Mechanical injury of tissues is followed by the formation of a provisional fibrin matrix, which is later replaced by granulation tissue. The fibrinolytic proteinase, plasmin, is thought to contribute to the displacement of the primary matrix. Plasmin is generated from the ubiquitous proenzyme plasminogen by plasminogen activators. The system of plasminogen activation is controlled at several levels: plasminogen activator inhibitors (PAI-1 and PAI-2) counteract the activity of plasminogen activators and alpha 2-antiplasmin inhibits the activity of plasmin. In order to elucidate the mechanisms that regulate the plasminogen activator system in healing human skin wounds, we performed the immunohistological study reported here. The plasmin inhibitor alpha 2-antiplasmin and PAI-2 were found in the primary fibrin-rich matrix and in the granulation tissue. alpha 2-Antiplasmin was diffusely distributed in the tissue and its distribution correlated with the presence and localization of plasmin(ogen) except that, in contrast to plasmin(ogen), the alpha 2-antiplasmin was apparently not cell-associated. The stainings for PAI-2 increased with time and paralleled the development of the cellular infiltrate. PAI-2 was found in association with cells, which were identified by double immunofluorescence stainings as monocytes/macrophages and fibroblasts. In line with the immunohistological data, polymerase chain reaction after reverse transcription revealed mRNA for PAI-2 in healing human skin wounds. Taken together, our findings indicate that in healing human skin wounds, PAI-2 is the primary regulator of plasminogen activators, whereas alpha 2-antiplasmin may serve to control plasmin activity.
The phase and mixing state of atmospheric aerosols is a central determinant of their properties and thus their role in atmospheric cycling and climate. Particularly, the hygroscopic response of aerosol particles to relative humidity (RH) variation is a key aspect of their atmospheric life cycle and impacts. Here we applied X-ray microspectroscopy under variable RH conditions to internally mixed aerosol particles from the Amazonian rain forest collected during periods with anthropogenic pollution. Upon hydration, we observed substantial and reproducible changes in particle microstructure, which appear as mainly driven by efflorescence and recrystallization of sulfate salts. Multiple solid and liquid phases were found to coexist, especially in intermediate humidity regimes. We show that X-ray microspectroscopy under variable RH is a valuable technique to analyze the hygroscopic response of individual ambient aerosol particles. Our initial results underline that RH changes can trigger strong particle restructuring, in agreement with previous studies on artificial aerosols.
Recently, we identified the homeodomain transcription factor CUTL1 as important mediator of cell migration and tumor invasion downstream of transforming growth factor b (TGFb). The molecular mechanisms and effectors mediating the pro-migratory and pro-invasive phenotype induced by CUTL1 have not been elucidated so far. Therefore, the aim of this study was to identify signaling pathways downstream of CUTL1 which are responsible for its effects on tumor cell migration. We found that the reduced motility seen after knock down of CUTL1 by RNA interference is accompanied by a delay in tumor cell spreading. This spreading defect is paralleled by a marked reduction of Src protein levels. We show that CUTL1 leads to Src protein stabilization and activation of Srcregulated downstream signaling molecules such as RhoA, Rac1, Cdc42 and ROCK. In addition, we demonstrate that CUTL1 decreases proteasome-mediated Src protein degradation, possibly via transcriptionally upregulating Cterminal Src kinase (Csk). Based on experiments using Src knockout cells (SYF), we present evidence that Src plays a crucial role in CUTL1-induced tumor cell migration. In conclusion, our findings linking the pro-invasive transcription factor CUTL1 and the Src pathway provide important new insights in the molecular effector pathways mediating CUTL-induced migration and invasion.
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