Analysis of epigenetic alterations to chromatin during development.

Each cell within a multicellular organism has distinguishable characteristics established by its unique patterns of gene expression. This individual identity is determined by the expression of genes in a time and place-dependent manner, and it is becoming increasingly clear that chromatin plays a fundamental role in the control of gene transcription in multicellular organisms. Therefore, understanding the regulation of chromatin and how the distinct identity of a cell is passed to daughter cells during development is paramount. Techniques with which to study chromatin have advanced rapidly over the past decade. Development of high throughput techniques and their proper applications has provided us essential tools to understand the regulation of epigenetic phenomena and its effect on gene expression. Understanding the changes that occur in chromatin during the course of development will not only contribute to our knowledge of normal gene expression, but will also add to our knowledge of how gene expression goes awry during disease. This review opens with an introduction to some of the key premises of epigenetic regulation of gene expression. A discussion of experimental techniques with which one can study epigenetic alterations to chromatin during development follows, emphasizing recent breakthroughs in this area. We then present examples of epigenetic mechanisms exploited in the control of developmental cell fate and regulation of tissue-specific gene expression. Finally, we discuss some of the frontiers and challenges in this area of research.

Tiam1 regulates cell adhesion, migration and apoptosis in colon tumor cells.

The guanine nucleotide exchange factor Tiam1 regulates numerous biologic properties including migration and invasion. We demonstrated previously that colon tumor cells biologically selected for increased migration were increased in Tiam1 expression. Cells selected for increased Tiam1 expression or that ectopically overexpress Tiam1 were increased in metastatic potential. Here, we demonstrate that Tiam1 regulates additional functions associated with metastasis, including reduced cellular adhesion and resistance to anoikis. Tiam1 effects on cellular migration are mediated through its downstream substrate, Rac. Increased Tiam1 expression also leads to anoikis-resistance, whereas decreasing Tiam1 expression by siRNA sensitizes cells to this form of apoptosis; however, Tiam1's regulation of anoikis is Rac-independent. Staurosporine sensitivity is also Rac-independent, suggesting Tiam1's effects on apoptosis require other effectors. As many of the observed phenotypes are characteristic of a transition of transformed epithelial cells to a mesenchymal-like phenotype, we also examined biochemical properties associated with an EMT. We demonstrate an increase in vimentin expression in cell lines that overexpress Tiam1 and have a more metastatic phenotype. Concomitant with this increase, we observe a decrease in E-cadherin expression in these cells. Lastly, we stained a panel of human colorectal specimens and adjacent normal tissue, and demonstrate that Tiam1 is overexpressed in a subset of human colorectal tumors. In summary, in colon tumor cells, Tiam1 affects multiple properties associated with acquisition of the metastatic phenotype, and may represent a marker of colon tumor progression and metastasis in a subset of tumors.

The guanine nucleotide exchange factor Tiam1 increases colon carcinoma growth at metastatic sites in an orthotopic nude mouse model.

Alterations in migration and adhesion are critical to invasion and metastasis. To examine signaling pathways important for colon tumor metastasis, cells of increased migratory potential from the low migratory SW480 human colorectal carcinoma parental cell line were biologically selected by serial migration through modified Boyden chambers. Several sublines were obtained with statistically significantly increased migration relative to the parental cell line. One highly migratory population was single-cell cloned and characterized. The migratory clones exhibit a four- to five-fold increase in protein and mRNA expression of T-lymphoma invasion and metastasis gene 1 (Tiam1), a guanine nucleotide exchange factor. To determine directly the role of Tiam1 in the migration of these migratory sublines, the parental SW480 cell line was transfected with a plasmid encoding the Tiam1 protein, and single cell clones were established. Ectopic expression of Tiam1 in these clones led to morphologic changes identical to biologically selected clones and increased migration. Finally, the implantation of clones that overexpress Tiam1 into the cecum of athymic mice resulted in tumor growth in the spleen, liver, and lung, whereas parental cells do not form tumors by this route of injection. These results demonstrate that overexpression of Tiam1 contributes to the metastatic phenotype of colon cancer cells.

The role of the guanine nucleotide exchange factor Tiam1 in cellular migration, invasion, adhesion and tumor progression.

While advances in molecular genetics have provided new insights into molecular alterations that lead to the development of many tumors, including breast carcinoma, the genetic and epigenetic alterations that result in metastatic spread of the disease, from which afflicted patients ultimately succumb, are much more poorly understood. Important biologic processes in the development of metastasis include increased migration and invasion of tumor cells. While the regulation of these processes is complex, they are controlled in part by small G proteins of the Rho family, including Rho, Rac, and Cdc42, that are involved in cytoskeletal organization. These proteins, active when bound to GTP, are, in turn, regulated by guanine nucleotide exchange factors (GNEFs) and guanine nucleotide activating proteins. The GNEF Tiam1 catalyzes nucleotide exchange for Rac in vivo, and Rac, Cdc42 and Rho in vitro. Tiam1 was identified first in 1994 by in vitro selection for invasiveness in T-lymphoma cells. Accordingly, Tiam1 has been shown to increase invasion in T-lymphoma cells, as well as to increase cellular migration in fibroblasts, and to promote motility in some neuronal cells. In contrast, Tiam1 has been demonstrated to increase cellular adhesion in some epithelial cell populations. Thus, Tiam1 has multiple roles in regulating cellular functions, likely dependent on the cell type, the substratum, transformation status of the cells, and the activation state of small G proteins in a given cell. Increasing evidence has focused on Tiam1's regulation, as well as Tiam1's role in cancer progression and metastasis. Recent results from other laboratories and ours have demonstrated that increased Tiam1 expression correlates with grade of breast cancer in humans and metastatic potential of human breast carcinoma cell lines in nude mice. This review will discuss Tiam1's cellular functions and methods of regulation, and will highlight Tiam1's contribution to cancer progression and metastasis.