Synthetic (glyco-)peptides of the homophilic recognition domain of E-cadherin lead to increased E-cadherin mRNA synthesis and are inductors of cell differentiation in primary lung cancer cell lines.

E-cadherin is one of the critical molecules involved in the metastatic process in many types of cancer. Once combined, E-cadherin exceeds the amount of membranous E-cadherin on the cellular surface by activation of intracellular signaling cascades. Studies on transformed keratinocytes of the HaCat cell line showed induction of differentiation by synthetical partial structures of the homophilic binding region of E-cadherin. The knowledge of effects in lung cancer cells is sparse. Therefore, the effects in primary lung cancer cell lines were investigated. Four primary lung cancer cell lines were incubated for 3, 6, 12, 15, 18, and 24h with synthetic partial structures (peptide and glycopeptide). The control substance was sodium butyrate. mRNA was isolated, and relative quantification of E-cadherin was performed using the Real-Time PCR. During the stimulation period, morphologic pictures were taken, and immunohistochemical staining of membranous E-cadherin was performed. Life/dead assays were used to display cell vitality. The intracellular E-cadherin mRNA amount was increased after incubation with the synthetic partial structures. Life/dead assays showed improved survival and integrated cell/cell bindings after stimulation with the partial structures. Increased cell mortality was revealed after sodium butyrate incubation. An effect mediated via E-cadherin on the cellular surface is proposed. The two synthetic partial structures of the homophilic binding region of E-cadherin increased the intracellular E-cadherin mRNA amount, cell-cell bindings, and survival of the tumor cells. Extracellular binding by synthetic partial structures to the binding region may have a beneficial influence on tumor progression in the metastatic process.

MGMT activity, promoter methylation and immunohistochemistry of pretreatment and recurrent malignant gliomas: a comparative study on astrocytoma and glioblastoma.

The DNA repair protein O(6)-methylguanine-DNA methyltransferase (MGMT) is a key player in tumor cell resistance. Promoter methylation, MGMT activity and immunohistochemistry are used for determining the MGMT status. However, it is unclear whether MGMT promoter methylation correlates with MGMT activity and whether MGMT promoter methylation of the pretreatment tumor predicts the MGMT status of recurrences. To address these questions, we determined MGMT activity promoter methylation and immunoreactivity in pretreatment and recurrent glioblastomas (GB, WHO Grade IV), and in astrocytomas (WHO Grade III). We show that GB that were promoter methylated display a range of 0-62 fmol/mg MGMT and tumors that were nonmethylated 0-423 fmol/mg protein. For astrocytomas, promoter-methylated samples displayed 0-28 fmol/mg and, nonmethylated samples, 23-107 fmol/mg. No correlation was found between the intensity of promoter methylation and MGMT activity. Given a threshold level of 30 fmol/mg of protein, we found a correlation between promoter methylation and no/low MGMT activity in 82.4% of the tumors. This high correlation level was only observed when tumors were excluded showing a hemimethylated promoter (20%). Therefore, classification of hemimethylated tumors remains questionable. Further, we show that 39.1% of pretreatment GB and 5.3% of recurrences were promoter methylated, which is in line with the observed increase of MGMT activity in recurrences. Although individual exceptions were found, the data show an overall correlation between promoter methylation and lack/low MGMT activity in GB and astrocytomas. We also show that promoter methylation assay is superior over immunohistochemistry in determining the MGMT status defined by a given MGMT activity level.

Implementation of new software for fast screening of cell compatibility on surface modifications using low-contrast time-lapsed microscopy.

Assessment of cell adhesion and cell size provides valuable information on surface biocompatibility. However, most investigations on cell morphology dynamics are time and resource consuming, of rather descriptive character and lack procedures for appropriate quantification. The aim of the study was to develop a software programme which allows automated cell segmentation and identification as well as calculation and further processing of cell size in low-contrast images. The software utilises modified edge detection and morphologic operations for automatic cell analysis in light microscopy images. In an application study, osteogenic cell-adhesion dynamics were quantified for the ECM proteins collagen type I (COL) and fibronectin (FIB) over a period of 12 hrs. Untreated tissue culture polystyrene (TCPS) served as control. The software programme proofed full function in automatic cell tracking and quantification of cell size. After 11 h, cell sizes were highest for COL (6391 ± 1167 µm(2)) and FIB (6036 ± 411 µm(2)) compared with TCPS (3261 ± 693 µm(2)). The developed software allows quantification of initial cell size changes on translucent surface modifications and is suitable as a reliable tool for fast biocompatibility screening. Osteogenic cell adhesion was significantly promoted by COL and FIB indicating the potential of respective functionalized biomaterial surfaces.

Pharmacological inhibition of Bcl-2 family members reactivates TRAIL-induced apoptosis in malignant glioma.

The major aim of this study was to develop novel therapeutic approaches to potentiate and reactivate apoptosis induced by TNF-Related Apoptosis Inducing Ligand (TRAIL) in malignant glioma. Analysis of five glioma cell lines (U87, U251, U373, MZ-54 and MZ-18) indicated that only two of the cell lines were sensitive to apoptosis induced by TRAIL alone. TRAIL resistance was not correlated to expression levels of the death receptors DR4 and DR5 or the decoy receptors DcR1 and DcR2, suggesting that it was mediated by inactivation of TRAIL-induced downstream signalling. Activation of the BH3 only protein Bid and subsequent activation of the mitochondrial apoptosis pathway are known to play a pivotal role in TRAIL-induced apoptosis. Since this process is blocked by overexpression of anti-apoptotic Bcl-2 family members, we analyzed the therapeutic potential of BH3 mimetics in potentiating TRAIL-induced apoptosis. Treatment with TRAIL in combination with the specific Bcl-2 inhibitor HA14-1 and the Bcl-2/Bcl-xL inhibitor BH3I-2' potently enhanced apoptosis in TRAIL-sensitive U87 cells in a dose-dependent fashion. TRAIL-induced apoptosis was significantly reactivated by HA14-1 and BH3I-2' in one (U343) and two (MZ-54 and MZ-18) of three investigated TRAIL-insensitive cell lines, respectively. Knockdown of the anti-apoptotic Bcl-2 family member Mcl-1 by RNA interference had no additional effect on apoptosis induced by TRAIL and HA14-1 in U87 and U343 cells. Our data indicate that Bcl-2 and Bcl-xL play fundamental roles in TRAIL resistance of malignant glioma and suggest that using TRAIL or agonistic TRAIL receptor antibodies in combination with BH3 mimetics may represent a promising approach to reactivate apoptosis in therapy-resistant high grade gliomas.

In vitro assessment of motility and proliferation of human osteogenic cells on different isolated extracellular matrix components compared with enamel matrix derivative by continuous single-cell observation.

OBJECTIVES: The composition of the extracellular matrix (ECM) plays a substantial role in bone remodelling, fracture healing and osseointegration of dental implants by regulating proliferation, migration and finally differentiation of osteogenic cell populations. Emdogain, a composition of an enamel matrix derivative (EMD), has been introduced as a potential candidate to promote tissue regeneration. We investigated whether EMD could serve as a potential promoter of cell proliferation and motility as a dynamic cell response and compared the results with the ubiquitous single ECM components type I collagen and laminin. MATERIAL AND METHODS: In the investigation presented, we used a continuous observation method for the analysis of migratory and proliferative patterns of individual cells. We analyzed the response of four osteoblastic cell lines to specific extracellular ligands (type I collagen, laminin and EMD) over a period of 24 h compared with untreated glass surface and bovine serum albumin (BSA) as control groups. RESULTS: Type I collagen and laminin promoted cell motility significantly compared with the control groups and, in part, compared with EMD as well. The analysis of all 451 investigated cells revealed the following mean values for cell motiliy: untreated glass (n=99): 5.46+/-2.74 microm/h, BSA (n=89): 6.35+/-2.43 microm/h, type I collagen (n=108): 8.77+/-3.42 microm/h, laminin (n=74): 9.89+/-5.10 microm/h and EMD (n=81): 7.92+/-3.35 microm/h. Proliferation rates on the different surfaces were heterogenous for all investigated cell lines and varied from 0% to 50% within 24 h without a correlation to cell motility. CONCLUSION: In our study, EMD promotes cell motility better than the control groups. The two investigated single ECM components type I collagen and laminin promoted cell motility superior to EMD. This supports the hypothesis that EMD promotes a less mobile but more differentiated osteogenic phenotype.