Chalcone JAI-51 improves efficacy of synchrotron microbeam radiation therapy of brain tumors.

International audienceMicrobeam radiation therapy (MRT), a preclinical form of radiosurgery, uses spatially fractionated micrometre-wide synchrotron-generated X-ray beams. As MRT alone is predominantly palliative for animal tumors, the effects of the combination of MRT and a newly synthesized chemotherapeutic agent JAI-51 on 9L gliosarcomas have been evaluated. Fourteen days (D14) after implantation (D0), intracerebral 9LGS-bearing rats received either MRT, JAI-51 or both treatments. JAI-51, alone or immediately after MRT, was administered three times per week. Animals were kept up to ∼20 weeks after irradiation or sacrificed at D16 or D28 after treatment for cell cycle analysis. MRT plus JAI-51 increased significantly the lifespan compared with MRT alone (p = 0.0367). JAI-51 treatment alone had no effect on rat survival. MRT alone or associated with JAI-51 induced a cell cycle blockade in G2/M (p 8c). The combination of MRT and JAI-51 increases the survival of 9LGS-bearing rats by inducing endoreduplication of DNA and tumor cell death; further, it slowed the onset of tumor growth resumption two weeks after treatment

Characterization of a B16-F10 melanoma model locally implanted into the ear pinnae of C57BL/6 mice

<div><p>The common experimental use of B16-F10 melanoma cells focuses on exploring their metastatic potential following intravenous injection into mice. In this study, B16-F10 cells are used to develop a primary tumor model by implanting them directly into the ears of C57BL/6J mice. The model represents a reproducible and easily traceable tool for local tumor growth and for making additional <i>in vivo</i> observations, due to the localization of the tumors. This model is relatively simple and involves (i) surgical opening of the ear skin, (ii) removal of a square-piece of cartilage followed by (iii) the implantation of tumor cells with fibrin gel. The remodeling of the fibrin gel within the cartilage chamber, accompanying tumor proliferation, results in the formation of blood vessels, lymphatics and tissue matrix that can be readily distinguished from the pre-existing skin structures. Moreover, this method avoids the injection-enforced artificial spread of cells into the pre-existing lymphatic vessels. The tumors have a highly reproducible exponential growth pattern with a tumor doubling time of around 1.8 days, reaching an average volume of 85mm³ 16 days after implantation. The melanomas are densely cellular with proliferative indices of between 60 and 80%. The induced angiogenesis and lymphangiogenesis resulted in the development of well-vascularized tumors. Different populations of immunologically active cells were also present in the tumor; the population of macrophages decreases with time while the population of T cells remained quasi constant. The B16-F10 tumors in the ear frequently metastasized to the cervical lymph nodes, reaching an incidence of 75% by day 16. This newly introduced B16-F10 melanoma model in the ear is a powerful tool that provides a new opportunity to study the local tumor growth and metastasis, the associated angiogenesis, lymphangiogenesis and tumor immune responses. It could potentially be used to test different treatment strategies.</p></div

Activation of TRPV2 and BKCa channels by the LL-37 enantiomers stimulates calcium entry and migration of cancer cells.

International audienceExpression of the antimicrobial peptide hCAP18/LL-37 is associated to malignancy in various cancer forms, stimulating cell migration and metastasis. We report that LL-37 induces migration of three cancer cell lines by activating the TRPV2 calcium-permeable channel and recruiting it to pseudopodia through activation of the PI3K/AKT pathway. Ca2+ entry through TRPV2 cooperated with a K+ efflux through the BKCa channel. In a panel of human breast tumors, the expression of TRPV2 and LL-37 was found to be positively correlated. The D-enantiomer of LL-37 showed identical effects as the L-peptide, suggesting that no binding to a specific receptor was involved. LL-37 attached to caveolae and pseudopodia membranes and decreased membrane fluidity, suggesting that a modification of the physical properties of the lipid membrane bilayer was the underlying mechanism of its effects

High-Precision Radiosurgical Dose Delivery by Interlaced Microbeam Arrays of High-Flux Low-Energy Synchrotron X-Rays

Microbeam Radiation Therapy (MRT) is a preclinical form of radiosurgery dedicated to brain tumor treatment. It uses micrometer-wide synchrotron-generated X-ray beams on the basis of spatial beam fractionation. Due to the radioresistance of normal brain vasculature to MRT, a continuous blood supply can be maintained which would in part explain the surprising tolerance of normal tissues to very high radiation doses (hundreds of Gy). Based on this well described normal tissue sparing effect of microplanar beams, we developed a new irradiation geometry which allows the delivery of a high uniform dose deposition at a given brain target whereas surrounding normal tissues are irradiated by well tolerated parallel microbeams only. Normal rat brains were exposed to 4 focally interlaced arrays of 10 microplanar beams (52 µm wide, spaced 200 µm on-center, 50 to 350 keV in energy range), targeted from 4 different ports, with a peak entrance dose of 200Gy each, to deliver an homogenous dose to a target volume of 7 mm3 in the caudate nucleus. Magnetic resonance imaging follow-up of rats showed a highly localized increase in blood vessel permeability, starting 1 week after irradiation. Contrast agent diffusion was confined to the target volume and was still observed 1 month after irradiation, along with histopathological changes, including damaged blood vessels. No changes in vessel permeability were detected in the normal brain tissue surrounding the target. The interlacing radiation-induced reduction of spontaneous seizures of epileptic rats illustrated the potential pre-clinical applications of this new irradiation geometry. Finally, Monte Carlo simulations performed on a human-sized head phantom suggested that synchrotron photons can be used for human radiosurgical applications. Our data show that interlaced microbeam irradiation allows a high homogeneous dose deposition in a brain target and leads to a confined tissue necrosis while sparing surrounding tissues. The use of synchrotron-generated X-rays enables delivery of high doses for destruction of small focal regions in human brains, with sharper dose fall-offs than those described in any other conventional radiation therapy

Metabolism

Background: Cardiovascular disease is the leading cause of deaths in nonalcoholic steatohepatitis (NASH) patients. Mouse models, while widely used for drug development, do not fully replicate human NASH nor integrate the associated cardiac dysfunction, i.e. heart failure with preserved ejection fraction (HFpEF). To overcome these limitations, we established a nutritional hamster model developing both NASH and HFpEF. We then evaluated the effects of the dual peroxisome proliferator activated receptor alpha/delta agonist elafibranor developed for the treatment of NASH patients. Methods: Male Golden Syrian hamsters were fed for 10 to 20 weeks with a free choice diet, which presents hamsters with a choice between control chow diet with normal drinking water or a high fat/high cholesterol diet with 10% fructose enriched drinking water. Biochemistry, histology and echocardiography analysis were performed to characterize NASH and HFpEF. Once the model was validated, elafibranor was evaluated at 15 mg/kg/day orally QD for 5 weeks. Results: Hamsters fed a free choice diet for up to 20 weeks developed NASH, including hepatocyte ballooning (as confirmed with cytokeratin-18 immunostaining), bridging fibrosis, and a severe diastolic dysfunction with restrictive profile, but preserved ejection fraction. Elafibranor resolved NASH, with significant reduction in ballooning and fibrosis scores, and improved diastolic dysfunction with significant reduction in E/A and E/E' ratios. Conclusion: Our data demonstrate that the free choice diet induced NASH hamster model replicates the human phenotype and will be useful for validating novel drug candidates for the treatment of NASH and associated HfpEF

The James Webb Space Telescope Mission

Twenty-six years ago a small committee report, building on earlier studies, expounded a compelling and poetic vision for the future of astronomy, calling for an infrared-optimized space telescope with an aperture of at least $4m$. With the support of their governments in the US, Europe, and Canada, 20,000 people realized that vision as the $6.5m$ James Webb Space Telescope. A generation of astronomers will celebrate their accomplishments for the life of the mission, potentially as long as 20 years, and beyond. This report and the scientific discoveries that follow are extended thank-you notes to the 20,000 team members. The telescope is working perfectly, with much better image quality than expected. In this and accompanying papers, we give a brief history, describe the observatory, outline its objectives and current observing program, and discuss the inventions and people who made it possible. We cite detailed reports on the design and the measured performance on orbit.Comment: Accepted by PASP for the special issue on The James Webb Space Telescope Overview, 29 pages, 4 figure

differential response of healthy and tumoral tissu after microbeam radiation therapy

La radiothérapie par microfaisceaux (MRT) synchrotron est une méthode de radiothérapie alternative pour les tumeurs cérébrales, qui présente l'avantage unique de pouvoir déposer de très hautes doses d'irradiation (plusieurs 100aines de Gy) au niveau de la masse tumorale. En effet, le fractionnement spatial des rayons X en microfaisceaux parallèles de quelques dizaines de micromètres s'est montré efficace dans le traitement des tumeurs cérébrales du rongeur tout en préservant le tissu cérébral péritumoral. Pour autant, son mode d'action sur le plan biologique n'est qu'en partie connu. Si l'effet différentiel de cette irradiation sur les vaisseaux sains et tumoraux a pu être démontré ces dernières années, il ne peut expliquer à lui seul l'efficacité de la MRT. Dans ce travail, nous avons établi une description de la réponse transcriptomique précoce des tissus sains et tumoraux (gliosarcome 9L) à la MRT et les fonctions biologiques et voies de signalisation associées. Ces résultats constituent une base de données interrogeable à partir d'hypothèses précises. Cette base a ainsi permis d'identifier des transcrits impliqués dans la réponse de la tumeur à la MRT et dont l'inhibition n'interfèrerait pas avec la réparation des tissus sains : nous avons proposé 3 cibles potentielles qui permettraient d'augmenter l'index thérapeutique de la MRT. (i) L'inhibition radio-induite d'un groupe de 13 gènes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe et Cenpf), participerait au contrôle tumoral précoce après MRT par la perturbation de la division cellulaire et pourrait être amplifié pour prolonger l'inhibition de la croissance tumorale. (ii) La mise à profit de l'activation du promoteur de Clecsf6 au sein des tumeurs irradiées permettrait la surexpression locale, via les monocytes modifiés et infiltrés, de protéine d'intérêt thérapeutique. (iii) Areg (codant pour l'Amphiréguline) est surexprimé au sein du tissu tumoral après MRT et son implication connue dans la chimio/radiorésistance nous conduit à considérer que son inhibition pourrait être une stratégie de renforcement des effets de la MRT. Par ailleurs, nous avons montré que la MRT engendrait de meilleurs résultats sur le contrôle tumoral et la survie animale qu'une irradiation synchrotron en champ plein (avec une dose équivalente à la vallée MRT). Cependant, aucune différence transcriptomique ne pouvant soutenir cet effet n'a pu être mis en évidence.Synchrotron Microbeam Radiation Therapy (MRT) is a novel form of radiosurgery of brain tumors which allows high dose deposition (few hundreds of Gy) in pathologic tissues. The spatial fractionation of the incident beam into arrays of near-parallel microbeams has shown efficiency on brain tumors implanted in rodents while sparing normal tissues. The preferential effects observed on tumor vessels could not entirely explain the efficiency of MRT and other biological mechanisms might be involved in tumor control. In this work, we described the early whole transcriptomic responses of normal and tumoral (9L gliosarcoma) tissues to MRT and the associated biofunctions and pathways. This provides a questionable data base which can be used by the whole MRT community. This base allows to identify transcripts involved in tumor response to MRT and which inhibition would have no consequence in healthy tissue repair. We identified 3 relevant targets which might increase the therapeutic index of MRT. (i) The radio-induced inhibition of a cluster of 13 genes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe and Cenpf) may be involved in tumor control after MRT through the deregulation of cell division and could be amplified to continue the tumor growth inhibition. (ii) We might benefit from the activation of the Clecsf6 promoter in irradiated tumors by delivering, via modified and injected monocytes, some therapeutic proteins. (iii) Finally, Areg (encoding for Amphiregulin) is overexpressed in tumors after MRT and its involvement described in chimio/radioresistance enable to consider that its inhibition might help in tumor control after irradiation. We also showed that MRT induces a greater tumor control and survival rates compared with similar broad beam irradiations but no differences in transcriptomic responses have been highlighted

Réponse transcriptomique des tissus cérébraux sains et tumoraux à la radiothérapie par microfaisceaux synchrotron

Synchrotron Microbeam Radiation Therapy (MRT) is a novel form of radiosurgery of brain tumors which allows high dose deposition (few hundreds of Gy) in pathologic tissues. The spatial fractionation of the incident beam into arrays of near-parallel microbeams has shown efficiency on brain tumors implanted in rodents while sparing normal tissues. The preferential effects observed on tumor vessels could not entirely explain the efficiency of MRT and other biological mechanisms might be involved in tumor control. In this work, we described the early whole transcriptomic responses of normal and tumoral (9L gliosarcoma) tissues to MRT and the associated biofunctions and pathways. This provides a questionable data base which can be used by the whole MRT community. This base allows to identify transcripts involved in tumor response to MRT and which inhibition would have no consequence in healthy tissue repair. We identified 3 relevant targets which might increase the therapeutic index of MRT. (i) The radio-induced inhibition of a cluster of 13 genes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe and Cenpf) may be involved in tumor control after MRT through the deregulation of cell division and could be amplified to continue the tumor growth inhibition. (ii) We might benefit from the activation of the Clecsf6 promoter in irradiated tumors by delivering, via modified and injected monocytes, some therapeutic proteins. (iii) Finally, Areg (encoding for Amphiregulin) is overexpressed in tumors after MRT and its involvement described in chimio/radioresistance enable to consider that its inhibition might help in tumor control after irradiation. We also showed that MRT induces a greater tumor control and survival rates compared with similar broad beam irradiations but no differences in transcriptomic responses have been highlighted.La radiothérapie par microfaisceaux (MRT) synchrotron est une méthode de radiothérapie alternative pour les tumeurs cérébrales, qui présente l'avantage unique de pouvoir déposer de très hautes doses d'irradiation (plusieurs 100aines de Gy) au niveau de la masse tumorale. En effet, le fractionnement spatial des rayons X en microfaisceaux parallèles de quelques dizaines de micromètres s'est montré efficace dans le traitement des tumeurs cérébrales du rongeur tout en préservant le tissu cérébral péritumoral. Pour autant, son mode d'action sur le plan biologique n'est qu'en partie connu. Si l'effet différentiel de cette irradiation sur les vaisseaux sains et tumoraux a pu être démontré ces dernières années, il ne peut expliquer à lui seul l'efficacité de la MRT. Dans ce travail, nous avons établi une description de la réponse transcriptomique précoce des tissus sains et tumoraux (gliosarcome 9L) à la MRT et les fonctions biologiques et voies de signalisation associées. Ces résultats constituent une base de données interrogeable à partir d'hypothèses précises. Cette base a ainsi permis d'identifier des transcrits impliqués dans la réponse de la tumeur à la MRT et dont l'inhibition n'interfèrerait pas avec la réparation des tissus sains : nous avons proposé 3 cibles potentielles qui permettraient d'augmenter l'index thérapeutique de la MRT. (i) L'inhibition radio-induite d'un groupe de 13 gènes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe et Cenpf), participerait au contrôle tumoral précoce après MRT par la perturbation de la division cellulaire et pourrait être amplifié pour prolonger l'inhibition de la croissance tumorale. (ii) La mise à profit de l'activation du promoteur de Clecsf6 au sein des tumeurs irradiées permettrait la surexpression locale, via les monocytes modifiés et infiltrés, de protéine d'intérêt thérapeutique. (iii) Areg (codant pour l'Amphiréguline) est surexprimé au sein du tissu tumoral après MRT et son implication connue dans la chimio/radiorésistance nous conduit à considérer que son inhibition pourrait être une stratégie de renforcement des effets de la MRT. Par ailleurs, nous avons montré que la MRT engendrait de meilleurs résultats sur le contrôle tumoral et la survie animale qu'une irradiation synchrotron en champ plein (avec une dose équivalente à la vallée MRT). Cependant, aucune différence transcriptomique ne pouvant soutenir cet effet n'a pu être mis en évidence

Réponse transcriptomique des tissus cérébraux sains et tumoraux à la radiothérapie par microfaisceaux synchrotron

La radiothérapie par microfaisceaux (MRT) synchrotron est une méthode de radiothérapie alternative pour les tumeurs cérébrales, qui présente l'avantage unique de pouvoir déposer de très hautes doses d'irradiation (plusieurs 100aines de Gy) au niveau de la masse tumorale. En effet, le fractionnement spatial des rayons X en microfaisceaux parallèles de quelques dizaines de micromètres s'est montré efficace dans le traitement des tumeurs cérébrales du rongeur tout en préservant le tissu cérébral péritumoral. Pour autant, son mode d'action sur le plan biologique n'est qu'en partie connu. Si l'effet différentiel de cette irradiation sur les vaisseaux sains et tumoraux a pu être démontré ces dernières années, il ne peut expliquer à lui seul l'efficacité de la MRT. Dans ce travail, nous avons établi une description de la réponse transcriptomique précoce des tissus sains et tumoraux (gliosarcome 9L) à la MRT et les fonctions biologiques et voies de signalisation associées. Ces résultats constituent une base de données interrogeable à partir d'hypothèses précises. Cette base a ainsi permis d'identifier des transcrits impliqués dans la réponse de la tumeur à la MRT et dont l'inhibition n'interfèrerait pas avec la réparation des tissus sains : nous avons proposé 3 cibles potentielles qui permettraient d'augmenter l'index thérapeutique de la MRT. (i) L'inhibition radio-induite d'un groupe de 13 gènes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe et Cenpf), participerait au contrôle tumoral précoce après MRT par la perturbation de la division cellulaire et pourrait être amplifié pour prolonger l'inhibition de la croissance tumorale. (ii) La mise à profit de l'activation du promoteur de Clecsf6 au sein des tumeurs irradiées permettrait la surexpression locale, via les monocytes modifiés et infiltrés, de protéine d'intérêt thérapeutique. (iii) Areg (codant pour l'Amphiréguline) est surexprimé au sein du tissu tumoral après MRT et son implication connue dans la chimio/radiorésistance nous conduit à considérer que son inhibition pourrait être une stratégie de renforcement des effets de la MRT. Par ailleurs, nous avons montré que la MRT engendrait de meilleurs résultats sur le contrôle tumoral et la survie animale qu'une irradiation synchrotron en champ plein (avec une dose équivalente à la vallée MRT). Cependant, aucune différence transcriptomique ne pouvant soutenir cet effet n'a pu être mis en évidence.Synchrotron Microbeam Radiation Therapy (MRT) is a novel form of radiosurgery of brain tumors which allows high dose deposition (few hundreds of Gy) in pathologic tissues. The spatial fractionation of the incident beam into arrays of near-parallel microbeams has shown efficiency on brain tumors implanted in rodents while sparing normal tissues. The preferential effects observed on tumor vessels could not entirely explain the efficiency of MRT and other biological mechanisms might be involved in tumor control. In this work, we described the early whole transcriptomic responses of normal and tumoral (9L gliosarcoma) tissues to MRT and the associated biofunctions and pathways. This provides a questionable data base which can be used by the whole MRT community. This base allows to identify transcripts involved in tumor response to MRT and which inhibition would have no consequence in healthy tissue repair. We identified 3 relevant targets which might increase the therapeutic index of MRT. (i) The radio-induced inhibition of a cluster of 13 genes (Plk1, Cdc20, Ccnb1, Pttg1, Bub1, Dlgap5, Cenpf, Kif20a, Traf4af1, Depdc1b, Mxd3, Cenpe and Cenpf) may be involved in tumor control after MRT through the deregulation of cell division and could be amplified to continue the tumor growth inhibition. (ii) We might benefit from the activation of the Clecsf6 promoter in irradiated tumors by delivering, via modified and injected monocytes, some therapeutic proteins. (iii) Finally, Areg (encoding for Amphiregulin) is overexpressed in tumors after MRT and its involvement described in chimio/radioresistance enable to consider that its inhibition might help in tumor control after irradiation. We also showed that MRT induces a greater tumor control and survival rates compared with similar broad beam irradiations but no differences in transcriptomic responses have been highlighted.SAVOIE-SCD - Bib.électronique (730659901) / SudocGRENOBLE1/INP-Bib.électronique (384210012) / SudocGRENOBLE2/3-Bib.électronique (384219901) / SudocSudocFranceF

Effects of microbeam radiation therapy on normal and tumoral blood vessels

Microbeam radiation therapy (MRT) is a new form of preclinical radiotherapy using quasi-parallel arrays of synchrotron X-ray microbeams. While the deposition of several hundred Grays in the microbeam paths, the normal brain tissues presents a high tolerance which is accompanied by the permanence of apparently normal vessels. Conversely, the efficiency of MRT on tumor growth control is thought to be related to a preferential damaging of tumor blood vessels. The high resistance of the healthy vascular network was demonstrated in different animal models by in vivo biphoton microscopy, magnetic resonance imaging, and histological studies. While a transient increase in permeability was shown, the structure of the vessels remained intact. The use of a chick chorioallantoic membrane at different stages of development showed that the damages induced by microbeams depend on vessel maturation. In vivo and ultrastructural observations showed negligible effects of microbeams on the mature vasculature at late stages of development; nevertheless a complete destruction of the immature capillary plexus was found in the microbeam paths. The use of MRT in rodent models revealed a preferential effect on tumor vessels. Although no major modification was observed in the vasculature of normal brain tissue, tumors showed a denudation of capillaries accompanied by transient increased permeability followed by reduced tumor perfusion and finally, a decrease in number of tumor vessels. Thus, MRT is a very promising treatment strategy with pronounced tumor control effects most likely based on the anti-vascular effects of MRT