Metallothionein as a clonable tag for protein localization by electron microscopy of cells.

A benign, clonable tag for the localization of proteins by electron microscopy of cells would be valuable, especially if it provided labelling with high signal-to-noise ratio and good spatial resolution. Here we explore the use of metallothionein as such a localization marker. We have achieved good success with desmin labelled in vitro and with a component of the yeast spindle pole body labelled in cells. Heavy metals added after fixation and embedding or during the process of freeze-substitution fixation provide readily visible signals with no concern that the heavy atoms are affecting the behaviour of the protein in its physiological environment. However, our methods did not work with protein components of the nuclear pore complex, suggesting that this approach is not yet universally applicable. We provide a full description of our optimal labelling conditions and other conditions tried, hoping that our work will allow others to label their own proteins of interest and/or improve on the methods we have defined.

The use of filter membranes for high-pressure freezing of cell monolayers.

Rapid freezing of cells and tissues, followed by freeze-substitution fixation and plastic embedding, has become a highly reliable method for preparing samples for imaging in the electron microscope. High-pressure freezing is an efficient means of immobilizing suspensions of yeasts, thick pellets of mammalian cells, or small (< 0.5 mm) pieces of plant or animal tissue. Monolayers of cultured mammalian cells that are too thick for efficient immobilization by other modes of rapid freezing have also been successfully preserved by this method. Monolayer cultures are often important because they can be imaged by light microscopy (LM) both before and after their preparation for electron microscopy (EM). Additionally, some monolayer cultures serve as model systems for physiological processes, so it is important that cells under study can grow on a substrate that is both physiologically appropriate and convenient for EM processing. Here we describe a reliable method for preparing mammalian cell monolayers (PtK1 and polarized MDCK) for EM. Our protocol results in good preservation of cellular ultrastructure, it is a useful companion to studies of cell physioloy and, with some limitation, is suitable for correlative LM and EM.

Slk19p is a centromere protein that functions to stabilize mitotic spindles.

We have identified a novel centromere-associated gene product from Saccharomyces cerevisiae that plays a role in spindle assembly and stability. Strains with a deletion of SLK19 (synthetic lethal Kar3p gene) exhibit abnormally short mitotic spindles, increased numbers of astral microtubules, and require the presence of the kinesin motor Kar3p for viability. When cells are deprived of both Slk19p and Kar3p, rapid spindle breakdown and mitotic arrest is observed. A functional fusion of Slk19p to green fluorescent protein (GFP) localizes to kinetochores and, during anaphase, to the spindle midzone, whereas Kar3p-GFP was found at the nuclear side of the spindle pole body. Thus, these proteins seem to play overlapping roles in stabilizing spindle structure while acting from opposite ends of the microtubules.

Improved preservation of ultrastructure in difficult-to-fix organisms by high pressure freezing and freeze substitution: I. Drosophila melanogaster and Strongylocentrotus purpuratus embryos.

In this study, we have applied the techniques of high pressure freezing and freeze substitution to embryonic cell types which are usually difficult to fix properly for electron microscopy. In both Drosophila and Strongylocentrotus purpuratus, we see improved preservation of both membrane systems and cytoskeleton when compared to published results on the same cells using conventional electron microscope (EM) fixation methods. Finally, we have seen that postembedding labelling of sections is possible even after light osmium fixation during freeze substitution.