Jan Bonnet

Platinum Porphyrins as Phosphorescent Label for Time-resolved Microscopy

We investigated phosphorescent metalloporphyrins as potential labels for time-resolved microscopy. On the basis of spectroscopic analysis of their physicochemical properties (quantum yield, molar absorption coefficient, decay times) the best candidates were selected. Next, we synthesized antibody and avidin metalloporphyrin conjugates. The optimal F/P ratio with respect to quantum yield, decay time, and retention of biological activity of these immunoreagents was determined. The reagents were then evaluated by in situ hybridization and immunocytochemical procedures for demonstration of hapten-labeled DNA probes, membrane antigens (CD type), and 28S rRNA. All stained samples exhibited bright phosphorescence that could be selectively detected using time-resolved microscopy, especially when glucose/glucose oxidase was added to the embedding medium to deplete oxygen. Applications of time-resolved detection of phosphorescent porphyrins in strongly autofluorescent material (histological sections) are discussed.

An automated microscope for quantitative cytology combining television image analysis and stage scanning microphotometry.

This paper describes an automated microscope developed for operation in conjunction with the Leyden Television Analysis System. It features automated control of magnification, illumination, movement of scanning stages, and fine focus. These functions are controlled by means of a microcomputer. This enables a flexible design and relieves the supervising computer of simple but time consuming tasks. The combination of an automated microscope and Leyden Television Analysis System provides a powerful tool in quantitative cytological research. The flexible design permits other microscopic functions to be added with relatively little effort.

Phosphorescent Platinum/Palladium Coproporphyrins for Time-resolved Luminescence Microscopy:

Streptavidin and antibodies were labeled with phosphorescent platinum and palladium coproporphyrin. The optimal conjugates were selected on the basis of spectroscopic analysis (molar extinction coefficient, quantum yield, lifetime) and using ELISA assays to determine the retention of biological activity and immunospecificity. They were subsequently tested for the detection of prostate-specific antigen, glucagon, human androgen receptor, p53, and glutathione transferase in strongly autofluorescent tissues. Furthermore, platinum and palladium coproporphyrin-labeled dUTPs were synthesized for the enzymatic labeling of DNA probes. Porphyrin-labeled DNA probes and porphyrin-labeled streptavidin conjugates were evaluated for DNA in situ hybridization on metaphase spreads, using direct and indirect methods, respectively. The developed in situ detection technology is shown to be applicable not only in mammals but also in plants. A modular-based time-resolved microscope was constructed and used for the evaluation of porphyrinstained samples. The time-resolved module was found suitable for detection of antigens and DNA targets in an autofluorescent environment. Higher image contrasts were generally obtained in comparison with conventional detection systems (e.g., fourfold improvement in detection of glutathione transferase).

Multicolour preparations for in situ hybridization using precipitating enzyme cytochemistry in combination with reflection contrast microscopy

We have further developed a method for the detection of different enzyme cytochemical reaction products by means of reflection contrast microscopy (RCM). By embedding these enzyme precipitates in a protein matrix, we were able to prevent the reaction products from dissolving in immersion oil, which is required for RCM analysis. The applicability of the RCM procedure is, therefore, extended to a range of cytochemical enzyme precipitation methods, which normally result in oil soluble reaction products. To test their usefulness, these enzyme precipitates have been used in single- as well as double-label in situ hybridization (ISH) procedures to visualize a number of DNA target sequences by several different reflection colours, i.e. white, yellow and red. Three repetitive DNA probes for the (sub)centromeric regions of chromosomes 1, 7 and 17, as well as a repetitive DNA probe for the telomeric region of chromosome 1, and two cosmid DNA probes (40 kb each) for both arms of chromosome 11 could be detected with high efficiency in both interphase and metaphase preparations. Moreover the enzyme precipitates were shown to be stable upon exposure to excitation light or upon storage. It may be concluded that these findings render RCM a sensitive method for the visualization of multiple targets in biological specimens.

Reflection contrast microscopy of ultrathin sections in immunocytochemical localization studies : a versatile technique bridging electron microscopy with light microscopy

Reflection contrast microscopy (RCM) of ultrathin sections was recently introduced as a sensitive technique for visualization with enhanced definition in immunogold histochemistry. Experience of using RCM as a major tool in immunocytochemical research in different fields is summarized, e.g. oncology, nephrology and embryology. The sensitive visualization of immunocytochemical labels, gold particles or peroxidase-diaminobenzidine deposits in or on ultrathin sections, by RCM instead of electron microscopy is demonstrated. RCM of ultrathin sections is an adequate light microscopical alternative for immunoelectron microscopy, since an overview of both label and tissue is obtained with a high image definition and high contrast of label. In the studies presented, RCM is shown to provide a better gradation in staining intensity and staining pattern than other light microscopical methods. Moreover, a precise localization of multiple labels is obtained with this method. Besides the applications shown, ultrathin section visualization by RCM is very useful for correlative light- and electron microscopical studies of fine structures. Commercially available fluorescence microscopes can be adapted for proper RCM functioning; an adaptation scheme and list of microscopes tested is provided.

Reflection contrast microscopy performed on epi‐illumination microscope stands: Comparison of reflection contrast‐ and epi‐polarization microscopy

In reflection contrast microscopy (RCM) special optics such as a quarter‐wave plate and a central stop are used, the latter being unique for Leitz microscope stands and contributing much to contrast enhancement of the image. In this paper we demonstrate that a cap or prism, linked by oil immersion to the glass slide, can be used instead of this central stop. Thus, microscope stands with incident illumination may be used for RCM.

Effect of chromatic errors in microscopy on the visualization of multi-color fluorescence in situ hybridization.

The relevant microscopical conditions for the optimal visualization of ratio-color FISH stained cells were investigated. Special attention was given to the influence of the type of illumination, (semi)-critical vs. Köhler type illumination, in combination with the use of multi-band excitation and emission filters, on the registration of the colors of ratio labelled probes. Due to chromatic errors, many collecting lenses were found to cause a wavelength dependent excitation pattern with critical illumination. This resulted in a change of the observed color of microscopic objects when stained with a mixture of two dyes and excited with a dual band pass filter. A quantitative study of this effect for semi-critical illumination of FISH ratio-labelled chromosomes revealed a difference of 20% between highest and lowest ratio values depending on the position of the object in the microscopic field vs. only 2.5% for Köhler type of illumination. The impact of these errors on the identification of ratio-labelled probes and on the sensitivity of comparative genomic hybridization (CGH) to detect gene amplifications or losses is discussed. Standard preparations consisting of solutions of defined mixtures of fluorescent dyes or objects stained with defined ratios of fluorophores, are proposed to correct for the errors observed.

A new type of cytocentrifuge, the valve-centrifuge.

SummaryA new type of cytocentrifuge has been developed in which the sedimentation process of the cells onto the slides is separated from the draining of the sedimentation fluid. This is realised by electrically controlled valves which can be closed and opened while the centrifuge is running. Sedimentation is carried out with closed valves, draining of adhering medium with open valves.The preparations, freed of adhering medium by the centrifugal force can be taken out and the cells can be fixed. Alternatively the valves can be closed again and fixative can be introduced through a central well, the cells still being under the influence of the centrifugal force. With subsequent draining of the fixative and introduction of washing and staining solutions through the central well, the whole process from sedimentation to staining can be carried out in the running centrifuge. The process seems well suited for complete automation.Using dilution series from a suspension of human buffy coat cells counted in a Buerker chamber, the cell counts in the centrifuge preparations showed virtually total recovery of cells, with no apparent selection or specific distribution of cell types. Draining of the sedimentation and fixative fluids at a slow rate was found to be vital for optimal recovery of cells. The morphology of different cell types sedimented on the slide was excellent. The flattening of nuclei through gravity was studied by cytophotometry of Feulgen-stained leucocytes. The nuclear area of these cells was found to be approximately double that from cells in identically stained classical smears. With this type of valve-centrifuge a quantitative and unbiased recovery of uniformly spread and flattened cells on coverslips or slides may be obtained, thus making the procedure well suited to automated analysis based on cytophotometric principles and morphometric pattern recognition.