Errors in chromosome segregation during mitosis result in aneuploidy, which in humans may play a role in the onset of neoplasia by changing gene dosage. Nearly all solid tumors exhibit genomic instability at the chromosomal level, showing both structural and numerical chromosome abnormalities. Chromosomal instability occurs early in the development of cancer and may represent an important step in the initiation and/or progression of the disease. Telomere integrity appears to be a critical element in the genesis of structural chromosome imbalances, but it is still not clear whether it can also generate numerical chromosome aberrations. We investigated the possible relationship between telomere shortening and aneuploidy formation in human mammary epithelial cells using the cytokinesis-block micronucleus assay combined with fluorescent DNA probes. In this cell system, uncapped chromosomes fuse with each other resulting in dicentric chromosomes, which are known to be a source of new structural chromosome rearrangements. Here, we show that in primary epithelial cells, the chromosomes with short telomeres are more frequently involved in missegregation events than chromosomes of normal telomere length. Whole chromosome aneuploidy occurs through both nondisjunction and anaphase lagging of dicentric chromatids, which suggests that pulling anaphase bridges toward opposite poles can generate the necessary force for detaching a chromosome from the microtubules of one or both spindle poles. Therefore, telomere-driven instability can promote not only the appearance of chromosomal rearrangements but also the appearance of numerical chromosome aberrations that could favor cell immortalization and the acquisition of a tumor phenotype.
The development of genomic instability is an important step toward generating the multiple genetic changes required for cancer. Telomere dysfunction is one of the factors that contribute to tumorigenesis. Telomeres shorten with each cell division in the absence of telomerase. Human mammary epithelial cells (HMECs) obtained from normal human tissue demonstrate two growth phases. After an initial phase of active growth, HMECs exhibit a growth plateau termed selection. However, some cells can emerge from this growth plateau by spontaneously losing expression of the p16(INK4a) protein. These post-selection HMECs are capable of undergoing an additional 20-50 population doublings in culture. Continued proliferation of these post-selection HMECs leads to further telomere erosion, loss of the capping function, and the appearance of end-to-end chromosome fusions that can enter bridge-fusion-breakage (BFB) cycles, generating massive chromosomal instability before terminating in a population growth plateau termed agonescence. We have found that the chromosome arms carrying the shortest telomeres are those involved in telomere-telomere type rearrangements. In addition, we found that the risk of a particular chromosome being unstable differs between individuals. Most importantly, we identified sister chromatid fusion as a first event in generating genomic instability in HMECs. During post-selection HMEC growth, double strand breaks are generated by both fused chromosomes as well as individual chromosomes with fused chromatids entering BFB cycles. These broken chromosome extremities are able to join other broken ends or eroded telomeres, producing massive chromosomal instability at the later passages of the cell culture. This article contains Supplementary Material available at http://www.interscience.wiley.com/jpages/1045-2257/suppmat.
Psoriasis is a prevalent, chronic inflammatory disease of the skin, mediated by crosstalk between epidermal keratinocytes, dermal vascular cells, and immunocytes such as antigen presenting cells (APCs) and T cells. Exclusive cellular “responsibility” for the induction and maintenance of psoriatic plaques has not been clearly defined. Increased proliferation of keratinocytes and endothelial cells in conjunction with APC/T cell/monocyte/macrophage inflammation leads to the distinct epidermal and vascular hyperplasia that is characteristic of lesional psoriatic skin. Despite the identification of numerous susceptibility loci, no single genetic determinant has been identified as responsible for the induction of psoriasis. Thus, numerous other triggers of disease, such as environmental, microbial and complex cellular interactions must also be considered as participants in the development of this multifactorial disease. Recent advances in therapeutics, especially systemic so-called “biologics” have provided new hope for identifying the critical cellular targets that drive psoriasis pathogenesis. Recent recognition of the numerous co-morbidities and other autoimmune disorders associated with psoriasis, including inflammatory bowel disease, multiple sclerosis, rheumatoid arthritis, and systemic lupus erythematosus suggest common signaling elements and cellular mediators may direct disease pathogenesis. In this review, we discuss common cellular pathways and participants that mediate psoriasis and other autoimmune disorders that share these cellular signaling pathways.
Psoriasis is a hereditary disease elicited by chronic activation of cutaneous T cells. Delineating the mechanistic interplay of the cell subsets involved is key to developing the next generation of effective treatments. In this issue, Bovenschen et al. report that regulatory T cells maintain a fine balance between the transcription factors Foxp3 and RORγt. In patients with psoriasis, Tregs readily turn into IL-17-expressing cells, thus potentially perpetuating the inflammatory process that characterizes the disease. Results demonstrating that the histone/protein deacetylation inhibitor trichostatin A can block this conversion suggest that an epigenetic modification may underlie regulatory T-cell plasticity.
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