Aurélie Lacroix

Microwave biosensors for identifying cancer cell aggressiveness grade

This paper illustrates the potential of microwave frequencies for biological analysis. Once penetrating inside biological cells, microwaves can interact with their intracellular content and inform on their safe or malignant state. This work demonstrates that their cancer grade (i.e. aggressiveness level) can also be identified by this way. Hence, based on permittivity measurements on three colon cancer cell lines loading RF resonators, the presented results show significant differences of electromagnetic signature in the cancer grade of analyzed cells. This sensing method appears very promising to develop new powerful tools for early cancer diagnostic.

p75 neurotrophin receptor and pro-BDNF promote cell survival and migration in clear cell renal cell carcinoma

p75NTR, a member of TNF receptor family, is the low affinity receptor common to several mature neurotrophins and the high affinity receptor for pro-neurotrophins. Brain-Derived Neurotrophic Factor (BDNF), a member of neurotrophin family has been described to play an important role in development and progression of several cancers, through its binding to a high affinity tyrosine kinase receptor B (TrkB) and/or p75NTR. However, the functions of these two receptors in renal cell carcinoma (RCC) have never been investigated. An overexpression of p75NTR, pro-BDNF, and to a lesser extent for TrkB and sortilin, was detected by immunohistochemistry in a cohort of 83 clear cell RCC tumors. p75NTR, mainly expressed in tumor tissues, was significantly associated with higher Fuhrman grade in multivariate analysis. In two derived-RCC lines, 786-O and ACHN cells, we demonstrated that pro-BDNF induced cell survival and migration, through p75NTR as provided by p75NTR RNA silencing or blocking anti-p75NTR antibody. This mechanism is independent of TrkB activation as demonstrated by k252a, a tyrosine kinase inhibitor for Trk neurotrophin receptors. Taken together, these data highlight for the first time an important role for p75NTR in renal cancer and indicate a putative novel target therapy in RCC.

TrkB-containing exosomes promote the transfer of glioblastoma aggressiveness to YKL-40-inactivated glioblastoma cells

The neurotrophin receptors are known to promote growth and proliferation of glioblastoma cells. Their functions in spreading glioblastoma cell aggressiveness to the microenvironment through exosome release from glioblastoma cells are unknown. Considering previous reports demonstrating that YKL-40 expression is associated with undifferentiated glioblastoma cancer stem cells, we used YKL-40-silenced cells to modulate the U87-MG differentiated state and their biological aggressiveness. Herein, we demonstrated a relationship between neurotrophin-receptors and YKL-40 expression in undifferentiated cells. Differential functions of cells and derived-exosomes were evidenced according to neurotrophin receptor content and differentiated cell state by comparison with control pLKO cells. YKL-40 silencing of glioblastoma cells impairs proliferation, neurosphere formation, and their ability to induce endothelial cell (HBMEC) migration. The modulation of differentiated cell state in YKL-40-silenced cells induces a decrease of TrkB, sortilin and p75NTR cellular expressions, associated with a low-aggressiveness phenotype. Interestingly, TrkB expressed in exosomes derived from control cells was undetectable in exosomes from YKL-40 -silenced cells. The transfer of TrkB-containing exosomes in YKL-40-silenced cells contributed to restore cell proliferation and promote endothelial cell activation. Interestingly, in U87 MG xenografted mice, TrkB-depleted exosomes from YKL-40-silenced cells inhibited tumor growth in vivo. These data highlight that TrkB-containing exosomes play a key role in the control of glioblastoma progression and aggressiveness. Furthermore, TrkB expression was detected in exosomes isolated from plasma of glioblastoma patients, suggesting that this receptor may be considered as a new biomarker for glioblastoma diagnosis.

Tunable frequency resonant biosensors dedicated to dielectric permittivity analysis of biological cell cytoplasm

This paper presents an improved design of resonant biosensor, dedicated to dielectric analysis on biological cells at microwave frequencies. Such sensor uses the capability of microwaves to penetrate inside biological cells in order to interact with their intracellular content. Hence, individual dielectric properties of the cell cytoplasm can be known and then used as a signature of the cell pathological state (living or dead, malignant or safe...). In this paper is introduced a continuously tunable frequency sensor prototype, able to perform an accurate dielectric analysis over at least a 1GHz bandwidth while keeping enough sensitivity to detect and analyze a single cell. As a proof of concept, permittivity measurements have been led on calibrated size polystyrene beads: achieved results show good agreement with expected permittivity values. Finally experiments on Glioblastoma cells will be presented.

Autophagy and TrkC/NT-3 signaling joined forces boost the hypoxic glioblastoma cell survival

Glioblastoma multiform (GBM), the most common and aggressive primary brain tumor, is characterized by a high degree of hypoxia and resistance to therapy because of its adaptation capacities, including autophagy and growth factors signaling. In this study, we show an efficient hypoxia-induced survival autophagy in four different GBM cell lines (U87MG, M059K, M059J and LN-18) and an activation of a particular neurotrophin signaling pathway. Indeed, the enhancement of both TrkC and NT-3 was followed by downstream p38MAPK phosphorylation, suggesting the occurrence of a survival autocrine loop. Autophagy inhibition increased the hypoxia-induced expression of TrkC and its phosphorylated form as well as the phosphorylation of p38, suggesting a complementary effect of the two processes, leading to cell survival. Alone, autophagy inhibition reduced cellular growth without inducing cell death. However, the double inhibition of autophagy and TrkC signaling was necessary to bring cells to death as shown by PARP cleavage, particularly important in hypoxia. Moreover, a very high expression of TrkC and NT-3 was found in tumor sections from GBM patients, highlighting the importance of neurotrophic signaling in GBM tumor cell survival. These data suggest that a combined treatment targeting these two pathways could be considered in order to induce the death of GBM cells.

Improved sedimentation field-flow fractionation separation channel for concentrated cellular elution

SdFFF is now commonly used for cell sorting. Nevertheless, as with many other separation methods, SdFFF Hyperlayer elution leads (1) to sample dilution resulting in cell loss which could restrict further use; and (2) to a high output flow rate impacting detector sensitivity and selectivity. In order to limit these problems, we proposed modifications of the SdFFF separation channel consisting both in downscaling and the insertion of an outlet stream splitter. This last system corresponded to a strip which divides the flow rate output into two parts, one containing concentrated cells in a reduced volume and flow rate, the other containing the excess mobile phase useless for further cell manipulation, detection and characterization. For the first time we have shown that splitter implementation and downscaling respected channel flowing and resulted in Hyperlayer elution of around 95% of cells in less than 50% of input flow rate. Improved cell sorting was demonstrated by enrichment (∼10 times) of cancer stem cells from WiDr cells with two times less quantity of injected cells.

KLRC3, a Natural Killer receptor gene, is a key factor involved in glioblastoma tumourigenesis and aggressiveness.

Glioblastoma is the most lethal brain tumour with a poor prognosis. Cancer stem cells (CSC) were proposed to be the most aggressive cells allowing brain tumour recurrence and aggressiveness. Current challenge is to determine CSC signature to characterize these cells and to develop new therapeutics. In a previous work, we achieved a screening of glycosylation‐related genes to characterize specific genes involved in CSC maintenance. Three genes named CHI3L1, KLRC3 and PRUNE2 were found overexpressed in glioblastoma undifferentiated cells (related to CSC) compared to the differentiated ones. The comparison of their roles suggest that KLRC3 gene coding for NKG2E, a protein initially identified in NK cells, is more important than both two other genes in glioblastomas aggressiveness. Indeed, KLRC3 silencing decreased self‐renewal capacity, invasion, proliferation, radioresistance and tumourigenicity of U87‐MG glioblastoma cell line. For the first time we report that KLRC3 gene expression is linked to glioblastoma aggressiveness and could be a new potential therapeutic target to attenuate glioblastoma.