Synchronization of Yeast.

The budding yeast Saccharomyces cerevisiae and fission yeast Schizosaccharomyces pombe are amongst the simplest and most powerful model systems for studying the genetics of cell cycle control. Because yeast grows very rapidly in a simple and economical media, large numbers of cells can easily be obtained for genetic, molecular, and biochemical studies of the cell cycle. The use of synchronized cultures greatly aids in the ease and interpretation of cell cycle studies. In principle, there are two general methods for obtaining synchronized yeast populations. Block-and-release methods can be used to induce cell cycle synchrony. Alternatively, centrifugal elutriation can be used to select synchronous populations. Because each method has innate advantages and disadvantages, the use of multiple approaches helps in generalizing results. An overview of the most commonly used methods to generate synchronized yeast cultures is presented along with working Notes: a section that includes practical comments, experimental considerations and observations, and hints regarding the pros and cons innate to each approach.

Methods of Synchronization of Yeast Cells for the Analysis of Cell Cycle Progression.

Cell division is a fascinating and fundamental process that sustains life. By this process, unicellular organisms reproduce and multicellular organisms sustain development, growth, and tissue repair. Division of a mother cell gives rise to two daughter cells according to an ordered set of events within four successive phases called G1 (gap1), S (DNA Synthesis), G2 (gap2), and M (Mitosis) phase. How these different phases are orchestrated to ensure the physical separation of the two daughter cells is a tightly regulated process. Indeed, inappropriate cell division could lead to uncontrolled cell proliferation and ultimately to cancer. Saccharomyces cerevisiae is an excellent model system for unraveling the secrets of cell division. A large community of researchers has chosen budding yeast as a model because of its advantages: rapid growth in simple and economical media, tractable genetics, powerful biochemistry, cell biology, and proteomics approaches. Furthermore, the cell cycle mechanisms, as elucidated in yeast, are conserved in higher eukaryotes. The ability to synchronize and get large numbers of cells in a particular stage of the cell cycle is crucial to properly explore the mechanisms of the cell cycle. An overview of the most common yeast synchronization techniques has been compiled in this chapter.

Fission Yeast Cell Cycle Synchronization Methods.

Fission yeast cells can be synchronized by cell cycle arrest and release or by size selection. Cell cycle arrest synchronization is based on the block and release of temperature-sensitive cell cycle mutants or treatment with drugs. The most widely used approaches are cdc10-129 for G1; hydroxyurea (HU) for early S-phase; cdc25-22 for G2, and nda3-KM311 for mitosis. Cells can also be synchronized by size selection using centrifugal elutriation or a lactose gradient. Here we describe the methods most commonly used to synchronize fission yeast cells.