Identification of normal or neoplastic murine mesenchymal cells in chimeric tissues or heterotransplants

An improved method for identifying murine mesenchymal cells in chimeric tissues or heterotransplants using Hoechst dye 33258 is described. Following fixation in formalin-saline, tissues are embedded in JB-4 plastic. Sections 3 micron thick are then stained in a 10 microgram/ml solution of Hoechst 33258 in Hanks' balanced salt solution for 5-10 min at 4 C. After rising, the sections are coverslipped using a modified polyvinyl alcohol mounting medium. This approach offers several advantages over existing techniques: 1) uniform section thickness is more easily obtained than with paraffin or cryostat microtomy, thereby allowing improved resolution and more reliable identification of mesenchymal cells with small nuclei such as skeletal muscle myocytes or fibroblasts, 2) the preparations are stable over long periods and can be repeatedly viewed or photographed, and 3) calcified tissues can be examined without prior decalcification. An example is shown of species identification using rat chondrosarcoma cells grown in nude mice.     

A Novel Technique for Viable Cell Determinations

We have developed a simple method to determine cell viability using two fluorescent dyes, Hoechst 33258 and acridine orange. When these dyes are used in combination, dead cells fluoresce brilliant blue and live cells fluoresce green. This method works over a range of dye concentrations (Hoechst 33258, 0.25-2 μg/ml; acridine orange, 1-5.0 μg/ml) and the fluorescence spectra of the two dyes are such that only one set of filters is required to visualize the effects of both dyes simultaneously. It is insensitive to a wide range of exogenous serum concentrations and is read with greater uniformity by different observers.     

Permeability of boar and bull spermatozoa to the nucleic acid stains propidium iodide or Hoechst 33258, or to eosin: accuracy in the assessment of cell viability

This study was designed to assess whether nucleic acid stains such as propidium iodide and Hoechst 33258 and the cytosolic stain eosin identified equivalent proportions of non-viable cells. Sub-samples of boar spermatozoa stored for up to 72 h, and frozen bull spermatozoa stored in straws and thawed before staining, were exposed to either propidium iodide or Hoechst 33258 alone or in combination. Additional sub-samples were stained with eosin-nigrosin and subsequently with Giemsa. The proportion of non-viable cells identified by propidium iodide alone was equivalent to that observed when it was used in combination with the other fluorescent probe. Similar results were observed for Hoechst 33258. However, direct microscopic examination of sub-samples exposed to both stains revealed that a proportion of spermatozoa stained with propidium iodide did not incorporate Hoechst 33258. This was found consistently in boar and bull spermatozoa under the different experimental conditions used. Quantification showed that the proportion of propidium iodide-positive cells was significantly higher than Hoechst 33258-positive cells. Furthermore, the proportion of propidium iodide-positive cells was higher than cells stained with eosin, but no differences were found between the number of cells stained with Hoechst 33258 or eosin. The proportion of cells stained with propidium iodide was positively correlated with the proportion stained with either Hoechst 33258 or eosin, despite the observation that more cells incorporated propidium iodide. Taken together, these results indicate that there are differences in the ability of fluorescent probes to identify non-viable sperm cells and that this should be considered when staining protocols are used to analyse sperm viability, or when viability is used as a discriminating factor in functional studies, such as those related to acrosomal exocytosis.     

Determination of cell concentration in a plant cell suspension using a fluorescence microplate reader

Microscopic counting of plant cells is a very tedious and time-consuming process and is therefore seldom used to evaluate plant cell number on a routine basis. This study describes a fast and simple method to evaluate cell concentration in a plant cell suspension using a fluorescence microplate reader. Eschscholtzia californica cells were fixed in a mix of methanol and acetic acid (3:1) and stained with a fluorescent DNA binding dye (Hoechst 33258). Readings were done in a fluorescence microplate reader at 360/465 nm. Specific binding of the dye to double-stranded DNA was significantly favored over unspecific binding when 1.0 M Tris buffer at pH 7.5 containing 1.0 M NaCl and 75 microg ml(-1) of Hoechst 33258 was used. Fluorescence readings must be done between 4 min and 12 min following the addition of the staining solution to the sample. The microplate counting method provides a convenient, rapid and sensitive procedure for determining the cell concentration in plant cell suspensions. The assay has a linear detection range from 0.2 x 10(6) cells to 10.0 x 10(6) cells per milliliter (actual concentration in the tested cell suspension). The time needed to perform the microplate counting was 10% of that needed for the microscopic enumeration. However, this microplate counting method can only be used on genetically stable cell lines and on asynchronous cell suspensions.     

A bromodeoxyuridine (BUdR)-mithramycin technique for detecting cycling and non-cycling cells by flow microfluorometry

Bromodeoxyuridine (BUdR) incorporation into cellular DNA results in an increase in fluorescence of mithramycin-stained cells. Flow microfluorometry can be used to distinguish among cells which have not replicated, cells which have replicated once, and cells which have replicated two or more times in the presence of 30 μM BUdR. This technique offers two advantages over present protocols: (1) a positive fluorescent signal is provided by the mithramycin stain rather than a negative signal, as with the Hoechst stain; (2) after mithramycin staining, hundreds of thousands of cells in any phase of the cell cycle can be analyzed in less than 10 min. The BUdR-mithramycin technique described herein is a useful tool for studying the cell-cycle kinetics of heterogeneous populations containing dividing and non-dividing cells.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-UV irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.     

A comparison of the effect of 5-bromodeoxyuridine substitution on 33258 Hoechst- and DAPI-fluorescence of isolated chromosomes by bivariate flow karyotyping

Summary Application of the fluorescent DNA-intercalator propidium iodide for stabilization of the mitotic chromosome structure during isolation of chromosomes from V79 Chinese hamster cells and subsequent staining with the fluorochromes 33258 Hoechst or DAPI allowed bivariate flow karyotyping of isolated chromosomes. Fluorescence of 33258 Hoechst bound to isolated chromosomes containing 5-bromodeoxyuridine (BrdUrd) was quenched in comparison with the fluorescence of control chromosomes. Despite structural relationship and similarity of both absorption and fluorescence spectra of DAPI and 33258 Hoechst, reduction of fluorescence of DAPI-stained isolated chromosomes was not observed, by contrast with findings in conventional cytological metaphase preparations. It could be obtained, however, by preirradiation of the chromosomes with near-UV in the presence of DAPI. This led to a progressive destruction of the chromosomes. Destruction also occurred without BrdUrd, though at a slower rate. Preirradiation of chromosomes in the presence of 33258 Hoechst hardly affected the integrity of the chromosomes. Preirradiation of a 33258 Hoechst solution and its subsequent use as a stain resulted in a considerably decreased fluorescence of chromosomes. For DAPI this effect was small. Thus, whereas 33258 Hoechst itself is much more sensitive to near-U.V irradiation than DAPI, DAPI bound to DNA in chromosomes renders the DNA much more sensitive to irradiation than 33258 Hoechst bound to DNA. Presumably, these differences can at least partly be reduced to the different molecular sizes of the dyes.In honour of Prof. P. van Duijn     

Improved method for the routine analysis of acetylcholine release in vivo: quantitation in the presence and absence of esterase inhibitor

An improved high-performance liquid chromatographic (HPLC) method using electrochemical detection (ED) is described capable of routinely measuring the low levels of acetylcholine (ACh) typically found in rat brain microdialysis samples. Microdialysis was performed in the striatum of the urethane anesthetized rat using a 4-mm membrane length, high recovery (40% at 1.0 μl/min; ambient conditions), loop-design probe perfused with an artificial cerebrospinal fluid (aCSF) solution containing physiologically normal calcium levels (1.2 mM). The HPLC method utilizes a polymeric stationary phase to resolve choline (Ch) from ACh. These analytes are then converted to hydrogen peroxide (H₂O₂) by a solid-phase reactor (containing immobilized choline oxidase and acetylcholinesterase enzymes). The H₂O₂ is detected amperometrically and quantitated on a platinum (Pt) working electrode (+300 mV; with a unique analytical cell featuring a solid-state palladium reference electrode). Two designs of the Pt working electrode were examined, differing only in the support material used (Kel-F or PEEK). The Kel-F/Pt electrode had a limit of detection (LOD) for both analytes of <30 fmol per 10 μl with a signal-to-noise ratio of 3:1. Striatal microdialysis perfusates were monitored for ACh and Ch over a 0–1000 nM range of neostigmine (NEO) in the CSF perfusion medium. Using the 4-mm probe, basal ACh and Ch levels were detected with a NEO level as low as 10 nM and were found to be 37 ± 3 fmol and 22 ± 1 pmol per 10 μl (mean ± S.E.M., n = 6 replicates) respectively. In similar experiments using 3-mm concentric probes comparable (lower) levels of ACh were found with the 50 and 1000 nM NEO doses (n = 4–21 animals). ACh could not be reliably quantitated when animals were perfused with the 10 nM dose of NEO (n = 4). The PEEK/Pt electrode had an improved LOD of < 20 fmol per 10 μl due to a two- to three-fold decrease in the background noise component. Basal striatal levels of ACh in the absence of NEO approached the LOD and were found to be 15 ± 2 fmol per 10 μl; Ch was 5 ± 1 pmol per 10 μl (n = 2, mean of five basal samples). The analytical system requires very little maintenance; a simple electrochemical electrode cleaning step eliminates the need for routine polishing of the Pt electrode and the mobile phase is stable for up to one week. Both ACh and Ch are resolved in under 7 min making this method highly suitable for analysis of microdialysis samples.     

In situ detection of mycoplasma contamination in cell cultures by fluorescent Hoechst 33258 stain

A simple, fast, and easily reproducible routine laboratory technique for detecting mycoplasma contamination in cell cultures is reported. Cells grown on a coverslip are fixed directly with Carnoy's, air-dried, stained with DNA-specific fluorescent Hoechst 33258, and examined microscopically. All cultures that were infected with mycoplasmas had readily discernible, small, morphologically uniform, bright fluorescent bodies in the extranuclear and intercellular space in contrast to the non-contaminated control cultures in which the extra-nuclear background appeared uniformly dark. To probe the degree of sensitivity to detect mycoplasmas, control cultures were infected with aliquots from serially diluted cells or media collected from Mycoplasma hyorhinus infected cultures. The lowest infection rate (0.40% by sampling 1 000 cells in average per culture 4–24 h after infection) scored presently, however, can easily be lowered by increasing sample size since a cell infected with even one mycoplasma can be discerned. These mycoplasmas resisted centrifugation at 2 500 rpm for 30 min and easily filtered through 0.22 μm pore-size filter membrane. Amazingly infection rate of 0.63% scored from 24 h post-infection incubation attained 100% contamination with several hundreds of mycoplasmas per host cell within 120 h.     

Binding of Hoechst 33258 to chromatin in situ

The binding of Hoechst 33258 to rat thymocytes, human lymphocytes, and NHIK 3025 tissue culture cells was studied by measuring the fluorescence and light scattering of the cells as functions of dye concentration using flow cytometry. The results indicated that there were two different modes of binding of Hoechst 33258 to chromatin in situ at physiological pH. Type 1 binding, which dominated at total dye/phosphate ratios below 0.1 (0.15, M), was characterized by a binding constant of the order 10(7) M-1 and fluorescence with high quantum yield. Further binding of the dye resulted in a reduced blue/green fluorescence ratio, indicating that secondary sites were occupied. Binding at secondary sites above a certain density (0.1 less than or equal to bound dye/phosphate less than or equal to 0.2) induced strong quenching of fluorescence and precipitation of chromatin. Precipitation was quantitated by measuring the large-angle (greater than or equal to 15 degrees) light scattering of the cells above 400 nm, i.e., outside the Hoechst 33258/DNA absorption spectrum, as a function of dye concentration. In contrast, the light scattering at 365 nm, i.e., within the absorption spectrum of Hoechst 33258/DNA, was independent of the total dye/phosphate ratio. The coefficient of variation of the light-scattering (greater than or equal to 400 nm) histograms decreased with Hoechst 33258 concentration. Type 2 binding to histone-depleted chromatin was cooperative (Hill-coefficient approximately 2) and the apparent binding constant was 2-3 X 10(5) M-1 as determined from quenching and precipitation data.(ABSTRACT TRUNCATED AT 250 WORDS)     

Identification in Histological Sections of Species Origin of Cells from Mouse, Rat and Human

A simple method for identifying the species of origin of mammalian cells in tissue sections using Hoechst dye #33258 is described. This rapid procedure involves staining fresh frozen or formalin fixed paraffin sections with 4 µg/ml of Hoechst #33258 for one minute at room temperature; following one to five minutes of washing in running tap water, the slides are coverslipped using McIlvaine's buffer (pH 5.5) and sealed with clear lacquer. Sections examined by fluorescence microscopy indicate that mouse cells contain several small discrete intranuclear fluorescent bodies, which are absent in cells from either rat or human. This simple technique should be useful in studying developmental phenomena in chimeric organs.     

Detection and analysis by dual-laser flow cytometry of bacteriophage T4 DNA inside Escherichia coli.

Bacteriophage T4 DNA was detected and analyzed inside E. coli by dual-laser flow cytometry using a dye combination of Hoechst 33258 (H33258) and chromomycin A3 (CA3) which bind to A-T- and G-C-rich regions of DNA, respectively. An exponentially-growing culture of E. coli ATCC 11303 was infected with T4 bacteriophage at a 1:1 multiplicity of infection. Samples were taken immediately and at 5 min intervals and placed on ice to interrupt viral replication. The samples were then centrifuged, ethanol-fixed, stained with H33258 and CA3, and analyzed by flow cytometry. Twenty-five minutes post-infection, a population of cells which contained T4 DNA began to appear on both a bivariate contour plot and a frequency histogram plot of the data. By 35 min, T4 DNA-containing cells could be distinguished from E. coli cells containing little or no T4 DNA. The ratio of CA3:H33258 fluorescence was then used to calculate the % G + C value for T4 DNA inside E. coli. A value of 35.6 +/- 0.2% was obtained, which agrees with % G + C values determined by traditional methods. These results demonstrate that dual-laser flow cytometry can be used to study viral DNA inside the bacterial host.     

Chromosome Preparatons of Bone Marrow Cells without Prior In Vitro Culture or In Vivo Colchicine Administration

Bone marrow (about 0.5 ml) from au erythropoietic region is freed of blood clots by washing 1-3 min in 1 μg/ml colchicine solution (2-3 ml) and then soaking 1-2 hr at 20-30° C in a second change. For mammalian or avian marrows, the colchicine is made up in phosphate-buffered (pH 7) physiological NaCl solution; for amphibian, Ringer's A solution. Next the specimens are soaked about 20 min in a hypotonic solution as follows: for mammalian, 1% Na-citrate; for avian, a 1:4 dilution of the buffered NaCl solution by distilled water; and for amphibian, Ringer's A-distilled water, 1:1. Then they are heated in a mixture of 2% orcein in 45% acetic acid and 1 N HCl, 9:1. Immediately after heating, squash preparations are made with 2% acetic-orcein in the usual manner. An alternative method is to dissociate the marrow cells by agitating after colchicine treatment. Then, recovering the cells between changes by low-speed centrifugation, to carry out the hypotonic treatment and subsequent fixation in Carnoy's solution I (alcohol acetic, 3:1) before drying the cells onto slides from the fixative. After thorough drying the slides may be stained 10-20 min in acetic orcein, or by other suitable technics.     

Flow cytometric analysis of bromodeoxyuridine-substituted cells stained with 33258 Hoechst.

This paper describes a flow-cytometric application of the quenching of fluorescence from 33258 Hoechst stained Chinese hamster ovary-line cells due to the incorporation of 5-bromo-deoxyuridine (BrdU) into the cellular deoxyribonucleic acid. Cells were grown for 24 hr in medium containing BrdU in concentrations ranging from 1 x 10(-8) to 1 x 10(-4) M. For each concentration we measured the average fluorescence as determined by flow cytometry, the extent of BrdU substitution and the effect of the BrdU on cell growth. We determined that a BrdU concentration of 1 x 10(-5) M resulted in sufficient substitution to quench the fluorescence from 33258 Hoechst by a factor of 4, allowing discrimination between cycling and noncycling cells. The extent of BrdU substitution after growth for 24 hr in this concentration of BrdU was 64%. These data indicate the feasibility of detecting deoxyribonucleic acid synthesis in whole cells using the 33258 Hoechst-BrdU methodology.     

A staining procedure for identifying viable cell hybrids constructed by somatic cell fusion, cybridization, or nuclear transplantation

A general procedure for identifying viable hybrid cells was developed. One cell type was labeled by a brief incubation in the Kodak laser dye rhodamine 123, which accumulates in the mitochondria; a second cell type was labeled by a brief incubation in the Hoechst fluorochrome 33258, which binds to chromatin. The substances which are eventually lost from the organelles, appeared to be nontoxic; the plating efficiencies of numerous cell lines tested was unaffected. Either whole cells or cytoplasts labeled with rhodomine 123 were fused, using inactivated Sendai virus, to whole cells or karyoplasts labeled with Hoechst 33258. When living cells were illuminated with ultraviolet light, individual whole cell hybrids, cybrids or cytoplasmic- nuclear hybrid cells could be rapidly identified by the appropriate staining pattern.     

Quenching of Hoechst 33258 fluorescence in erythroid precursors.

Quenching of the fluorescence of DNA-bound Hoechst 33258 in erythroid precursors was studied by flow cytometry and cytochemistry. This quenching artifact may affect the measurement of ploidy in specific cases. The bone marrow cells of two patients with hemolytic disease and active erythropoiesis contained subpopulations of cells with an apparent hypodiploid DNA content as measured by flow cytometry of paraformaldehyde-fixed cells stained with Hoechst 33258. No aneuploidy was detected in either of the two cases when cells were stained with mithramycin or 7-aminoactinomycin D. Cells exhibiting reduced Hoechst 33258 fluorescence expressed glycophorin A and low amounts of CD36, and were therefore erythroid precursors. In one case studied, the number of cells with reduced Hoechst 33258 fluorescence and glycophorin A expressed agreed well with the number of cells containing nuclear hemoglobin. In the other case, hemoglobin was present in a significant proportion of nucleated cells. Calculated values for the efficiency of resonance energy transfer from Hoechst 33258 to hemoglobin were in accordance with the observed levels of quenching (approximately 10%). However, the results could also be explained by hemoglobin reabsorption of Hoechst 33258 fluorescence. Nuclei stained with Hoechst 33258 showed uniform fluorescence, probably due to extraction of hemoglobin during the isolation procedure.     

Base-sequence specificity of Hoechst 33258 and DAPI binding to five (A/T)4 DNA sites with kinetic evidence for more than one high-affinity Hoechst 33258-AATT complex

The binding of Hoechst 33258 and DAPI to five different (A/T)4 sequences in a stable DNA hairpin was studied exploiting the substantial increase in dye fluorescence upon binding. The two dyes have comparable affinities for the AATT site (e.g. association constant K(a)=5.5 x 10(8) M(-1) for DAPI), and their affinities decrease in the series AATT > TAAT approximately equal to ATAT > TATA approximately equal to TTAA. The extreme values of K(a) differ by a factor of 200 for Hoechst 33258 but only 30 for DAPI. The binding kinetics of Hoechst 33258 were measured by stopped-flow under pseudo-first order conditions with an (A/T)4 site in excess. The lower-resolution experiments can be well represented by single exponential processes, corresponding to a single-step binding mechanism. The calculated association-rate parameters for the five (A/T)4 sites are similar (2.46 x 10(8) M(-1) s(-1) to 0.86 x 10(8) M(-1) s(-1)) and nearly diffusion-controlled, while the dissociation-rate parameters vary from 0.42 s(-1) to 96 s(-1). Thus the association constants are kinetically controlled and are close to their equilibrium-determined values. However, when obtained with increased signal-to-noise ratio, the kinetic traces for Hoechst 33258 binding at the AATT site reveal two components. The concentration dependencies of the two time constants and amplitudes are consistent with two different kinetically equivalent two-step models. In the first model, fast bimolecular binding is followed by an isomerization of the initial complex. In the second model, two single-step associations form two complexes that mutually exclude each other. For both models the four reaction-rate parameters are calculated. Finally, specific dissociation kinetics, using poly[d(A-5BrU)], show that the kinetics are even more complex than either two-step model. We correlate our results with the different binding orientations and locations of Hoechst 33258 in the DNA minor groove found in several structural studies in the literature.     

Determination of guanine-plus-cytosine content of bacterial DNA by dual-laser flow cytometry

A dual-laser flow cytometer was used to analyse different species of bacteria for the molar percentage of guanine-plus-cytosine (% G + C) without the need for DNA extraction or purification. Ethanol-fixed bacterial cells were stained with a combination of DNA-specific fluorochromes, Hoechst 33258 and chromomycin A3, which bind to AT- and GC-rich regions of DNA, respectively. A linear relationship (r = 0.99) was demonstrated between the log of the ratio of chromomycin A3 to Hoechst 33258 fluorescence and the log of the % G + C as determined by thermal denaturation (Tm) or buoyant density centrifugation (Bd) methods. Linearity was maintained for all bacterial species tested over the range of 28-67% G + C. A standard curve was constructed using five strains whose % G + C had been determined by other methods. From the equation describing this line, the % G + C values of nine other strains with known DNA base composition, together with the five strains used to construct the curve, were calculated using the chromomycin A3 to Hoechst 33258 ratio and were in agreement with values obtained by Tm, Bd or HPLC. The reproducibility of flow cytometric analysis (mean error 0.7% G + C) compared well with the reproducibility of other methods. Mixtures containing two species were also analysed. Two cell populations could be discerned in mixtures containing two species which differed in base composition by as little as 4% G + C.(ABSTRACT TRUNCATED AT 250 WORDS)     

A novel technique for viable cell determinations

We have developed a simple method to determine cell viability using two fluorescent dyes, Hoechst 33258 and acridine orange. When these dyes are used in combination, dead cells fluoresce brilliant blue and live cells fluoresce green. This method works over a range of dye concentrations (Hoechst 33258, 0.25-2 micrograms/ml; acridine orange, 1-5.0 micrograms/ml) and the fluorescence spectra of the two dyes are such that only one set of filters is required to visualize the effects of both dyes simultaneously. It is insensitive to a wide range of exogenous serum concentrations and is read with greater uniformity by different observers.     

Simple and sensitive method for determination of metronidazole in human serum by high-performance liquid chromatography

A simple and sensitive HPLC method for determination of metronidazole in human plasma has been developed. A step of freezing the protein precipitate allowed an efficient separation of aqueous and organic phases minimizing the noise level and improved therefore the limit of quantitation (10 ng ml⁻¹ using 1 ml of plasma sample). The separation of compounds was performed on a RP 18 column with acetonitrile–aqueous 0.01 M phosphate solution (15:85, v/v) as mobile phase. Detection was performed by UV absorbance at 318 nm. Metronidazole was well resolved from the plasma constituents and internal standard. An excellent linearity was observed between peak-height ratios plasma concentrations over a concentration range of 0.01 to 10 μg ml⁻¹. Within-day and between-day precision (expressed by relative standard deviation) and accuracy (mean error in per cent) did not exceed 4% between 1 and 10 μg ml⁻¹ and 8.3 and 7.2% respectively for the limit of quantitation. The method is suitable for bioavailability and pharmacokinetic studies in humans.