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Much of the pioneering work on the genetics of cell cycle regulation was accomplished using budding and fission yeast. The relative simplicity of these single-celled organisms allowed investigators to readily identify and assign roles to individual genes. While the molecular mechanisms worked out in yeast are more or less identical to those operating in higher organisms, additional layers of control...
All eukaryotes rely on multi-protein assemblies, called kinetochores, to direct the segregation of their chromosomes in mitosis. The list of known kinetochore components has been growing rapidly in the post-genomic era: in animal cells, there are presently more than 80 proteins that show either exclusive or partial localization at kinetochores during mitosis. The future challenge is to elucidate how...
Mitotic and meiotic chromosomes are the compact packages that faithfully transport the genetic and epigenetic information to the following cell generations. How chromatin dynamically cycles between the decompacted interphase state that supports transcription and replication and the compacted state required for chromosome segregation is not understood. To address this long-standing problem, the structure...
Analysis of genetic interactions has been extensively exploited to study gene functions and to dissect pathway structures. One such genetic interaction is synthetic lethality, in which the combination of two non-lethal mutations leads to loss of organism viability. We have developed a dSLAM (heterozygote diploid-based synthetic lethality analysis with microarrays) technology that effectively studies...
Computational modeling has the potential to add an entirely new approach to hypothesis testing in yeast cell biology. Here, we present a method for seamless integration of computational modeling with quantitative digital fluorescence microscopy. This integration is accomplished by developing computational models based on hypotheses for underlying cellular processes that may give rise to experimentally...
Gross chromosomal rearrangements (GCRs), including translocations, deletions, amplifications and aneuploidy are frequently observed in various types of human cancers. Despite their clear importance in carcinogenesis, the molecular mechanisms by which GCRs are generated and held in check are poorly understood. By using a GCR assay, which can measure the rate of accumulation of spontaneous GCRs in Saccharomyces...
Drosophila melanogaster presents in an unparalleled opportunity to study the regulation of the cell division cycle in the context of cellular differentiation, growth regulation and the development of a multicellular organism. The complexity of Drosophila cell cycles and the large number of techniques available can, however, be overwhelming. We aim to provide here (1) an overview of cell cycle regulation...
Fluorescence activated cell sorting (FACS) analysis has become a standard tool to analyze cell cycle distributions in populations of cells. These methods require relatively large numbers of cells, and do not provide optimal resolution of the transitions between cell cycle phases. In this report we describe in detail complementary methods that utilize the incorporation of nucleotide analogs combined...
Studies in th Saccharomyces cerevisiae have provided a framework for understanding how eukaryotic cells replicate their chromosomal DNA to ensure faithful transmission of genetic information to their daughter cells. In particular, S. cerevisiae is the first eukaryote to have its origins of replication mapped on a genomic scale, by three independent groups using three different microarray-based approaches...
Although not a traditional experimental “method,” mathematical modeling can provide a powerful approach for investigating complex cell signaling networks, such as those that regulate the eukaryotic cell division cycle. We describe here one modeling approach based on expressing the rates of biochemical reactions in terms of nonlinear ordinary differential equations. We discuss the steps and challenges...
Our knowledge of cell cycle events such as DNA replication and mitosis has been advanced significantly through the use of Xenopus egg extracts as a model system. More recently, Xenopus extracts have been used to investigate the cellular mechanisms that ensure accurate and complete duplication of the genome, processes otherwise known as the DNA damage and replication checkpoints. Here we describe several...
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