Differential effect of hypoxia on early endothelial-mesenchymal transition response to transforming growth beta isoforms 1 and 2.

Angiogenesis is essential for mammalian development and tissue homeostasis, and is involved in several pathological processes, including tumor growth and dissemination. Many factors within the tissue microenvironment are known to modulate angiogenesis, including cytokines, such as transforming growth factor beta (TGFß), and oxygen level. TGFß exists in three different isoforms (1, 2 and 3), all of which (albeit in different contexts) might mediate angiogenesis and are able to induce endothelial-mesenchymal transition (EndoMT), a process involved in heart development, pathologic fibrosis and, as recently reported, in angiogenesis. Low oxygen level, referred to as hypoxia, has been independently shown to induce angiogenesis, modulate TGFß signalling and promote EndoMT. However, how these phenomena might be interconnected to drive angiogenesis is rather unexplored. To begin addressing the potential contribution of TGFß-induced EndoMT to angiogenesis, and to explore how microenvironmental hypoxia might influence these processes, we investigated the effect of TGFß isoforms 1 and 2 on early EndoMT response in cultured adult endothelium under standard (21 %) and hypoxic (1 %) culture conditions. Our data indicates that EndoMT-like changes, such as an increase in expression and nuclear translocation of Snail, Slug and Zeb1, and reduction of VE-cadherin expression, occur in response to TGFß1 and/or TGFß2 as early as 6h after stimulation and might be enhanced by hypoxia in an isoform-specific manner. Further, hypoxia enhances canonical TGFß signalling, and appears to be a key determinant of Snail's differential involvement in endothelial cell responses to TGFß1 versus TGFß2.

Par6 is an essential mediator of apoptotic response to transforming growth factor beta in NMuMG immortalized mammary cells.

BACKGROUND: We previously observed that the TGFbeta-Par6 pathway mediates loss of polarity and apoptosis in NMuMG cells. Here we investigate the contribution of Par6 versus TGFbeta receptor I activation to TGFbeta-induced apoptosis in association with changes in apico-basal polarity. We focus on the effect of Par6 activation on alpha6beta4 integrin expression and localization, and Nuclear Factor-kappaB (p65/RelA) activation, previously shown to mediate polarity-dependent cell survival. METHODS: Using immunoblotting and/or immunofluorescence we investigated the effect of TGFbeta1 on apoptosis, alpha6, beta4 and beta1 integrin expression/localization, and p65/RelA phosphorylation/localization in monolayer and three-dimensional (3D) cultures of NMuMG cells with an overactive or inactive Par6 pathway. Results were quantified by band densitometry or as percent of 3D structures displaying a phenotype. Differences among means were compared by two-way ANOVA. RESULTS: Blocking Par6 activation inhibits TGFbeta-induced apoptosis. Par6 overactivation enhances TGFbeta-induced apoptosis, notably after 6-day exposure to TGFbeta (p < 0.001), a time when parental NMuMG cells no longer respond to TGFbeta apoptotic stimuli. 48-hour TGFbeta treatment reduced beta4 integrin levels in NMuMG monolayers and significantly reduced the basal localization of alpha6 (p < 0.001) and beta4 (p < 0.001) integrin in NMuMG 3D structures, which was dependent on both Par6 and TGFbeta receptor I activation and paralleled apoptotic response. After 6-day exposure to TGFbeta, Par6-dependent changes to beta4 integrin were no longer apparent, but there was reduced phosphorylation of p65/RelA (p < 0.001) only in Par6 overexpressing cells. Differences in p65/RelA localization were not observed among the different cell lines after 48-hour TGFbeta exposure. CONCLUSIONS: Par6 and TGFbeta receptor I activation are both necessary for TGFbeta-induced apoptosis in NMuMG cells. Importantly, Par6 overexpression enhances the sensitivity of NMuMG to TGFbeta-induced apoptosis, notably upon prolonged exposure to this growth factor, when NMuMG parental cells are usually apoptosis-resistant. Thus, endogenous Par6 level might be important in determining whether TGFbeta will function as either a pro-apoptotic or pro-survival factor in breast cancer, and potentially aid in predicting patient's prognosis and therapy response.

De novo genetic variation revealed in somatic sectors of single Arabidopsis plants.

Concern over the tremendous loss of genetic diversity among many of our most important crops has prompted major efforts to preserve seed stocks derived from cultivated species and their wild relatives.  Arabidopsis thaliana propagates mainly by self-fertilizing, and therefore, like many crop plants, theoretically has a limited potential for producing genetically diverse offspring. Despite this, inbreeding has persisted in Arabidopsis for over a million years suggesting that some underlying adaptive mechanism buffers the deleterious consequences of this reproductive strategy. Using presence-absence molecular markers we demonstrate that single Arabidopsis plants can have multiple genotypes. Sequence analyses reveal single nucleotide changes, loss of sequences and, surprisingly, acquisition of unique genomic insertions. Estimates based on quantitative analyses suggest that these genetically discordant sectors are very small but can have a complex genetic makeup. In ruling out more trivial explanations for these data, our findings raise the possibility that intrinsic drivers of genetic variation are responsible for the targeted sequence changes we detect. Given the evolutionary advantage afforded to populations with greater genetic diversity, we hypothesize that organisms that primarily self-fertilize or propagate clonally counteract the genetic cost of such reproductive strategies by leveraging a cryptic reserve of extra-genomic information.