G. J. Brakenhoff

The temporal and spatial progression of DNA replication in interphase nuclei of eukaryotic cells has been investigated. Application of a recently developed technique for the immunofluorescence double staining of cell nuclei labelled first with iododeoxyuridine (IdUrd) and subsequently with chlorodeoxyuridine (CldUrd) allows the visualization of two replication patterns in the same nucleus originating from two different periods of the S-phase. We have analysed changes in the three-dimensional replication patterns during the S-phase. To record dual colour three-dimensional images of doubly stained nuclei, a confocal microscope is used. This CSLM is equipped with a specific laser/filter combination to collect both fluorescence signals (FITC and Texas Red) in a single scan, thus precluding pixel shift between the images. A method for the quantitative evaluation of the degree of overlap between DNA regions replicated in two different periods of the S-phase is applied. The results confirm the generally accepted theory that DNA is replicated coordinately in a specific temporal order during the S-phase. The replication time of a DNA domain (i.e. the time between initiation and termination of DNA replication within a domain) at the very beginning of the S-phase was known to be one hour (Nakamura et al., 1986). Our observations show that in the rest of the S-phase, the replication time of a DNA region is also about one hour. We conclude that replicon clusters located in the same region are replicated in the same relatively short period of time. After this period there is no unreplicated DNA left in this region.

SUMMARY The imaging characteristics of a confocal scanning light microscope (CSLM) with high aperture, immersion type, lenses (N.A. = 1·3) are investigated. In the confocal arrangement the images of the illumination and detector pinholes are made to coincide in a common point, through which the object is scanned mechanically. Results show that for point objects the theoretically expected improved response by a factor of 1·4 in comparison with standard microscopy can indeed be realized. Low side lobe intensity and absence of glare permits the imaging at high resolution of weak details close to strong features. A further improvement by a factor of 1·25 in point resolution in CSLM is found after apodization with an annular aperture. Due to the scanning approach all possibilities of electronic image processing become available in light microscopy.

Third harmonic generation microscopy is used to make dynamical images of living systems for the first time. A 100 fs excitation pulse at 1.2 aem results in a 400 nm signal which is generated directly within the specimen. Chara plant rhizoids have been imaged, showing dynamic plant activity, and non-fading image characteristics even with continuous viewing, indicating prolonged viability under these THG-imaging conditions.

In interphase cells the proliferation-associated antigen recognized by monoclonal antibody Ki-67 is almost exclusively located in the nucleoli. When cells at several stages of mitosis were examined for the localization of the Ki-67 antigen, a striking redistribution could be observed. During prophase the distinct nucleolar Ki-67 fluorescence changed to a bright irregular meshwork throughout the nucleoplasm. At metaphase the antigen appeared to be distributed in a reticulate structure surrounding the condensed chromosomes, while at late telophase a punctated staining of the entire nucleoplasm was observed, which preceded the typical nucleolar localization pattern in each of the two daughter cells. Immunolabelling with Ki-67 of metaphase chromosome spreads revealed a circumferential staining of the individual chromosomes. The Ki-67 antigen is preserved in nuclear matrix preparations obtained after in situ fractionation of interphase cells. When mitotic cells were exposed to such treatments, the obtained fluorescence data suggested that the antigen may be part of the chromosome scaffold. Quantification of the Ki-67 fluorescence signal using flow cytometry revealed the highest staining intensities in mitotic cells. Furthermore, it was shown that nutritionally deprived cells became negative for Ki-67.