Karin Mossberg

Evidence for colocalization of glucocorticoid receptor with cytoplasmic microtubules in human gingival fibroblasts, using two different monoclonal anti-GR antibodies, confocal laser scanning microscopy and image analysis.

The cellular distribution of the glucocorticoid receptor (GR) in relation to the microtubule protein tubulin was studied in human gingival fibroblasts, using two different anti-GR antibodies of different Ig-classes, by indirect immunofluorescence immunocytology. Further studies were performed by confocal laser scanning microscopy and digital image analysis. The study focused on fluorochrome separation, optical sectioning, digital subtraction techniques and reconstruction of projections obtained using stacks of recorded transversal sections. The data presented further strengthens the notion of a structural colocalization between GR and cytoplasmic microtubules in human fibroblasts.

Computerized Quantification of Immunofluorescence-labeled Axon Terminals and Analysis of Co-localization of Neurochemicals in Axon Terminals with a Confocal Scanning Laser Microscope'

The confocal scanning laser microscope (CSLM) offers improved optical resolution and contrast, high photometric precision, and the ability to make optical sections. These benefits were explored for use in quantitative analysis of immunofluorescence-labeled axon terminals. Guidelines were obtained for adjustments of the CSLM parameters. In the present applications, bleaching of the fluorescence did not represent a serious obstacle to analysis with the CSLM. A method was developed to distinguish the background fluorescence from the specific fluorescence labeling. This procedure made way for the development of automated quantification of immunolabeled axon terminals. The automated procedures substantially reduced the man-hour expenditure for analysis and provided highly reproducible quantifications compared with manual methods. The increased resolution and contrast of the CSLM allowed measurements of the fluorescence signal strength of individual axon terminals. The CSLM also allowed detection of co-localized neurochemicals in axon terminals.

Detection of doubly stained fluorescent specimens using confocal microscopy

Studies of doubly stained specimens were performed with a confocal scanning microscope. The instrument used provides the possibility of making separate detections of the fluorescent dyes. The optimal choice of excitation wavelengths and optical filters are discussed. The fluorphores that were used are Lucifer Yellow, Texas Red, fluorescein isothiocyanate and tetramethylrhodamine isothiocyanate.

Simultaneous confocal recording of multiple fluorescent labels with improved channel separation

Confocal microscopes are often used to study specimens labelled with fluorophores. A commonly used method for simultaneous recording of the distribution of multiple fluorophores is to divide the fluorescent light emitted by the specimen into different wavelength regions using dichroic and bandpass filters. These different wavelength regions are then distributed to multiple detectors. However, the broad and overlapping spectra of commonly used fluorophores often result in considerable crosstalk between channels. A new technique, intensity‐modulated multiple‐beam scanning (IMS) microfluorometry, can be used to reduce this cross‐talk substantially.

Reduction of cross-talk between fluorescent labels in scanning laser microscopy

By using dual detectors in combination with a dichroic filter, it is possible to record simultaneously the distribution of two fluorescent labels in a specimen. It is often difficult, however, to obtain a good separation, i.e. each detector will generally detect light from more than one fluorophore. In such cases it is desirable to find image‐processing methods to improve the separation. A simple method is to form a linear combination of the recorded images. In this paper we investigate the necessary prerequisites for this method to be successful, and we also investigate to what extent these are fulfilled in some practical cases. In this context the spectral properties of the fluorophores turn out to be of crucial importance. Even when the necessary prerequisites are not strictly fulfilled, a considerable improvement in image quality can, nevertheless, be obtained.

Morphometric studies of the localization of the glucocorticoid receptor in mammalian cells and of glucocorticoid hormone-induced effects.

We studied the subcellular distribution of the glucocorticoid receptor (GR) by light microscopy (LM) and confocal laser scanning microscopy (CLSM) in different mammalian cell types. The effect of added glucocorticoid hormones on GR distribution was investigated by photometric quantitation on optical sections obtained by CLSM followed by statistical analysis. In the control interphase cytoplasm, the distribution of GR was fibrillar in some and diffuse in other cell types. Fibrillar GR was distributed along cytoplasmic microtubules (MTs) with predilection for a subset of MTs. GR was also observed in the centrosomes. Nuclear GR was both diffuse and granular in distribution. During cell division, GR appeared in the mitotic apparatus at all stages of mitosis. These findings were not fixation-dependent. Glucocorticoid treatment increased both the nuclear and cytoplasmic GR signal. However, this was detectable only after precipitating but not cross-linking fixation. There was both intra- and intercellular GR heterogeneity in the absence and presence of hormone but no indication of a hormone-induced nuclear translocation of GR. We present a hypothetical model of two independent GR populations in the nucleus and cytoplasm, respectively, without any discernible ligand-induced nuclear translocation of GR. The extranuclear GR population may exert effect(s) on site in the cytoplasm without involving nuclear genomic transcription.

Imaging of fluorescent neurons labelled with fluoro-gold and fluorescent axon terminals labelled with AMCA (7-amino-4-methylcoumarine-3-acetic acid) conjugated antiserum using a UV-laser confocal scanning microscope.

This paper describes the implementation of an ultraviolet (UV) laser (Spectra Physics 171-18 with 3 lines: 334, 351 and 364 nm in UV) as light source for fluorescence confocal scanning microscopy. With this instrument it is possible to use fluorophores not previously available for confocal laser microscopical imaging of fluorophores such as fluoro-gold and AMCA. In the study we show confocal laser microscopical imaging of fluorescent motoneurons labelled by retrograde transport of fluoro-gold and AMCA-fluorescent axon terminals labelled with antisera against immunogenes as thyrotropin-releasing hormone (TRH) and calcitonin gene-related peptide (CGRP). These two fluorophores may be recorded simultaneously or separately by using a filter that suppresses the emission of one of the fluorophores. The described instrument should also be useful in applications involving detection of monoamines by the Falck-Hillarp technique, as well as measurements of cytosolic free calcium by indicators such as Fura-2 and Indo-1. Measurements performed in reflected and fluorescence light indicated that the resolution along the optical axis improved by about 25% when UV (351 nm) is used instead of visible light (514 nm). This figure is close to that expected on theoretical basis. There are, however, also serious problems related to the use of UV excitation. Firstly, objectives must be selected based on their UV transmission properties. Secondly, chromatic aberration may cause a substantial focal shift between illuminating and emitted light, calling for a flexible instrumental design in order to allow for compensation. As shown here, this problem can be circumvented by using reflecting objectives but at a price of lower resolution compared with high-aperture refracting objectives.

Use of UV excitation in confocal laser scanning fluorescence microscopy

Abstract By making only minor modifications, we adapted a conventional confocal beam-scanning laser microscope for the recording of UV-excited fluorescence. The major, and most expensive, change is that we coupled an external UV argon ion laser, providing the wavelengths 334, 351 and 364 nm, to the microscope scanner. We also replaced some optical components to obtain improved transmission and reflection properties in the UV. Only easily obtainable and inexpensive off-the-shelf components were used. The most serious problem encountered was the chromatic aberration of the microscope objective when using both UV and visible wavelengths. This is of no consequence in conventional microscopy where good imaging properties are important only in the visible region. In confocal microscopy on the other hand, good imaging properties are necessary for both the exciting and fluorescent light. Rather than having new optics designed, we tried with simple means to reduce the effects of the chromatic aberration to a tolerable level. This was done by mechanical adjustments in the ray-path. In addition we also tested two mirror objectives, which are inherently free from chromatic aberrations. However, such objectives have rather limited numerical apertures and are not of the immersion type. Their value in biomedical applications is therefore limited. The objective most frequently used in our experiments was a 63/1.25 oil-immersion fluorite. Without any compensation this objective had a depth resolution in UV-excited confocal fluorescence that was an order of magnitude worse than when using visible-light excitation. The useful field of view was also very small due to lateral chromatic aberration. By simple means we managed to improve the depth resolution by a factor of 4.4, and at the same time increase the useful field of view substantially. Still, the depth resolution was worse than what is obtained using visible light excitation. We think this is due to the fact that after compensation the objective is working with an incorrect tube length. Using the modified instrument, we recorded specimens labelled with AMCA and Fluoro-Gold, obtaining 1.5 μm thick optical sections.

Using intensity-modulated scanning beams in combination with lock-in detection for recording multiple-labeled fluorescent specimens in confocal laser microscopy

We demonstrate how the new Intensity-modulated Multiple-beam Scanning technique can be used in improve simultaneous recording of multiple fluorophores in confocal scanning laser microscopes.

Use of UV excitation for confocal fluorescence microscopy in a conventional beam-scanning instrument

By making only minor modifications, we have adapted a conventional confocal scanning laser microscope for the recording of UV-excited fluorescence. An external argon ion laser provides the wavelengths 334, 351, and 364 nm for specimen illumination. In addition to substituting some optical components to obtain improved transmission and reflection properties in the UV, we have also adjusted the ray-path to compensate for the severe chromatic aberration of most conventional microscope objectives in the UV. We have also tested mirror objectives, which are inherently free from chromatic aberrations. However, since these objectives are not of the immersion-type, and furthermore have rather low numerical apertures, they are of limited value in biomedical applications. Using the modified instrument, we have recorded specimens labeled with AMCA and Fluoro-Gold. At present the instrument is capable of recording optical sections with a thickness of 1.5 micrometers when using an oil-immersion objective with a numerical aperture of 1.25.