A comparison of the fluorescence properties of TMA-DPH as a probe for plasma membrane and for endocytic membrane.

In earlier studies, the fluorescence probe 1-(4-(trimethylamino)phenyl)-6-phenylhexa-1,3,5-triene (TMA-DPH) was shown to interact with living cells by instantaneous incorporation into the plasma membrane, according to a water (probe not fluorescent)/membrane (probe highly fluorescent) partition equilibrium. This made it interesting both as a fluorescence anisotropy probe for plasma membrane fluidity determinations and as a quantitative tracer for endocytosis and intracellular membrane traffic. In order to ascertain the limiting concentrations for its use in these applications, we performed a systematic study of its fluorescence properties (intensity, lifetime, anisotropy) in the plasma membrane and in endocytic membranes of intact L929 mouse fibroblasts. Some of the experiments were repeated on mouse-bone-marrow-derived macrophages and on phospholipidic LUV to confirm the results. Rather unexpectedly, it was observed that: (i) the incorporation of TMA-DPH into the membranes, monitored by UV absorption measurements, remained proportional to the probe concentration over the wide range explored (5 x 10(-7) M-2.5 x 10(-5) M); (ii) however, concerning fluorescence, quenching effects occurred in the membranes above certain critical concentrations. These effects were shown to result from Förster-type resonance auto-transfer; (iii) strikingly, the critical concentrations were considerably higher in early-endocytic-vesicle membranes than in the bulk plasma membrane. It was established that membrane fluidity was involved and this was confirmed by the parallel study on phospholipidic vesicles. Potential applications of these properties as a novel approach for evaluating membrane fluidity are suggested.

Contrary results on mouse hepatitis virus type 3 susceptibility in A/J mouse hepatocytes of phosphatidylserine treatment and of a hypercholesterolaemic diet: no correlation with membrane fluidity levels.

The aim of this study was to examine whether or not membrane fluidity directly influences infection by enveloped viruses, and, more precisely here, the susceptibility of A/J mouse hepatocytes to Mouse Hepatitis Virus type 3 (MHV3). We therefore studied, in parallel, the effects on hepatocyte membrane fluidity and on intracellular viral titre of two treatments, i) a hypercholesterolaemic diet to increase the hepatocyte membrane cholesterol content, ii) direct phosphatidylserine incorporation into hepatocyte membrane. Membrane fluidity was monitored on isolated hepatocytes by fluorescence anisotropy with TMA-DPH, and the viral titre was determined by plaque assay. The results clearly demonstrate that membrane fluidity is not directly involved in viral infection mechanisms.

The kinetic aspects of intracellular fluorescence labeling with TMA-DPH support the maturation model for endocytosis in L929 cells.

TMA-DPH (1-(4-trimethylammonium)-6-phenyl-1,3,5-hexatriene), a hydrophobic fluorescent membrane probe, interacts with living cells by instantaneous incorporation into the plasma membrane, where it becomes fluorescent. It then follows the intracellular constitutive membrane traffic and acts as a bulk membrane marker of the endocytic pathway (Illinger, D., P. Poindron, P. Fonteneau, M. Modolell, and J. G. Kuhry. 1990. Biochim. Biophys. Acta. 1030:73-81; Illinger, D., P. Poindron, and J. G. Kuhry. 1991. Biol. Cell. 73:131-138). As such, TMA-DPH displays particular properties mainly due to partition between membranes and aqueous media. From these properties, original arguments can be inferred in favor of the maturation model for the endocytic pathway, against that of pre-existing compartments, in L929 cultured mouse fibroblasts. (a) TMA-DPH labeling is seen to progress from the cell periphery to perinuclear regions during endocytosis without any noticeable loss in fluorescence intensity; with a vesicle shuttle model this evolution would be accompanied by probe dilution with a decrease in the overall intracellular fluorescence intensity, and the labeling of the inner (late) compartments could in no way become more intense than that of the peripheral (early) ones. (b) From TMA-DPH fluorescence anisotropy assays, it is concluded that membrane fluidity is the same in the successive endocytic compartments as in the plasma membrane, which probably denotes a similar phospholipidic membrane composition, as might be expected in the maturation model. (c) TMA-DPH internalization and release kinetics are more easily described with the maturation model.

Comparative evolution of endocytosis levels and of the cell surface area during the L929 cell cycle: a fluorescence study with TMA-DPH.

1-[4-(trimethylamino)phenyl]-6-phenylhexa-1,3,5-triene (TMA-DPH), a membrane fluorescence probe, interacts with living cells by instantaneous partition between the external medium and the plasma membrane, where it becomes fluorescent. The corresponding fluorescence intensity is then proportional to the cell surface. On the other hand, once incorporated into the plasma membrane, TMA-DPH follows this membrane in the constitutive intracellular traffic and behaves as a monitor for endocytosis. Using this tool on L929 synchronized cells, we showed that the endocytosis levels after 30 min uptake of the probe increased from G1 to mitosis, when they abruptly decreased. The cell surface remained constant throughout the cell cycle, except at the beginning of mitosis when it almost doubled.

Membrane fluidity aspects in endocytosis; a study with the fluorescent probe trimethylamino-diphenylhexatriene in L929 cells.

The fluorescent hydrophobic plasma membrane probe, trimethylamino-diphenylhexatriene (TMA-DPH) was previously shown to follow the plasma membrane throughout its internalization and recycling process and thus to behave as a marker for endo- and exocytosis in living cell systems. In this paper, we made use of these properties to investigate membrane fluidity effects associated with endocytosis in L929 cells. For that purpose we performed TMA-DPH fluorescence anisotrophy measurements which showed that endocytosis starts from particularly rigid regions of the plasma membrane (probably coated pits). The fluorescence anisotropy then continuously decreases to a lower limit corresponding to the membrane fluidity of the probe in the lysosomial membrane. Strikingly, the value of this limit is identical to the average anisotropy value in the peripheral membrane, which suggests that lysosomes and plasma membrane may have a similar phospholipidic composition and a possible common origin.

Fluid phase endocytosis investigated by fluorescence with trimethylamino-diphenylhexatriene in L929 cells; the influence of temperature and of cytoskeleton depolymerizing drugs.

The temperature-dependence of fluid phase endocytosis was investigated in L929 cells, using a recently described fluorescence approach with trimethylamino-diphenylhexatriene (TMA-DPH). In interaction with cells, this probe is rapidly incorporated into the plasma membrane and follows its intracellular traffic of internalization-recycling, thus behaving as a suitable marker for fluid phase endocytosis. The kinetics of the process may be followed accurately by simple fluorescence intensity measurements, while complementary fluorescence anisotropy and micrographic data may be obtained in parallel with the same probe. It was shown that the formation of endocytic vesicles was not inhibited by cooling the cells, even down to 4 degrees C, but only reduced in a quasi-linear way with temperature. Conversely the further fusion events between the vesicles and large vacuolar bodies (endosomes, lysosomes) were strongly and discontinuously influenced: they were almost totally suppressed below 15 degrees C. The evolution of the membrane fluidity during endocytosis, which was monitored by fluorescence anisotropy measurements, indicated that the fusion inhibition was probably correlated with the inability of the endocytic vesicles to shed their initial clathrin coat at low temperature. Moreover, microscopic observations showed that at low temperature the endocytic vesicles hardly moved from the place of their formation. Pretreatment of the cells with microtubule and microfilament depolymerizing drugs (cytochalasin B, vinblastine) led to the conclusion that the cytoskeleton played little role in the vesicle movements. Altogether, the results suggested that the progression of the vesicles towards the cell core resulted from successive fusion events, which explained why they were considerably slowed down by cooling.

Internalization of the lipophilic fluorescent probe trimethylamino-diphenylhexatriene follows the endocytosis and recycling of the plasma membrane in cells.

The lipophilic fluorescent probe trimethylamino-diphenylhexatriene (TMA-DPH) has been shown previously to behave as a marker of plasma membrane in living cell systems, and it has therefore been widely used in membrane fluidity studies via fluorescence anisotropy measurements. However, progressive internalization of this probe in cells could lead to unsuitable interferences, when long incubations times were required. The mechanism of this internalization had not yet been elucidated. We present here fluorescence-intensity kinetic results and fluorescence micrographic data on L929 cells and on mouse bone-marrow macrophages, which allow us to identify the mechanism as fluid-phase pinocytosis: the probe remains associated with the plasma membrane throughout its internalization-recycling flow and it is finally concentrated in lysosomes. The study was facilitated by the partition equilibrium property of TMA-DPH between plasma membranes and the external aqueous medium, which allowed to immediately distinguish the internalized fraction of the probe from the peripheral labelling, by simply washing cells. This conclusion is confirmed by the features of the influence of temperature on TMA-DPH internalization.

The plasma-membrane internalization and recycling is enhanced in macrophages upon activation with gamma-interferon and lipopolysaccharide; a study using the fluorescent probe trimethylaminodiphenylhexatriene.

The lipophilic fluorescent probe trimethylaminodiphenylhexatriene (TMA-DPH), previously used as a plasma membrane marker in membrane fluidity and exocytosis studies, was shown, to monitor the plasma-membrane internalization-recycling shuttle movement in cells. Using this approach we present here kinetic and dose-response data, which give evidence that the plasma membrane flow is enhanced in bone marrow macrophages from various mouse strains, upon in vitro activation with gamma interferon (IFN-gamma) or bacterial lipopolysaccharide (LPS), within physiological dose ranges. The effect studied evolved in line with the usual development kinetics of macrophage activation. Complementary assays on membrane fluidity, surface charge density and membrane surface indicated no related changes. From these experiments it is concluded that the observed enhancement of the plasma membrane traffic does not originate from specific limited membrane modifications, but is merely a particular feature of the overall macrophage activation.

TMA-DPH a fluorescent probe of membrane dynamics in living cells. How to use it in phagocytosis.

Trimethylammonium-diphenylhexatriene (TMA-DPH), a hydrophobic fluorescent probe, has been shown in earlier studies to possess a variety of particular properties in interaction with intact living cells--specific and rapid incorporation into the plasma membrane and partition equilibrium between the membranes and the buffer. These properties offer promising applications in membrane fluidity studies and in monitoring exocytosis kinetics. Furthermore, these properties offer a method described here for quantitative monitoring of phagocytosis kinetics, by means of simple fluorescence intensity measurements. This method is original in that it evaluates only the particles which have actually been internalized by phagocytosis, and not those adsorbed on the cell surface, and that it gives quantitative information on the amount of plasma membrane involved in the process. It has been tested on mouse bone marrow macrophages.

Establishment and characterization of long-term cultured cell lines of murine resident macrophages.

Murine resident macrophages can proliferate in vitro when they are grown in coculture on a layer of mesothelial or endothelial type feeder cells. Resident macrophages were obtained from lung explants of C57Bl/6 lpr/lpr mice and from spleen explants or peritoneal washing of Balb/c mice; the cells were seeded without further washing. After 3-4 weeks of culture, the macrophages began to proliferate on a confluent layer of feeder cells. The macrophages then could be collected in the fluid phase and reseeded for permanent culture after generation of a new feeder layer. These cells were characterized as macrophages by the following criteria: 1) their morphology, ultrastructure, and adherence properties; 2) more than 90% of the macrophages phagocytized yeasts compared with less than 1% of the feeder cells; 3) the presence of functional Fc and mannose receptors, nonspecific cytoplasmic esterases, and membrane ectoenzymes such as nicotinamide adenine dinucleotide (NAD) glycohydrolase and nucleotide pyrophosphatase; 4) by cytofluorographic phenotype analysis with monoclonal antibodies, characterizing a normal macrophage population (MAC1+, Fcrec+, H-2K+, THY1-, LYT2-, L3T4-). 5) by functional studies proving that the expanded macrophages could function as accessory cells in the induction of lymphocyte proliferation in response to concanavalin A (Con A), that they generated reactive oxygen radicals and that they were cytotoxic for tumor cells. During coculture, growth or activating factors such as macrophage colony-stimulating factor or gamma-interferon were released in the medium. Long-term cultured macrophages had chromosomal abnormalities. Our study suggests that tissue macrophages can proliferate in vitro and hence that it is possible to establish long-term cultured cell lines of macrophages of defined and reproducible characteristics.

Radiation therapy of spontaneous autoimmunity: a review of mouse models.

The classical types of generalized autoimmune disease in man are systemic lupus erythematosus (SLE) and rheumatoid arthritis (RA). Several murine strains which develop SLE and sometimes RA-like diseases are now available. They should help in the understanding of the etiopathology of SLE and RA. Basically two main therapeutic strategies which use solely irradiation have been tried; one being sublethal whole-body irradiation (WBI) and the other fractionated total lymphoid irradiation (TLI). Other protocols which combine lethal WBI and stem cell transplantation have often been attempted. It was regularly found that the bone marrow transplant (BMT) dictates the immune status of the recipient. This paper reviews the data published about NZB, NZB/W, BXSB and MRL mice in this context.

Lack of association between the elevation of adenosine 3',5'-cyclic monophosphate and the potentiation of the interferon-induced antiviral state by noradrenaline in normal and tumoral rat cells.

Rat interferon (IF) induced a moderate and persistent elevation of adenosine 3',5'-cyclic monophosphate (cAMP) after 6 h of contact with rat embryo fibroblasts (REFs), whereas in rat glial tumoral c6 cells IF did not enhance cAMP. Noradrenaline potentiated the antiviral state of REFs treated for 2 h or more with IF and increased cAMP in these cells, but it did not potentiate the IF-induced antiviral state of C6 cells. However, as the control cells, IF-treated C6 cells responded to catecholamines by a 100-fold or more increase in cAMP. This suggested that cAMP was not primarily involved in the establishment of the antiviral state.