Defect in early lung defence against Pseudomonas aeruginosa in DBA/2 mice is associated with acute inflammatory lung injury and reduced bactericidal activity in naïve macrophages
Chronic lung infection with P. aeruginosa and excessive neutrophil-associated inflammation are major causes of morbidity and mortality in patients with cystic fibrosis (CF). Overproduction of an exopolysaccharide known as alginate leads to the formation of mucoid biofilms that are resistant to antibiotics and host defences. Alginate overproduction or mucoidy is controlled by a stress-related ECF sigma factor AlgU/T. Mutation in the anti-sigma factor MucA is a known mechanism for conversion to mucoidy. Recently, we showed that inactivation of a kinase (KinB) in nonmucoid strain PAO1 results in overproduction of alginate. Here, we report the initial characterization of lipotoxin F (LptF, PA3692), an OmpA-like outer membrane protein that exhibited increased expression in the mucoid PAO1kinB mutant. The lipotoxin family of proteins has been previously shown to induce inflammation in lung epithelia, which may play a role in CF disease progression. Expression of LptF was observed to be AlgU-dependent and upregulated in CF isolates. Deletion of lptF from the kinB mutant had no effect on alginate production. Deletion of lptF from PAO1 caused a differential susceptibility to oxidants that can be generated by phagocytes. The lptF and algU mutants were more sensitive to hypochlorite than PAO1. However, the lptF mutant displayed increased resistance to hydrogen peroxide. LptF also contributed to adhesion to A549 human lung epithelial cells. Our data suggest that LptF is an outer membrane protein that may be important for P. aeruginosa survival in harsh environments, including lung colonization in CF.
The goal of this study was to ascertain the specific effects of 17-N-Allylamino-17-demethoxygeldanamycin (17-AAG) treatment in human acute myelogenous leukemia (AML). Four human leukemia cell lines were treated with varying doses of 17-AAG followed by analysis of toxicity, apoptosis, proliferation, and cell cycle. Cell cycle analysis revealed that the cells accumulate in G 2 /M phase within 96 hours of treatment, although the effect was not equivalent among the cell lines. p21, p53 expression and MDR1 activity were among the possible mechanisms uncovered for the differing responses. Exploiting these differences may allow for more effective combinatory treatments in patients with AML.
Cancer cells exist in a state of Darwinian selection using mechanisms that produce changes in gene expression through genetic and epigenetic alteration to facilitate their survival. Cellular plasticity, or the ability to alter cellular phenotype, can assist in survival of premalignant cells as they progress to full malignancy by providing another mechanism of adaptation. The connection between cellular stress and the progression of cancer has been established, although the details of the mechanisms have yet to be fully elucidated. The molecular chaperone HSP90 is often upregulated in cancers as they progress, presumably to allow cancer cells to deal with misfolded proteins and cellular stress associated with transformation. The objective of this work is to test the hypothesis that inhibition of HSP90 results in increased cell plasticity in mammalian systems that can confer a greater adaptability to selective pressures. The approach used is a murine in vitro model system of hematopoietic differentiation that utilizes a murine hematopoietic stem cell line, erythroid myeloid lymphoid (EML) clone 1, during their maturation from stem cells to granulocytic progenitors. During the differentiation protocol, 80%–90% of the cells die when placed in medium where the major growth factor is granulocyte–macrophage-colony stimulating factor. Using this selection point model, EML cells exhibit increases in cellular plasticity when they are better able to adapt to this medium and survive. Increases in cellular plasticity were found to occur upon exposure to geldanamycin to inhibit HSP90, when subjected to various forms of cellular stress, or inhibition of histone acetylation. Furthermore, we provide evidence that the cellular plasticity associated with inhibition of HSP90 in this model involves epigenetic mechanisms and is dependent upon high levels of stem cell factor signaling. This work provides evidence for a role of HSP90 and cellular stress in inducing phenotypic plasticity in mammalian systems that has new implications for cellular stress in progression and evolution of cancer.
The process of canalization whereby phenotypic traits are buffered against stochastic fluctuations to preserve the evolutionarily advantageous “normal” level can be potentially exploited during cancer progression. Release of canalization through pharmacologic or genetic down-regulation of Hsp90 removes this buffer and increases variation, allowing for rapid changes in traits as evidenced in Drosophila, Arabidopsis, and maize. If cancer is viewed as a Darwinian struggle of the premalignant cell to acquire the hallmarks of a fully malignant cell or be extinguished, then increasing variation or heterogeneity has a beneficial effect on the fitness of the premalignant cell. It is the goal of this work to test the hypothesis that Hsp90-derived canalization, though its ability to buffer phenotypic variance and thus reduce cell plasticity, is involved in hematopoietic cell differentiation. Furthermore, we wish to determine if the canalization mechanism has an epigenetic component. We are currently using a murine hematopoietic stem cell culture system, EML cells, to investigate this hypothesis. EML cells have been induced to differentiate into macrophage and granulocyte lineages with and without pharmacologic inhibition of HSP90 through 17-AAG. We found that 17-AAG treatment increases the ability of these differentiating cells to survive in a selective medium, during culturing conditions that suggest an epigenetic mechanism. If our hypothesis is true, then loss of canalization could be a potentially powerful mechanism driving cancer progression. Fully understanding the mechanism involved would allow for new therapeutic insights and provide vital information regarding the use of HSP90 inhibitors. Citation Format: Jennifer Napper, Vincent E. Sollars. Phenotypic plasticity in the EML cell culture system as a result of HSP90 inhibition. [abstract]. In: Proceedings of the AACR Special Conference on Chromatin and Epigenetics in Cancer; Jun 19-22, 2013; Atlanta, GA. Philadelphia (PA): AACR; Cancer Res 2013;73(13 Suppl):Abstract nr B16.
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