Analytical microscopy observations of rat enterocytes after oral administration of soluble salts of lanthanides, actinides and elements of group III-A of the periodic chart.

The behavior in the intestinal barrier of nine elements (three of the group III-A, four lanthanides and two actinides), absorbed as soluble salts, has been studied by two microanalytical methods: electron probe X-ray micro analysis (EPMA) and secondary ion mass spectrometry (SIMS). It has been shown that the three elements of group III-A, aluminium, gallium and indium; and the four lanthanides, lanthanum, cerium, europium and thulium, are selectively concentrated and precipitated as non-soluble form in enterocytes of proximal part of the intestinal tract. SIMS microscopy has shown that these elements are concentrated as a number of submicroscopic precipitates, most of them localized in the apical part of the duodenum enterocytes, where they are observed from one hour to 48 hr after a single intragastric administration. No precipitate is observed after three days. It is suggested that this mechanism of local concentration limits the diffusion of these elements through the digestive barrier, some of them being toxic and none of them having a recognized physiological role. Additionally, the precipitation in duodenal enterocytes, the life time of which is on the order of 2-3 days, allows the elements absorbed as soluble form to be eliminated as a non-soluble form in the digestive lumen along with the desquamation of the apoptotic enterocytes. The intracytoplasmic localization of the precipitates are supposed to be the lysosomes although no direct evidence could be given here due to the very small sizes of the lysosomes of enterocytes. The same results were not observed with the two studied actinides. After administration of thorium, only some very sparse microprecipitates could be observed in intestinal mucosa and, after administration of uranium, no precipitates were observed with the exception of some in the conjunctive part of the duodenal villi.

Distribution of I-BZA (N-2-diethylaminoethyl-4-iodobenzamide) in grafted melanoma and normal skin: a study by secondary ion mass spectroscopy.

Iodobenzamides labelled with radioactive iodine are undergoing clinical evaluation as imaging and potential therapeutic agents in malignant melanomas. However, the uptake mechanism in melanic tissues remains controversial. Using secondary ion mass spectrometry (SIMS), we studied the microscopic distribution of N-(2 diethylaminoethyl)-4 iodobenzamide (I-BZA) in B16 murine melanoma inoculated to C57BL/6J1 Co mice as well as in normal pigmented skin. SIMS provides specific detection of iodine-127 atoms entering 127I-BZA composition. In B16 melanoma, 127I-BZA distribution was found to be heterogeneous, with focal areas of high concentration corresponding to cells rich in melanin pigments. In skin, SIMS analysis showed 127I-BZA distribution appearing as multiple small selective concentration areas within the epidermis. The number of these foci decreased from the stratum basale towards the stratum corneum. In both tissues, the intracellular location appeared specifically intracytoplasmic, with no apparent nuclear uptake. Distribution of this molecule mirrored that of melanin pigments. There was no enhancement of uptake at the membrane site. These results suggest that, in melanic tumors as well as in normal pigmented tissue, specific uptake of 127I-BZA occurs in pigment cells, with a possible link to melanin pigments.

Use of SIMS microscopy and electron probe X-ray microanalysis to study the subcellular localization of aluminium in Vicia faba roots cells.

Received January 4, 1999; Accepted March 25, 1999 Secondary ion mass spectrometry (SIMS), electron probe X-ray microanalysis (EPMA) and transmission electron microscopy (TEM) were used to study the tissular distribution and subcellular localization of aluminium (Al) precipitate in roots of Viciafaba. The broad bean plant, grown in nitrate solution with 193 microM Al3+ at pH 4.8, for 15 days showed Al deposits in the roots. Al accumulation was not detected in the stems nor in the leaves. Al was found mainly localized on the root's surfaces and within the cell walls of the cortical cells. Al signal was not detected in the vascular tissues. Two weeks exposure to Al caused ultrastructural changes in cortical cells and sometimes a complete disruption of these cells. Deposition of Al in form of insoluble complexes associated with phosphorus, appeared as electron opaque materials in the vacuoles of disrupted cortex cells and in the intercellular inclusions. The leaves turned yellowish at the end of 15 days exposure. The use of electron microprobe, to investigate the same tissues as the ones investigated by SIMS, provided complementary results on aluminium allocation.

Mechanism involved in gallium-67 (Ga-67) uptake by human lymphoid cell lines.

The gallium-67 (Ga-67) is a radionuclide used for diagnostic imaging. It is known for its ability to accumulate in inflammatory lesions and tumors, especially in lymphomas. The intracellular distribution and the uptake mechanism of Ga-67 remains a subject of discussion. In this work, we studied the mechanism of Ga-67 uptake in 4 human lymphoid cell lines: 38658, Jurkat, DG75 and U715. Our results have pointed out the heterogeneity of Ga-67 uptake among these cell lines. Using flow cytometry analysis, we reported the expression of transferrin-receptor (TfR) in each lymphoid cell line, and found a positive correlation between TfR density and the Ga-67 uptake (r = 0.99) in lymphoid cells. The anti-TfR monoclonal antibody (MoAb) blocked significantly the Ga-67 uptake in all lymphoid cell lines indicating the Ga-67 uptake as a TfR-dependent mechanism. This mechanism has been saturated with different cold gallium concentrations. A total inhibition of Ga-67 uptake was obtained at a 10(-4) M cold gallium concentration. To conclude, we have shown that the Ga-67 uptake is TfR-dependent in lymphoid cells. Thus, the gallium penetrates in lymphoid cells by an active mechanism which can be saturated.

Mapping the subcellular distribution of biomolecules at the ultrastructural level by ion microscopy.

Analytical ion microscopy, a method proposed and developed in 1960 by Casting and Slodzian at the Orsay University (France), makes it possible to obtain easily and rapidly analytical images representing the distribution in a tissue section of elements or isotopes (beginning from the three isotopes of hydrogen until to transuranic elements), even when these elements or isotopes are at a trace concentration of 1 ppm or less. This method has been applied to study the subcellular distribution of different varieties of biomolecules. The subcellular location of these molecules can be easily determined when the molecules contain in their structures a specific atom such as fluorine, iodine, bromine or platinum, what is the case of many pharmaceutical drugs. In this situation, the distribution of these specific atoms can be considered as representative of the distribution of the corresponding molecule. In other cases, the molecules must be labelled with an isotope which may be either radioactive or stable. Recent developments in ion microscopy allow the obtention of their chemical images at ultra structural level. In this paper we present the results obtained with the prototype of a new Scanning Ion Microscope used for the study of the intracellular distribution of different varieties of molecules: glucocorticoids, estrogens, pharmaceutical drugs and pyrimidine analogues.

Subcellular distribution of a new fluorinated, biocompatible, non-ionic telomeric carrier: a study in cultured B16 melanoma and rat skin fibroblasts.

Tris-hydroxymethyl-amino-methane telomers bearing a fluorinated end have recently been proposed as potential drug carriers. Using ion microscopy, we have investigated the cell uptake and subcellular distribution of a perfluorinated telomere, called F-TAC, in two cell lines, malignant murine B16 melanoma and normal rat skin fibroblasts. Single layer cell cultures on gold plates were incubated with F-TAC at different concentrations. Ion microscopy using mass spectrometry enabled the detection of Fluorine 19 atoms entering into F-TAC constitution. This microanalytical study showed an elective cytoplasmic localization of the molecule, wherein the distribution is relatively homogeneous. Within same culture and incubation conditions, intercellular variations in F-TAC content were very low. In the malignant line, the intracellular concentration remains practically identical when increasing F-TAC concentration in the culture medium above 0.2 mg/ml, indicating that the uptake phenomenon is saturable. In conclusion, the F-TAC telomer easily crosses the plasma membrane, however, it has difficulties in crossing the nuclear membrane. It is likely that intracellular penetration is essentially due to rapid endocytosis of the telomer.

Localization of N-(2-diethylaminoethyl)4-iodobenzamide in the pigmented mouse eye: a microanalytical study.

The 123I-N-(2-diethylaminoethyl)4-iodobenzamide (123I-BZA) is a new radiopharmaceutical used for the scintigraphic imaging of malignant melanomas. The mechanism for BZA uptake in melanic tissues is still unknown. Two methods of microanalysis, secondary ion mass spectrometry and electron probe X-ray microanalysis, were used to determine tissue distribution and subcellular location of unlabelled BZA in the C57BL6/J1 co mouse eye. Microanalysis showed elective BZA uptake by the pigmented structures of the eye: choroidal melanocytes and retinal pigment cells, where it was specifically located within melanosomes. The tropism of BZA for melanic tumours, as well as for normal pigmented tissues, could be explained by a high affinity for the melanin pigment.

Subcellular localization of gadolinium injected as soluble salt in rats: a microanalytical study.

The rare earth gadolinium (Gd) is used in modern industry. Solubilized DTPA Gd and DOTA Gd complexes are used as contrast media in nuclear magnetic resonance imaging. In order to determine the subcellular localization of Gd, rats were injected intraperitoneally with Gd nitrate. Two microanalytic methods, ion microanalysis and electron microprobe, enabled the distribution and the intracellular localization of Gd to be determined in the liver, spleen, bone marrow, kidneys and lung. The results showed: a) a punctual distribution of Gd in the tissues (liver, spleen, bone marrow and lung) as observed by ion microscopy; b) a selective concentration of Gd in the lysosomes of macrophages of the liver (hepatocytes), spleen (macrophages), bone marrow (macrophages) and lung (phagocyte cells), as determined by electron probe X-ray microanalysis. In all these sites the Gd is associated to phosphorus. Results are compared to those found for other rare earths and metal elements.

Advantages of the scanning ion microscopy for mapping halogen corticoids in normal and transformed cells in culture.

The intra-cellular distribution of eight halogen glucocorticoids was investigated by ion microscopy in two cellular varieties of cultured non-cancer cells (fibroblast 3T3) and cancer cells (human breast tumor cells MCF-7). Two types of ion microscopy helped to determine this distribution, a direct imaging ion microscope (SMI 300) with low spatial resolution, and a scanning ion microscope (IMS4F), featuring high resolution, serving to obtain maps representing the intra-cellular distribution of the fluorine elements and drugs present in these monolayer cultured cells. The fluorine images representative of the drugs containing fluorine showed that these drugs are essentially concentrated in the cell nuclei. In these nuclei, the distribution of these drugs is different from that of heterochromatin and of the nucleolus.

Preservation of the diffusible cations for secondary ion mass spectrometry. II. Artefacts in material embedded in araldite or melamine.

Flotation on hot water (about 60 degrees C) which is frequently employed to stretch semithin sections on substrates for SIMS (secondary ion mass spectrometry) microscopy, is the cause of numerous artefacts. In the case of epoxy resin-embedded tissue, one observes loss of potassium and sodium and accumulation of calcium. The relative contrast of cell nuclei in the ionic images, is rapidly affected by these ion migrations. After prolonged contact with hot water, tissue becomes uniformly emissive. In the case of hydrosoluble resin-embedded tissue, potassium and sodium do not appear to be affected by the action of water, which suggests that they are covalently bound with chelating sites buried beneath the layer of water bound to the surface of the macromolecules. Calcium accumulates, probably on widely exposed anionic sites. Moreover, the domains observed in hydrosoluble resin-embedded tissue shrink differently according to the proportion of water removed by melamine; this can provide interesting information on the initial equilibrium between water, ion sand macromolecules. Our results seem to support the assumption that bound water should play an important role in the preservation of both macromolecular architecture and ion distributions.

Mapping of intracellular halogenous molecules by low and high resolution SIMS microscopy.

The subcellular distribution of halogenous molecules has been studied by SIMS microscopy in cultured cells of a human breast carcinoma (MCF-7 cell line). Two instruments of microanalysis were used. A low lateral resolution ion microscope (SMI 300 CAMECA) and a prototype scanning ion microscope equipped with a cesium gun that gives high lateral resolution images. This apparatus has been developed by G Slodzian, in Onera Laboratories (Office National d'Etudes et de Recherches Aérospatiales). Molecules studied by low lateral resolution ion microscope were halogenous steroids: fluorometholone, triamcinolone, bromocriptine and bromoandrosterone. Analytical images show that the first two compounds are mainly localized in the nuclear structure of MCF-7 cells whereas the last two molecules are localized in cytoplasm of these cells. Images were obtained with a resolution of 1 micron. With the scanning ion microscope, it is now possible to obtain images at the ultrastructural level. Four analytical images can be simultaneously obtained by a single scan of the imaged area, corresponding to a depth of erosion of the section of ten nm. The intranuclear distributions of three pyrimidine analogs, 5-bromo-2'-deoxyuridine, 5-iodo-2'-deoxyuridine and 5-fluorouracil have been studied in phase S and M of MCF-7 cells and these images have been compared to the distribution of sulfur, nitrogen and phosphorus. All these images have been obtained with a lateral resolution better than 100 nm.

Subcellular localization of two neurotropic drugs in three varieties of central nervous system cells by secondary ion mass spectroscopy (SIMS) microscopy.

The intracellular localization of two neurotropic drugs, flunitrazepam (benzodiazepine) and triflupromazine (phenothiazine), was studied by secondary ion mass spectrometry microscopy (SIMS) in three varieties of cells. The images of the intracellular distributions of the two drugs are easily obtained by selecting the fluorine atom of the molecules. These images show that the drug from the benzodiazepine group is mainly located in the nuclei, whereas the phenothiazine is exclusively located inside the cytoplasm.

[Localization of two neurotropic molecules in cultured glial cells by ion microscopy]. / Localisation de deux molécules neurotropes dans les cellules gliales en culture par microscopie ionique.

The intracellular localization of two families of neurotropic drugs: flunitrazepam and flurazepam (benzodiazepine), triflupromazine and trifluoperazine (phenothiazine) has been studied by ion microscopy. The molecules have been incubated with C6 glioblastoma cells from rat origin and with astroglial primary cultures. The images of the intracellular distributions of the two drugs are easily obtained by selecting the fluorine atom of the molecules. The images obtained show that flunitrazepam and flurazepam, two drugs of the benzodiazepine group are mainly located to the nuclei, whereas triflupromazine and trifluoperazine, two phenothiazines are exclusively located inside the cytoplasm.

Intracellular localization of drugs in cultured tumor cells by ion microscopy and image processing.

Several drugs, containing a halogen atom, F or Br, that are being used in antiviral or anticancer therapy, were studied for their localization in cultured cells by ion microanalysis. The association allows to reduce the exposure time to define the intracellular localization of the studied element. The topography of the cells is given by the image of the polyatomic ion 26CN-. The image of the distribution of 81Br- or 19F-, coded in another color scale, can be superimposed, giving a polychromic image of the cell, thus showing the intracellular localization of the compound. MCF-7 tumor cells were cultured in the presence of pyrimidine derivatives. 5-Bromo-2'-deoxyuridine (BUdR) and 5-trifluorothymidine (F3TdR) were localized in the nucleus, 5-fluoro-2'-deoxyuridine (FUdR) in the nucleus and only in some nucleoli. The method is simple and rapid, as compared with techniques using radiolabeled compounds, or with immunocytochemical techniques. It is possible to observe two different compounds in the same cell. It could be applied to other compounds containing a halogen atom.

[The detection of viral antigens and ribosomal RNA in cells by using low-temperature media]. / Vyiavlenie virusnykh antigenov i ribosomal'noi RNK v kletkakh s ispol'zovaniem nizkotemperaturnykh sred.

A post-embedding technique for immunocytochemical analysis at the ultrastructural level was used to detect and localize HIV antigens on ultrathin sections of Lowicryl-embedded HIV-infected cells. A genomic probe containing ribosomal sequences and labeled with biotin was used to hybridize rRNA molecules in sections of animal cells embedded in Lowicryl. The method presently described offers the possibility to detect rapidly and precisely ribosomal gene expression and viral proteins at the ultrastructural level.

Intracellular localization of cerium. A microanalytical study using an electron microprobe and ionic microanalysis.

Radioactive cerium is a nuclear toxicant. Metallic cerium is used in industry. Aspects of the intracellular metabolism of this element were studied following intraperitoneal injection and aerosol exposure in rat. Two microanalytic methods, an electron microprobe and ionic microanalysis, enabled the sites of incorporation and the process of intracellular concentration of cerium to be determined in the liver, lung, kidney, bone marrow and bone tissue. The very high sensitivity of ionic analysis enabled very low concentrations of cerium to be detected with a spatial resolution of 0.5 microns. Microanalysis by electron microprobe permitted: (i) the lysosomal localization of cerium to be determined; and (ii) the lysosomal coprecipitation of cerium with phosphorus to be demonstrated. Results are discussed in relation to aspects of radiological protection.

Detection by immunogold techniques of HIV antigens in Lowicryl ultrathin sections of infected cells.

A post-embedding technique for immunocytochemical analysis at the ultrastructural level was used to detect and localize HIV antigens on ultrathin sections of Lowicryl K4M-embedded HIV-infected cells. With serum from an AIDS patient, specific immunogold labelling was obtained exclusively on mature viral extracellular structures. The more intense reactivity was obtained with core antigens. The present immunoelectron microscopy method provides several advantages - high sensitivity of immunodetection, good preservation of cellular morphology, easy preparation procedure - which could lead to the use of this method for HIV-infected human tissues.

Processing of secondary ion microscope images: an example of application to the thyroid.

Ion microscopy is a microanalytical method by which one can obtain distribution images of any chemical element with isotope discrimination even at very low local concentrations, in successive slices of the specimen. These images are obtained at the price of progressive erosion of the specimen, so that the analysis may not be replayed and it is necessary to record the maximum amount of information during specimen erosion. We present an improvement of this method using a highly sensitive camera connected to a video analog-digital converter. The images are acquired and digitized on line and may be processed by an image computer. We illustrate the technique described with an application of ion microscopy that is made possible by digital recording and processing of images. This application concerns the precise comparison of iodine isotopes and phosphorus distributions in sections of the thyroid gland of rats which were submitted to an iodine-deficient diet followed by an injection of 129I.

Rapid localization of carbon 14-labeled molecules in biological samples by ion mass microscopy.

We report here on the ability of secondary ion mass spectrometry (SIMS) to provide rapid imaging of the intracellular distribution of 14C-labeled molecules. The validity of this method, using mass discrimination of carbon 14 atoms, was assessed by imaging the distribution of two molecules of well-known metabolism, [14C]-thymidine and [14C]-uridine, incorporated by human fibroblasts in culture. As expected, 14C ion images showed the presence of [14C]-thymidine in the nucleus of dividing cells, whereas [14C]-uridine was present in the cytoplasm as well as the nucleus of all cells, with a large concentration in the nucleoli. The time required to obtain the distribution images with the SMI 300 microscope was less than 6 min, whereas microautoradiography, the classical method for mapping the tissue distribution of 14C-labeled molecules, usually requires exposure times of several months. Secondary ion mass spectrometry using in situ mass discrimination is proposed here as a very sensitive method which permits rapid imaging of the subcellular distribution of molecules labeled with carbon 14.