). The possible relative contributions of NAD(P)H and hydrocarbon metabolites (or alterations) to such sequential spectra are still under consideration, but the main obstacle to their observation, fading, is removed by less intense excitation.