Agnès Leroux

Photodynamic therapy with intratumoral administration of Lipid-Based mTHPC in a model of breast cancer recurrence

Generalized skin sensitization is a main drawback of photodynamic therapy with systemic administration of photosensitizers. We have evaluated the potential use of an intratumoral injection of a liposomal formulation of mTHPC (Foslip) in a mouse model of local recurrence of breast cancer.

Enhanced Cell Growth Inhibition following PTEN Nonviral Gene Transfer Using Polyethylenimine and Photochemical Internalization in Endometrial Cancer Cells

PTEN is a tumor suppressor gene mapped on chromosome 10q23.3 and encodes a dual specificity phosphatase. PTEN has major implication in PI3 kinase (PI3K) signal transduction pathway and negatively controls PI3 phosphorylation. It has been reported to be implicated in cell cycle progression and cell death control through inhibition of PI3K-Akt signal transduction pathway and in the control of cell migration and spreading through its interaction with focal adhesion kinase. Somatic mutations of PTEN are frequently detected in several cancer types including brain, prostate and endometrium with more than 30% of tumor tissue specimens bearing PTEN mutations and/or deletions. Because of its high frequency of mutations and its important function as tumor suppressor gene, PTEN is a good candidate for gene therapy. Inducible expression of PTEN has been also reported. In cancer cells bearing PTEN abnormalities, the reversion of PTEN function by external gene transfer becomes more and more investigated in cancer treatment research. Several technologies including the photochemical internalization (PCI) and aiming at improving the transfection efficiency have been reported. PCI is an innovative procedure based on light-induced delivery of macromolecules such as DNA, proteins and other therapeutic molecules from endocytic vesicles to the cytosol of target cells. PCI has been reported to enhance the gene delivery potential of viral and nonviral vectors. The present study was designed to evaluate the influence of photochemical internalization on polyethylenimine (PEI)-mediated PTEN gene transfer and its effects on the cellular viability in Ishikawa endometrial cancer cells bearing PTEN abnormalities. PCI was found to significantly (P < 0.01) enhance PTEN mRNA expression (4.2 fold increase). Subsequently, following PEI-mediated PTEN gene transfer, the restoration of the PTEN protein expression was observed. As a consequence, significant cell growth inhibition (44%) was observed in Ishikawa endometrial cells. Using PCI for PEI-mediated PTEN gene transfer was found to further enhance PTEN mRNA and protein expression as well as PTEN-related cell growth inhibition reaching 89%.

Detection of BRAF Mutations Using a Fully Automated Platform and Comparison with High Resolution Melting, Real-Time Allele Specific Amplification, Immunohistochemistry and Next Generation Sequencing Assays, for Patients with Metastatic Melanoma

Background Metastatic melanoma is a severe disease with one of the highest mortality rate in skin diseases. Overall survival has significantly improved with immunotherapy and targeted therapies. Kinase inhibitors targeting BRAF V600 showed promising results. BRAF genotyping is mandatory for the prescription of anti-BRAF therapies. Methods Fifty-nine formalin-fixed paraffin-embedded melanoma samples were assessed using High-Resolution-Melting (HRM) PCR, Real-time allele-specific amplification (RT-ASA) PCR, Next generation sequencing (NGS), immunohistochemistry (IHC) and the fully-automated molecular diagnostics platform IdyllaTM. Sensitivity, specificity, positive predictive value and negative predictive value were calculated using NGS as the reference standard to compare the different assays. Results BRAF mutations were found in 28(47.5%), 29(49.2%), 31(52.5%), 29(49.2%) and 27(45.8%) samples with HRM, RT-ASA, NGS, IdyllaTM and IHC respectively. Twenty-six (81.2%) samples were found bearing a c.1799T>A (p.Val600Glu) mutation, three (9.4%) with a c.1798_1799delinsAA (p.Val600Lys) mutation and one with c.1789_1790delinsTC (p.Leu597Ser) mutation. Two samples were found bearing complex mutations. Conclusions HRM appears the less sensitive assay for the detection of BRAF V600 mutations. The RT-ASA, IdyllaTM and IHC assays are suitable for routine molecular diagnostics aiming at the prescription of anti-BRAF therapies. IdyllaTM assay is fully-automated and requires less than 2 minutes for samples preparation and is the fastest of the tested assays.

Optimization of routine KRAS mutation PCR-based testing procedure for rational individualized first-line-targeted therapy selection in metastatic colorectal cancer

KRAS mutation detection represents a crucial issue in metastatic colorectal cancer (mCRC). The optimization of KRAS mutation detection delay enabling rational prescription of first‐line treatment in mCRC including anti‐EGFR‐targeted therapy requires robust and rapid molecular biology techniques. Routine analysis of mutations in codons 12 and 13 on 674 paraffin‐embedded tissue specimens of mCRC has been performed for KRAS mutations detection using three molecular biology techniques, that is, high‐resolution melting (HRM), polymerase chain reaction restriction fragment length polymorphism (PCR‐RFLP), and allelic discrimination PCR (TaqMan PCR). Discordant cases were assessed with COBAS 4800 KRAS CE‐IVD assay. Among the 674 tumor specimens, 1.5% (10/674) had excessive DNA degradation and could not be analyzed. KRAS mutations were detected in 38.0% (256/674) of the analysable specimens (82.4% in codon 12 and 17.6% in codon 13). Among 613 specimens in whom all three techniques were used, 12 (2.0%) cases of discordance between the three techniques were observed. 83.3% (10/12) of the discordances were due to PCR‐RFLP as confirmed by COBAS 4800 retrospective analysis. The three techniques were statistically comparable (κ > 0.9; P < 0.001). From these results, optimization of the routine procedure consisted of proceeding to systematic KRAS detection using HRM and TaqMan and PCR‐RFLP in case of discordance and allowed significant decrease in delays. The results showed an excellent correlation between the three techniques. Using HRM and TaqMan warrants high‐quality and rapid‐routine KRAS mutation detection in paraffin‐embedded tumor specimens. The new procedure allowed a significant decrease in delays for reporting results, enabling rational prescription of first‐line‐targeted therapy in mCRC.

Comparison of Five Different Assays for the Detection of BRAF Mutations in Formalin-Fixed Paraffin Embedded Tissues of Patients with Metastatic Melanoma

BackgroundMetastatic or unresectable melanoma is a serious and deadly disease. Anti-BRAF and immunotherapy improved overall survival in patients with metastatic disease. Thus, BRAF genotyping is important to choose the right therapy.MethodsIn our study, we assessed and compared BRAF mutations in 59 formalin-fixed and paraffin-embedded tumor samples of patients with metastatic melanoma with next-generation sequencing (NGS), Cobas® 4800 BRAF V600 mutation test CE-IVD commercial kit, high-resolution melting PCR (HRM), multiplex real-time allele specific amplification (multiplexed RT-ASA) and immunohistochemistry (IHC).ResultsThirty-one samples were found bearing a BRAF mutation with NGS (52.5%), 28 with Cobas® test (47.5%), 28 with HRM (47.5%), 29 with multiplexed RT-ASA (49.2%) and 27 with IHC (45.8%). Based on NGS data, 26 (81.2%) were c.1799 T>A (p.Val600Glu), 3 (9.4%) were c. 1798-1799 GT>AA (p.Val600Lys), 1 was c.1789_1790 CT>TC (p.Leu597Ser) and 2 were complex mutations. Sensitivity was 90.3% for Cobas® test, 93.1% for multiplexed RT-ASA and 87.1% for IHC and HRM. Specificity was 100% for Cobas® test, IHC and multiplexed RT-ASA and 96.4% for HRM. The reference assay was NGS. Rare mutations were detected with NGS and HRM: c.1789_1790 CT>TC (p.Leu597Ser) mutation and the complex mutation c.1796 A>T; c.1797_1798 insACT (p.Thr599Thr; p.Thr599_Val600insThr). Our data suggest that multiplexed RT-ASA is the most sensitive assay but specific primers for each mutation are needed. HRM can detect all exon 15 mutations but has a lower sensitivity. Because of its specificity for Val600Glu mutation, IHC may be considered only as a screening tool and testing should be completed by a method able to detect other V600 mutations. BRAF Cobas® assay is Val600Glu-specific and has poor sensitivity for the other V600 mutations; thus, it looks important to use multiplex assays able to detect all V600 mutations because a false-negative result will deprive the patient of an important treatment option.

Preventing bladder tumor implantation with photodynamic therapy in a rat model mimicking post-fluorescence guided transurethral resection

PURPOSE Fluorescence guided transurethral resection has gained acknowledgment from the urological community and it is progressively becoming more applied. It has been shown to decrease the recurrence rate of nonmuscle invasive bladder cancer due to incomplete resection due to lack of visualization. The implantation of viable tumor cells seeded during transurethral resection is another reason for recurrence. We investigated whether applying photodynamic therapy on sensitized tumor cells would decrease the amount of viable intraluminal cells and tumor cell implantation. MATERIAL AND METHODS Two models were designed to mimic the situation after fluorescence guided transurethral resection, including partly or fully de-epithelialized bladders and circulating tumor cells loaded with protoporphyrin IX. Photodynamic therapy was performed. Controls consisted of no drug with no light, light only and drug only. Immediately after photodynamic therapy the intravesical contents were retrieved and clonogenic assays were performed on cells. Bladders were harvested 10 days after cell administration and subjected to pathological analysis. RESULTS In the photodynamic therapy and control groups tumor volume was proportional to the instilled cell load. Clonogenic assays showed that viable cells were decreased a tenth of the initial administered amount. Tumor implantation decreased to less than a fifth of control values. CONCLUSIONS Photodynamic therapy can effectively decrease the amount of viable tumor cells in the bladder lumen. This results in a significant decrease in tumor implantation. This technique could possibly be used to further decrease the recurrence rate of nonmuscle invasive bladder cancer.

Prevention of bladder tumor implantion after fluorescence-guided TUR with photodynamic therapy

The prevalence of bladder cancer is very high, due to its high recurrence rate in superficial bladder cancer (30 to 85%), which is the staging of approximately 80% of the patients at first diagnosis. Risk of recurrence and progression is associated with grade, stage, presence of concomitant carcinoma in situ, size and number of lesions, as well as time to first recurrence. Recurrences can be partly attributed to new occurrences but also to residual tumors after resection. Incomplete tumor removal has been observed in 30 to 50% of TURs, especially when dealing with T1 or poorly visible malignant or pre-malignant disease1. Fluorescence guided resection with 5 amino levulinic acid (ALA) or its hexyl ester derivative (Hexvix, has now unequivocally been demonstrated to increase detection rate and a growing number of studies indicate this has a positive impact on recurrence and progression ratesImplantation of viable tumor cells, dispersed during resection, is a third factor influencing bladder cancer recurrence. The aim of early intravesical therapy is to interfere with cell viability and thus reduce implantation risks.