Miklós Petrás

Selecting the right fluorophores and flow cytometer for fluorescence resonance energy transfer measurements

Fluorescence resonance energy transfer applied in flow cytometry (FCET) is an excellent tool for determining supramolecular organization of biomolecules at the cell surface or inside the cell. Availability of new fluorophores and cytometers requires the establishment of fluorophore dye pairs most suitable for FCET measurements.

Two-sided fluorescence resonance energy transfer for assessing molecular interactions of up to three distinct species in confocal microscopy

The role of the expression patterns of proteins involved in oncogenesis can be understood after characterizing their multimolecular interactions. Conventional FRET methods permit the analysis of interaction between two molecular species at the most, which necessitates the introduction of new approaches for studying multicomponent signaling complexes. Flow cytometric as well as microscopic donor (dbFRET) and acceptor (abFRET) photobleaching FRET measurements were performed to determine the association states of ErbB2, β1‐integrin, and CD44 receptors. Based on consecutively applied abFRET and dbFRET methods (two‐sided FRET), the relationship of β1‐integrin–ErbB2 heteroassociation to ErbB2 homoassociation and of β1‐integrin–ErbB2 heteroassociation to ErbB2–CD44 heteroassociation was studied by correlating pixel‐by‐pixel FRET values of the corresponding abFRET and dbFRET images in contour plots. Anticorrelation was observed between β1‐integrin–ErbB2 heteroassociation and ErbB2 homoassociation on trastuzumab sensitive N87 and SK‐BR‐3 cells, while modest positive correlation was found between β1‐integrin–ErbB2 and ErbB2–CD44 heteroassociation on trastuzumab resistant MKN‐7 cells. The FRET efficiency values of β1‐integrin–ErbB2 heteroassociation were markedly higher at the focal adhesion regions on attached cells than those measured by flow cytometry on detached cells. In conclusion, we implemented an experimental set‐up termed two‐sided FRET for correlating two pairwise interactions of three arbitrarily chosen molecular species. On the basis of our results, we assume that the homoassociation state of ErbB2 is dynamically modulated by its interaction with β1‐integrins.

Molecular interactions of ErbB1 (EGFR) and integrin-β1 in astrocytoma frozen sections predict clinical outcome and correlate with Akt-mediated in vitro radioresistance.

INTRODUCTION Treatment of astrocytoma is frequently hampered by radioresistance of the tumor. In addition to overexpression of ErbB1/EGFR, functional crosstalk between receptor tyrosine kinases and cell adhesion molecules may also contribute to therapy resistance. METHODS Acceptor photobleaching FRET was implemented on frozen sections of clinical astrocytoma to check the role of ErbB1-integrin-β1 interaction. U251 glioma subclones were obtained by introducing extra CHR7 material or the ErbB1 gene to test the relevance and mechanism of this interaction in vitro. RESULTS Grade IV tumors showed higher ErbB1 and integrin-β1 expression and greater ErbB1-integrin-β1 heteroassociation than did grade II tumors. Of these, the extent of molecular association was a single determinant of tumor grade and prognosis in stepwise logistic regression. In vitro, integrin-β1 was upregulated, and radiosensitivity was diminished by ectopic ErbB1 expression. Great excess of ErbB1 provided colony forming advantage over medium excess but did not yield better radiation resistance or faster proliferation and decreased to medium level over time, whereas integrin-β1 levels remained elevated and defined the extent of radioresistance. Increased expression of ErbB1 and integrin-β1 was paralleled by decreasing ErbB1 homoassociation and increasing ErbB1-integrin-β1 heteroassociation. Microscopic two-sided FRET revealed that pixels with higher ErbB1-integrin-β1 heteroassociation exhibited lowed ErbB1 homoassociation, indicating competition for association partners among these molecules. Boosted Akt phosphorylation response to EGF accompanied this shift toward heteroassociation, and the consequentially increased radioresistance could be reverted by inhibiting PI3K. CONCLUSION The clinically relevant ErbB1-integrin-β1 heteroassociation may be used as a target of both predictive diagnostics and molecular therapy.

Expression of invasion-related extracellular matrix molecules in human glioblastoma versus intracerebral lung adenocarcinoma metastasis.

Tumor cell invasion into the surrounding brain tissue is mainly responsible for the failure of radical surgical resection, with tumor recurrence in the form of microdisseminated disease. Extracellular matrix (ECM)-related molecules and their receptors predominantly participate in the invasion process, including cell adhesion to the surrounding microenvironment and cell migration. The extent of infiltration of the healthy brain by malignant tumors strongly depends on the tumor cell type. Malignant gliomas show much more intensive peritumoral invasion than do metastatic tumors. In this study, the mRNA expression of 30 invasion-related molecules (twenty-one ECM components, two related receptors, and seven ECM-related enzymes) was investigated by quantitative reverse transcriptase-polymerase chain reaction. Fresh frozen human tissue samples from glioblastoma (GBM), intracerebral lung adenocarcinoma metastasis, and normal brain were evaluated. Significant differences were established for 24 of the 30 molecules. To confirm our results at the protein level, immunohistochemical analysis of seven molecules was performed (agrin, neurocan, syndecan, versican, matrix metalloproteinase 2 [MMP-2], MMP-9, and hyaluronan). Determining the differences in the levels of invasion-related molecules for tumors of different origins can help to identify the exact molecular mechanisms that facilitate peritumoral infiltration by glioblastoma cells. These results should allow the selection of target molecules for potential chemotherapeutic agents directed against highly invasive malignant gliomas.

[Expression pattern of invasion-related molecules in brain tumors of different origin].

Tumor cell invasion into the surrounding brain tissue is mainly responsible for the failure of radical surgical resection and successful treatment, with tumor recurrence as microdisseminated disease. Epidermal growth factor receptors (EGFRs), integrins and their ligands in the extracellular matrix (ECM) predominantly participate in the invasion process, including the cell adhesion to the surrounding microenvironment and cell migration. The extent of infiltration of the surrounding brain tissue by malignant tumors strongly depends on the tumor cell type. Malignant gliomas show much more intensive peritumoral invasion than do metastatic tumors. In this study, the mRNA expression of 29 invasion-related molecules (18 cell membrane receptors or receptor subunits (EGFRs and integrins) and 11 ECM components: collagens, laminins and fibronectin) was investigated by quantitative reverse transcriptase-polymerase chain reaction. Fresh frozen human tissue samples from glioblastoma (GBM) and intracerebral bronchial adenocarcinoma metastases (five pieces from each) were evaluated. Significant differences were established in six of the 29 molecules (ErbB1, 2, 3, integrins alpha3, 7 and beta1). To confirm our results at the protein level, immunohistochemical analysis of nine molecules was performed. The staining intensity differed definitely in the case of ErbB1, 2 and integrins alpha3 and beta1. Determining the differences in invasion-related molecules in tumors of different origin can help identify the exact molecular mechanisms that facilitate peritumoral infiltration by glioblastoma cells. These results should allow the selection of target molecules for potential chemotherapeutic agents directed against highly invasive malignant gliomas.

Különbözo eredetu malignus agydaganatok invazivitá sának panelszeru vizsgálata

Tumor cell invasion into the surrounding brain tissue is mainly responsible for the failure of radical surgical resection and successful treatment, with tumor recurrence as microdisseminated disease. Epidermal growth factor receptors (EGFRs), integrins and their ligands in the extracellular matrix (ECM) predominantly participate in the invasion process, including the cell adhesion to the surrounding microenvironment and cell migration. The extent of infiltration of the surrounding brain tissue by malignant tumors strongly depends on the tumor cell type. Malignant gliomas show much more intensive peritumoral invasion than do metastatic tumors. In this study, the mRNA expression of 29 invasion-related molecules (18 cell membrane receptors or receptor subunits (EGFRs and integrins) and 11 ECM components: collagens, laminins and fibronectin) was investigated by quantitative reverse transcriptase-polymerase chain reaction. Fresh frozen human tissue samples from glioblastoma (GBM) and intracerebral bronchial adenocarcinoma metastases (five pieces from each) were evaluated. Significant differences were established in six of the 29 molecules (ErbB1, 2, 3, integrins alpha3, 7 and beta1). To confirm our results at the protein level, immunohistochemical analysis of nine molecules was performed. The staining intensity differed definitely in the case of ErbB1, 2 and integrins alpha3 and beta1. Determining the differences in invasion-related molecules in tumors of different origin can help identify the exact molecular mechanisms that facilitate peritumoral infiltration by glioblastoma cells. These results should allow the selection of target molecules for potential chemotherapeutic agents directed against highly invasive malignant gliomas.

Különböző eredetű malignus agydaganatok invazivitásának panelszerű vizsgálata. Expression pattern of invasion-related molecules in cerebral tumors of different origin

Tumor cell invasion into the surrounding brain tissue is mainly responsible for the failure of radical surgical resection and successful treatment, with tumor recurrence as microdisseminated disease. Epidermal growth factor receptors (EGFRs), integrins and their ligands in the extracellular matrix (ECM) predominantly participate in the invasion process, including the cell adhesion to the surrounding microenvironment and cell migration. The extent of infiltration of the surrounding brain tissue by malignant tumors strongly depends on the tumor cell type. Malignant gliomas show much more intensive peritumoral invasion than do metastatic tumors. In this study, the mRNA expression of 29 invasion-related molecules (18 cell membrane receptors or receptor subunits (EGFRs and integrins) and 11 ECM components: collagens, laminins and fibronectin) was investigated by quantitative reverse transcriptase-polymerase chain reaction. Fresh frozen human tissue samples from glioblastoma (GBM) and intracerebral bronchial adenocarcinoma metastases (five pieces from each) were evaluated. Significant differences were established in six of the 29 molecules (ErbB1, 2, 3, integrins alpha3, 7 and beta1). To confirm our results at the protein level, immunohistochemical analysis of nine molecules was performed. The staining intensity differed definitely in the case of ErbB1, 2 and integrins alpha3 and beta1. Determining the differences in invasion-related molecules in tumors of different origin can help identify the exact molecular mechanisms that facilitate peritumoral infiltration by glioblastoma cells. These results should allow the selection of target molecules for potential chemotherapeutic agents directed against highly invasive malignant gliomas.

Significance of Epidermal Growth Factor Receptor in the Radiation Resistance of Glioblastoma Tumors

In the United States, a dramatically increased incidence and mortality of brain tumors have been observed over the past decades. Of the ∼44 thousand new cases of primary malignant and benign brain tumors diagnosed per year, high grade astrocytomas or multiform glioblastomas show particularly bad prognosis in spite of therapeutic developments. Current management of multiform glioblastoma includes the most extensive surgical resection possible, followed by adjuvant radio‐ and chemotherapy. However, treatment is frequently hampered by decreased radiosensitivity of the tumor. Recent studies revealed that subpopulations of glioblastoma cells show amplified checkpoint activation of the cell cycle upon ionizing radiation, which induces overactivation of DNA repair processes and leads to maintained proliferation rate as well as clinically observed radioresistance and recurrence of the tumor over time. In addition, overexpression of some transmembrane receptors has also been implicated in radioresistance. However, the role of the overexpressed proteins can only be interpreted reliably if their multi‐faceted molecular interactions are properly characterized. Thus, based on recent evidence for the functional crosstalk between certain cell adhesion molecules and receptor tyrosine kinases, we have examined the molecular interactions of the receptor tyrosine kinase EGFR and the cell adhesion molecule β1‐integrin using flow cytometric and microscopic fluorescence resosnance energy transfer (FRET) measurements on two cellular model systems showing similar expression patterns to low and high grade astrocytomas. On the one hand, U251 glioblastoma clones established by introducing varying amounts of extra chromosome 7 into the cells, and on the other hand stable, high and low EGFR expressing transfenctant U251 NCI sublines were investigated. The results revealed that increased EGFR and β1‐integrin expression levels correlate with stronger EGFR—β1‐integrin heteroassociation, while concurrently the EGFR homoassociation is decreased, suggesting that β1‐integrins may dynamically modulate the homoassociation state of EGFR receptors. This functional relationship may play an important role in decreasing radiosensitivity and tumor progression, especially since the EGFR—β1‐integrin molecular interaction appears to promote radioresistance via the Akt pathway.In the United States, a dramatically increased incidence and mortality of brain tumors have been observed over the past decades. Of the ∼44 thousand new cases of primary malignant and benign brain tumors diagnosed per year, high grade astrocytomas or multiform glioblastomas show particularly bad prognosis in spite of therapeutic developments. Current management of multiform glioblastoma includes the most extensive surgical resection possible, followed by adjuvant radio‐ and chemotherapy. However, treatment is frequently hampered by decreased radiosensitivity of the tumor. Recent studies revealed that subpopulations of glioblastoma cells show amplified checkpoint activation of the cell cycle upon ionizing radiation, which induces overactivation of DNA repair processes and leads to maintained proliferation rate as well as clinically observed radioresistance and recurrence of the tumor over time. In addition, overexpression of some transmembrane receptors has also been implicated in radioresistance. However,...