Severe keratin 5 and 14 mutations induce down-regulation of junction proteins in keratinocytes.

The intermediate filament cytoskeleton is essential for the development and maintenance of normal tissue function. A number of diverse recent observations implicate these filament systems in sensing stress and protecting cells against its worst consequences. Cells expressing severely disruptive keratin mutations, characteristic of Dowling-Meara EBS, were previously reported to show elevated responses to physiological stress, and partial disassembly of cell junctions was reported upon direct mechanical stress to the cells. Gene expression microarray analysis has therefore been used here to examine the broad spectrum of effects of mutant keratins. Many genes associated with keratins and other components of the cytoskeleton showed altered expression levels; in particular, many cell junction components are down-regulated in EBS cells. That this is due to the expression of the mutant keratins, and not to other genetic variables, is supported by observation of the same effects in isogenic cells generated from wild type keratinocytes transfected with the same keratin mutations in the helix boundary motifs of K14 or K5. Whilst the mechanism underlying this is unclear, these findings may help to explain other aspects of EBS-associated pathology, such as faster scratch wound migration, or acantholysis (cell-cell separation) in patients' skin. Constitutive stress combined with constitutively weakened cell junctions may also contribute to a recently reported increased risk of non-melanoma skin cancer in EBS patients.

Dual-specificity phosphatases in the hypo-osmotic stress response of keratin-defective epithelial cell lines.

Although mutations in intermediate filament proteins cause many human disorders, the detailed pathogenic mechanisms and the way these mutations affect cell metabolism are unclear. In this study, selected keratin mutations were analysed for their effect on the epidermal stress response. Expression profiles of two keratin-mutant cell lines from epidermolysis bullosa simplex patients (one severe and one mild) were compared to a control keratinocyte line before and after challenge with hypo-osmotic shock, a common physiological stress that transiently distorts cell shape. Fewer changes in gene expression were found in cells with the severely disruptive mutation (55 genes altered) than with the mild mutation (174 genes) or the wild type cells (261 genes) possibly due to stress response pre-activation in these cells. We identified 16 immediate-early genes contributing to a general cell response to hypo-osmotic shock, and 20 genes with an altered expression pattern in the mutant keratin lines only. A number of dual-specificity phosphatases (MKP-1, MKP-2, MKP-3, MKP-5 and hVH3) are differentially regulated in these cells, and their downstream targets p-ERK and p-p38 are significantly up-regulated in the mutant keratin lines. Our findings strengthen the case for the expression of mutant keratin proteins inducing physiological stress, and this intrinsic stress may affect the cell responses to secondary stresses in patients' skin.

Transcriptional profiling of the LPS induced NF-kappaB response in macrophages.

BACKGROUND: Exposure of macrophages to bacterial products such as lipopolysaccharide (LPS) results in activation of the NF-kappaB transcription factor, which orchestrates a gene expression programme that underpins the macrophage-dependent immune response. These changes include the induction or repression of a wide range of genes that regulate inflammation, cell proliferation, migration and cell survival. This process is tightly regulated and loss of control is associated with conditions such as septic shock, inflammatory diseases and cancer. To study this response, it is important to have in vitro model systems that reflect the behaviour of cells in vivo. In addition, it is necessary to understand the natural differences that can occur between individuals. In this report, we have investigated and compared the LPS response in macrophage derived cell lines and peripheral blood mononuclear cell (PBMC) derived macrophages. RESULTS: Gene expression profiles were determined following LPS treatment of THP-1 cells for 1 and 4 hours. LPS significantly induced or repressed 72 out of 465 genes selected as being known or putative NF-kappaB target genes, which exhibited 4 temporal patterns of expression. Results for 34 of these genes, including several genes not previously identified as LPS target genes, were validated using real time PCR. A high correlation between microarray and real time PCR data was found. Significantly, the LPS induced expression profile of THP-1 cells, as determined using real time PCR, was found to be very similar to that of human PBMC derived macrophages. Interestingly, some differences were observed in the LPS response between the two donor PBMC macrophage populations. Surprisingly, we found that the LPS response in U937 cells was dramatically different to both THP-1 and PBMC derived macrophages. CONCLUSION: This study revealed a dynamic and diverse transcriptional response to LPS in macrophages, involving both the induction and repression of gene expression in a time dependent manner. Moreover, we demonstrated that the LPS induced transcriptional response in the THP-1 cell line is very similar to primary PBMC derived macrophages. Therefore, THP-1 cells represent a good model system for studying the mechanisms of LPS and NF-kappaB dependent gene expression.