RESUMO
Background: Aberrant activation of mTORC1 is clearly defined in TSC, causing uncontrolled cell growth. While mTORC1 inhibitors show efficacy to stabilise tumour growth in TSC, they are not fully curative. Disease facets of TSC that are not restored with mTOR inhibitors might involve NF-κB. The study aimed to characterise NF-κB in the context of TSC. Results: Enrichment of NF-κB-regulated genes was observed in TSC patient tumours, SEN/SEGAs, cortical tubers and a TSC tumour-derived cell line (621 - 101). Highlighting an inflammatory component of TSC, TSC cell models showed an elevated level of NF-κB and STAT3 activation. Herein, we report a dysregulated inflammatory phenotype of TSC2-deficient cells where NF-κB promotes autocrine signalling involving IL-6. Of importance, mTORC1 inhibition does not block this inflammatory signal to promote STAT3, while NF-κB inhibition was much more effective. Combined mTORC1 and NF-κB inhibition was potent at preventing anchorage-independent growth of TSC2-deficient cells, and unlike mTORC1 inhibition alone was sufficient to prevent colony regrowth after cessation of treatment. Conclusion: This study reveals autocrine signalling crosstalk between NF-κB and STAT3 in TSC cell models. Furthermore, the data presented indicate that NF-κB pathway inhibitors could be a viable adjunct therapy with the current mTOR inhibitors to treat TSC.
RESUMO
Both hard material photolithography and soft lithography are widely used for patterned cell culture. Soft lithography techniques enable bioactive molecule incorporation, however complex surface modifications are required to introduce specific ligands or proteins in conventional photolithography. In this study, we demonstrate human umbilical vein cell (HUVEC) and adult bone marrow derived mesenchymal stem cell (MSC) patterning on titanium diboride (TiB2) layers deposited on silicon (Si) substrates by electron-beam evaporation and micropatterned using photolithography. Micropatterned cell growth specificity on geometric shapes of circle and/or lines is achieved via differential growth factors adsorption in the presence of heparin. Specifically, the deposited films of TiB2 showed increased stiffness, hardness, hydrophilicity and surface charge when compared to background Si. These substrates were found to be compatible with HUVEC and MSC viability, based on biomarker expression and RNA-sequence transcriptome analysis. Cell-type dependent, micropattern selective cell growth, such as contact guidance, alignment, and durotaxis, were observed. In addition, MSC clustering was achieved, enabling a three-dimensional (3D) aggregate based microenvironment during culture. This study clearly demonstrates the potential of microfabricated Si and TiB2 biomaterials for patterned cell culture in vitro, independent of any additional surface modification.