Effects of growth conditions on mitochondrial morphology in Saccharomyces cerevisiae.

Effects of growth conditions on mitochondrial morphology were studied in living Saccharomyces cerevisiae cells by vital staining with the fluorescent dye dimethyl-aminostyryl-methylpyridinium iodine (DASPMI), fluorescence microscopy, and confocal-scanning laser microscopy. Cells from respiratory, ethanol-grown batch cultures contained a large number of small mitochondria. Conversely, cells from glucose-grown batch cultures, in which metabolism was respiro-fermentative, contained small numbers of large, branched mitochondria. These changes did not significantly affect the fraction of the cellular volume occupied by the mitochondria. Similar differences in mitochondrial morphology were observed in glucose-limited chemostat cultures. In aerobic chemostat cultures, glucose metabolism was strictly respiratory and cells contained a large number of small mitochondria. Anaerobic, fermentative chemostat cultivation resulted in the large, branched mitochondrial structures also seen in glucose-grown batch cultures. Upon aeration of a previously anaerobic chemostat culture, the maximum respiratory capacity increased from 10 to 70 mumole.min-1.g dry weight-1 within 10 h. This transition resulted in drastic changes of mitochondrial number, morphology and, consequently, mitochondrial surface area. These changes continued for several hours after the respiratory capacity had reached its maximum. Cyanide-insensitive oxygen consumption contributed ca. 50% of the total respiratory capacity in anaerobic cultures, but was virtually absent in aerobic cultures. The response of aerobic cultures to oxygen deprivation was qualitatively the reverse of the response of anaerobic cultures to aeration. The results indicate that mitochondrial morphology in S. cerevisiae is closely linked to the metabolic activity of this yeast: conditions that result in repression of respiratory enzymes generally lead to the mitochondrial morphology observed in anaerobically grown, fermenting cells.

A computer-aided measuring system for the characterization of yeast populations combining 2D-image analysis, electronic particle counter, and flow cytometry.

An integrated measuring system was developed that directly compares the shape of size distributions of Saccharomyces cerevisiae populations obtained from either microscopic measurements, electronic particle counter, or flow cytometer. Because of its asymmetric mode of growth, a yeast population consists of two different subpopulations, parents and daughters. Although electronic particle counter and flow cytometer represent fast methods to assess the growth state of the population as a whole, the determination of important cell cycle parameters like the fraction of daughters or budded cells requires microscopic observation. We therefore adapted a semiautomatic and interactive 2D-image processing program for rapid and accurate determination of volume distributions of the different sub-populations. The program combines the capacity of image processing and volume calculation by contour-rotation, with the potential of visual evaluation of the cells. High-contrast images from electron micrographs are well suited for image analysis, but the necessary air drying caused the cells to shrink to 35% of their hydrated volume. As an alternative, hydrated cells overstained with the fluorochrome calcofluor and visualized by fluorescence light microscopy were used. Cell volumes calculated from length, and diameter measurements with the assumption of an ellipsoid cell shape were underestimated as compared to volumes derived from 2D-image analysis and contour rotation, because of a deviating cell shape, especially in the older parent cells with more than one bud scar. The bimodal volume distribution obtained from microscopic measurements was identical to the protein distribution measured with the flow cytometer using cells stained with dansylchloride, but differed significantly from the size distribution measured with the electronic particle counter. Compared with the flow cytometer, 2-D image analysis can thus provide accurate distributions with important additional information on, for instance, the distributions of subpopulations like parents, daughters, or budded cells.

Confocal scanning laser microscopy of mitochondria: a possible tool in the diagnosis of mitochondrial disorders.

This paper describes a non-invasive method for the study of mitochondrial morphology in cultured human skin fibroblasts by confocal scanning laser microscopy after staining the mitochondria with 2-[4-(dimethylaminostyryl]-1-methylpyridinium iodide. This method is applied to compare mitochondria in fibroblasts from healthy individuals and from patients with mitochondrial myopathy. In most cases there is a striking swelling of the patient's mitochondria and a loss of fine structure. The results with respect to the potential of this method as a diagnostic tool are discussed.

Three-dimensional chromosome arrangement of Crepis capillaris in mitotic prophase and anaphase as studied by confocal scanning laser microscopy.

To estimate the extent of ordering of chromosomes, confocal scanning laser microscopy was used to make three-dimensional images from optical sections. For Crepis capillaris, which has 2n = 6 easily recognizable chromosomes, a statistically significant sample of 75 Feulgen-stained root tip anaphases was analysed. A comparison of the observed chromosome ordering and the expected random distribution showed a significant surplus of one of the arrangements with a juxtaposition of the two chromosomes with a nucleolus organizer region. Two of the arrangements with these chromosomes in opposite positions were never observed in our material. Another analysis of 30 mithramycin A-stained prophases and 30 meta- and anaphases showed partly different patterns of non-random chromosome distribution in the two stages of mitosis. A preference for an association of the homologues was observed for all pairs of chromosomes in prophase cells, whereas in meta- and anaphase the association only persisted for the nucleolus organizer chromosomes. This indicates that there may be some relocation of the chromosome positions during the transition from prophase to metaphase. In meta- and anaphase one of the arrangements with juxtaposed NOR chromosomes was preferred, i.e. the ordering in which chromosomes 1 and 3 occupied alternate positions. Probably, the nucleolus is an important factor in producing a non-random distribution, but there could be other factors that influence chromosome ordering as well. A comparison of the anaphase chromosome ordering in C. capillaris plants from very different localities, indicated that the observed non-random distribution was independent of the origin of the material. Existing models of chromosome disposition are not sufficient to explain the observed non-random chromosome ordering in C. capillaris.

Three-dimensional imaging in fluorescence by confocal scanning microscopy.

The improved resolution and sectioning capability of a confocal microscope make it an ideal instrument for extracting three-dimensional information especially from extended biological specimens. The imaging properties, also with finite detection pinholes are considered and a number of biological applications demonstrated.

3-dimensional imaging of biological structures by high resolution confocal scanning laser microscopy.

Imaging in confocal microscopy is characterized by the ability to make a selective image of just one plane inside a specimen, virtually unaffected -within certain limits- by the out-of-focus regions above and below it. This property, called optical sectioning, is accompanied by improved imaging transverse to the optical axis. We have coupled a confocal microscope to a computer system, making the combination of both an excellent instrument for mapping the 3-dimensional structure of extended specimens into a computer memory/data array. We measured that the volume element contributing to each data point has, under typical fluorescence conditions, a size of 0.2 X 0.2 X 0.72 micron. The data can be analysed and represented in various ways, i.e., stereoscopical views from any desired angle. After a description of the experimental arrangement, we show various examples of biological and food-structural studies. The microscope can be operated either in reflection or in fluorescence. In the latter mode a spectral element allows selection of the wavelength band of fluorescence light contributing to the image. In this way, we can distinguish various structures inside the cell and study their 3-dimensional relationships. Various applications in biology and the study of food structure are presented.

Three-dimensional chromatin distribution in neuroblastoma nuclei shown by confocal scanning laser microscopy.

The relationship between cell shape and function has long been of interest. However, although the behaviour of the cytoskeleton during the cell cycle has been studied extensively variations in the shape and three-dimensional substructure of the nucleus are less well documented. The spatial distribution of chromatin has previously been studied by a mathematical analysis of the optical densities of stained nuclei, allowing an indirect derivation of the three-dimensional distribution of chromatin. More direct information on chromatin organization can be obtained from electron-microscopic serial sections, although this is very laborious. Using an iterative deconvolution algorithm, Agard and Sedat achieved a degree of optical sectioning in conventional fluorescence microscopy and reconstructed the three-dimensional arrangement of polytene chromosomes. We report here on the three-dimensional structure of cultured mammalian cells as visualized by confocal scanning laser microscopy (CSLM). The exceptionally short depth of field of this imaging technique provides direct optical sectioning which, together with its higher resolution, makes CSLM extremely useful for studying the three-dimensional morphology of biological structures.

Effects of temperature on the size and shape of Escherichia coli cells.

Two substrains of Escherichia coli B/r were grown to steady-state in batch cultures at temperatures between 22 and 42 degrees C in different growth media. The size and shape of the cells were measured from light and electron micrographs and with the Coulter channelizer. The results indicate that cells are shorter and somewhat thicker at the lower temperatures, especially in rich growth media; cell volume is then slightly smaller. A lower temperature was further found to increase the relative duration of the constriction period. The shapes of the cell size distributions are indistinguishable, indicating that the pattern of growth of the cells is the same at all temperatures. The adaptation of the cells to a temperature shift lasted several generations, indicating that the morphological effects of temperature are mediated by the cell's physiology.