Working with the confocal scanning UV-laser microscope: specific DNA localization at high sensitivity and multiple-parameter fluorescence

A new UV-visible confocal laser scanning microspectrofluorometer designed for spectral cellular imaging

With the aim to perform spectroscopic studies and spectral images inside living cells, a microspectrofluorometer has been designed for two-dimensional spectral imaging in the visible and in the near-UV region. The main advantage of the device relies on its ability to scan the laser beam along one direction of the sample. This scanning is optically coupled with one direction of a bidimensional detector, allowing an instantaneous recording of a one-dimensional spectral image. The overall scanning of the sample is achieved by means of submicrometric displacements of the stage in the perpendicular direction. The main characteristics and performances of the microspectrofluorometer in terms of sensitivity (detection of a few molecules), spatial resolution (0.5 x 0.5 x 1 microm), and spectral resolution (1 nm) are presented. Finally, applications of this new apparatus concerning in situ localization and spectral characterization of two dyes are shown with Drosophila salivary glands (ethidium bromide) and T47D tumor cells (Hoechst 33342).

Multiparameter microscopic analysis of nucleolar structure and ribosomal gene transcription

A survey of novel microscopic approaches for structural and functional analysis of subnucleolar compartments will be presented. Research on nucleolar structure and function concentrates predominantly on two distinct types of nucleoli: (1) nucleoli present during the interphase of the cell cycle in somatic tissue culture cells and (2) nucleoli present in meiotic cells, e.g. oocytes of amphibians. These nucleoli are found during meiotic prophase of oogenesis and are functional during several months of the diplotene stage of oogenesis. A further characteristic is the fact that these nucleoli are extrachromosomal, since they originate by selective ribosomal DNA (rDNA) amplification during the early pachytene stage of oogenesis. Miller-type chromatin spread preparations using transcriptionally active nucleoli, to a major part, contributed to our understanding of the structural organization of polymerase I directed pre-rRNA transcription. Although the structural organization of the template-associated pre-rRNA transcript is known in some detail from chromatin spreads, relatively little is known about structural aspects of pre-rRNA processing. In order to investigate this intriguing question in more detail, we have developed a computer-based densitometry analysis of both template-associated and template-dissociated pre-rRNA transcripts in order to follow the structural modification of pre-rRNA transcripts during processing. Another line of experiments is devoted to the in situ structure of actively transcribing genes in the nucleolus. In order to bridge the gap between light microscopy and electron microscopy we started video-enhanced light microscopical analysis of actively transcribing genes. Although the dimensions of individual spread genes are critical for detection by optical microscopy, we succeeded in obtaining the first series of images of transcribing genes in their "native' hydrated state. An additional promising type of microscopy is transmission X-ray microscopy. Recent progress in instrumentation as well as in sample preparation has allowed us to obtain the first images of density distribution within intact, fully hydrated nucleoli using amplitude-contrast and/or phase-contrast X-ray microscopy of non-contrasted, fully hydrated nucleoli at different states of transcriptional activity. Whereas the above mentioned investigations using video microscopy and X-ray microscopy are predominantly applicable to the analysis of amplified nucleoli in amphibian oocytes, which are characterized by an extremely high transcription rate of 80-90% of rDNA genes per individual nucleolus, structural analysis of the in situ arrangement of actively transcribing genes in somatic nucleoli as present in the interphase nucleus is far more difficult to perform, mainly due to the much lower number of simultaneously transcribed active genes per individual nucleolus. Visualization of actively transcribed gene clusters is approached by an integrated experimental assay using video microscopy, confocal laser scan microscopy, and antibodies against specific nucleolar proteins.

Flux of intracellular labile zinc during apoptosis (gene-directed cell death) revealed by a specific chemical probe, Zinquin

BACKGROUND

The transition metal Zn(II) is thought to regulate cell and tissue growth by enhancing mitosis (cell proliferation) and suppressing the counterbalancing process of apoptosis (gene-directed cell death). To investigate the role of Zn(II) further, we have used a UV-excitable Zn(II)-specific fluorophore, Zinquin. The ester group of Zinquin is hydrolyzed by living cells, ensuring its intracellular retention; this allows the visualization and measurement of free or loosely-bound (labile) intracellular Zn(II) by fluorescence video image analysis or fluorimetric spectroscopy.

RESULTS

Here we show that in cells undergoing early events of apoptosis, induced spontaneously or by diverse agents, there is a substantial increase in their Zinquin-detectable Zn(II). This increase occurred in the absence of exogenous Zn(II) and before changes in membrane permeability, consistent with a release of Zn(II) from intracellular stores or metalloproteins rather than enhanced uptake from the medium. We propose that there is a major redistribution of Zn(II) during the induction of apoptosis, which may influence or precipitate some of the later biochemical and morphological changes.

CONCLUSIONS

The phenomenon of Zn(II) mobilization, revealed by Zinquin, presents a new element in the process of apoptosis for investigation and may permit rapid and sensitive identification of apoptotic cells, particularly in those tissues where their frequency is low.

A UV laser-scanning confocal microscope for the measurement of intracellular Ca2+

Modifications to the optics of a conventional confocal laser-scanning microscope were made to allow imaging intracellular Ca(2+)-dependent fluorescence with a UV laser (351 or 364 nm). Modifications included: (1) a chromatic compensation lens in the laser path; (2) the design of a practically achromatic relay lens; (3) a longer tube length for the objective; and (4) highly reflective mirrors maximizing fluorescence measurement. This UV laser-scanning confocal microscope (UV-CLSM) yielded a lateral resolution of < 0.3 micron and an axial resolution of < 1.5 microns and a relevant field size of 100 microns in diameter for a 40X objective). The effects of varying the focal length of a compensation lens, the degree of the correction for the coverglass thickness of objective and the detector aperture size on the quality of image formation were examined. Finally, UV-CLSM revealed optical sections of fine and complex structures of bullfrog sympathetic neurones loaded with a Ca(2+)-sensitive fluorescent probe. Changes in intracellular free Ca2+ distribution in response to high [K+] or caffeine were demonstrated. In addition, an increase in the intracellular concentration of caffeine applied externally was clearly imaged in space and time and distinguished from a resultant rise in [Ca2+]i. Thus, the UV-CLSM developed is suitable for ratiometric intracellular Ca2+ measurements and other biological studies.

Cytochemistry and immunocytochemistry of nucleolar chromatin in plants

This review attempts to document the most relevant data currently available on the in situ localization of nucleolar chromatin on plant cells. The data provided by the most powerful and recent in situ techniques, such as DNA specific ultrastructural staining, immunogold labelling, in situ molecular cytochemistry, in situ hybridization or confocal microscopy, are summarized and discussed in the light of the potential and limitations of each individual methodology. The presence of DNA in both fibrillar centres and regions of the dense fibrillar component is extensively documented. Data on the nucleolar distribution of other important macromolecules involved in ribosomal transcription are also shown and referred to with regard to the location of DNA. The comparison with the available data on the animal cell nucleolus points towards models of similar functional organization in both plant and animal nucleoli.

Ultraviolet confocal fluorescence microscopy of the in vitro cornea: redox metabolic imaging

A laser scanning microscope was fitted with two argon-ion lasers that provided wavelengths in the regions of 364, 488, and 514 nm. A Zeiss water objective of 25 x , with a numerical aperture of 0.8, corrected for the UV, was used to measure the fluorescence from optical sections of freshly enucleated rabbit eyes. The confocal microscope was used in both the reflected and fluorescent modes to image in situ epithelial and endothelial cells. An excitation wavelength of 364 nm and emission at 400-500 nm were used to image the fluorescence from reduced pyridine nucleotides. We demonstrate the feasibility of two-dimensional fluorescent confocal imaging of reduced pyridine nucleotides in corneal epithelial and endothelial cells.

In vitro decondensation of mammalian sperm and subsequent formation of pronuclei-like structures for micromanipulation

In this study, we describe an efficient protocol for the formation of in vitro developed pronuclei for micromanipulation techniques. Our approach involved incubation of demembranated or permeabilized mammalian sperm in a phosphate buffer supplemented with heparin and beta-mercaptoethanol. Under the prevailing conditions, we achieved a uniform and reliable synchronous decondensation of sperm nuclear DNA. This initial decondensation facilitated the removal of mammalian protamines upon subsequent incubation in an amphibian egg extract. The interchange of protamines for histones to stabilize the DNA structure is recognized as a prerequisite for pronuclear formation. Furthermore, immunocytochemical studies have revealed that pronuclear development is accompanied by the formation of a nuclear lamina with corresponding DNA synthesis. The method described gave a high yield of nuclei during pronuclear formation. Ultimately, our aim is to transfer the in vitro-developed pronuclei into mammalian oocytes by micromanipulation. This novel procedure may prove useful in alleviating severe male factor problems especially in oligozoospermic cases in our in vitro fertilization center.

Localization of the nuclear matrix protein mitotin in mouse cells with a mitotic or endomitotic cell cycle

Immunofluorescence staining was used to study the precise subcellular distribution of the nuclear matrix antigen, mitotin, in mouse cells characterized by either a mitotic or an endomitotic organization of the cell cycle. In mitotically dividing cells, mitotin showed a speckled distribution within interphase nuclei. In addition, some interphase cells exhibited a weak, focused signal adjacent to the nucleus, reflecting a possible staining of the centrosome region. Using digital contrast-enhanced immunofluorescence microscopy, a distinct association of mitotin to the centrosome, pole microtubules, and midbody could be revealed in cells at different stages of mitosis. In parallel, trophoblast giant cells characterized by an endomitotic cell cycle were derived from blastocyst outgrowths and analyzed likewise. In all giant cells examined so far, mitotin was restricted to the nuclear compartment alone, although different patterns of intranuclear staining could be detected. The present study provides further information about the precise localization of mitotin in mitotic cells, especially during mitosis. In view of the results, the staining pattern observed in endomitotic cells may allow for a better understanding of the origin and the organization of the endomitotic cell cycle.