Your search keyword '"Tanori, M."' showing total 9 results

1. Contribution of Genetic Background to the Radiation Risk for Cancer and Non-Cancer Diseases in Ptch1+/– Mice.

Author

De Stefano, I., Leonardi, S., Casciati, A., Pasquali, E., Giardullo, P., Antonelli, F., Novelli, F., Babini, G., Tanori, M., Tanno, B., Saran, A., Mancusoa, M., and Pazzaglia, S.

Subjects

BACKGROUND radiation, DISEASE risk factors, RADIATION tolerance, DENTATE gyrus, CRYSTALLINE lens, RADIATION exposure

Abstract

Experimental mouse studies are important to gain a comprehensive, quantitative and mechanistic understanding of the biological factors that modify individual risk of radiation-induced health effects, including age at exposure, dose, dose rate, organ/tissue specificity and genetic factors. In this study, neonatal Ptch1+/– mice bred on CD1 and C57Bl/6 background received whole-body irradiation at postnatal day 2. This time point represents a critical phase in the development of the eye lens, cerebellum and dentate gyrus (DG), when they are also particularly susceptible to radiation effects. Irradiation was performed with γ rays (60Co) at doses of 0.5, 1 and 2 Gy, delivered at 0.3 Gy/min or 0.063 Gy/min. Wild-type and mutant mice were monitored for survival, lens opacity, medulloblastoma (MB) and neurogenesis defects. We identified an inverse genetic background-driven relationship between the radiosensitivity to induction of lens opacity and MB and that to neurogenesis deficit in Ptch1+/– mutants. In fact, high incidence of radiation-induced cataract and MB were observed in Ptch1+/–/CD1 mutants that instead showed no consequence of radiation exposure on neurogenesis. On the contrary, no induction of radiogenic cataract and MB was reported in Ptch1+/–/C57Bl/6 mice that were instead susceptible to induction of neurogenesis defects. Compared to Ptch1+/–/CD1, the cerebellum of Ptch1+/–/C57Bl/6 mice showed increased radiosensitivity to apoptosis, suggesting that differences in processing radiation-induced DNA damage may underlie the opposite strain-related radiosensitivity to cancer and non-cancer pathologies. Altogether, our results showed lack of dose-rate-related effects and marked influence of genetic background on the radiosensitivity of Ptch1+/–mice, supporting a major contribution of individual sensitivity to radiation risk in the population. [ABSTRACT FROM AUTHOR]

Published

2022

2. miRNA-Signature of Irradiated Ptch1+/– Mouse Lens is Dependent on Genetic Background.

Author

Tanno, B., Babini, G., Leonardi, S., De Stefano, I., Merla, C., Novelli, F., Antonelli, F., Casciati, A., Tanori, M., Pasquali, E., Giardullo, P., Pazzaglia, S., and Mancuso, M.

Subjects

MICE, IONIZING radiation, EPITHELIAL-mesenchymal transition, TOLL-like receptors, NUCLEOTIDE sequencing

Abstract

One harmful long-term effect of ionizing radiation is cataract development. Recent studies have been focused on elucidating the mechanistic pathways involved in this pathogenesis. Since accumulating evidence has established a role of microRNAs in ocular diseases, including cataract, the goal of this work was to determine the microRNA signature of the mouse lens, at short time periods postirradiation, to understand the mechanisms related to radio-induced cataractogenesis. To evaluate the differences in the microRNA profiles, 10-week-old Patched1 heterozygous (Ptch1+/–) mice, bred onto two different genetic backgrounds (CD1 and C57Bl/6J), received whole-body 2 Gy γ-ray irradiation, and 24 h later lenses were collected. Next-generation sequencing and bioinformatics analysis revealed that genetic background markedly influenced the list of the deregulated microRNAs and the mainly predicted perturbed biological functions of 2 Gy irradiated Ptch1+/– mouse lenses. We identified a subset of microRNAs with a contra-regulated expression between strains, with a key role in regulating Toll-like receptor (TLR)-signaling pathways. Furthermore, a detailed analysis of miRNome data showed a completely different DNA damage response in mouse lenses 24 h postirradiation, mainly mediated by a marked upregulation of p53 signaling in Ptch1+/–/C57Bl/6J lenses that was not detected on a CD1 background. We propose a strict interplay between p53 and TLR signaling in Ptch1+/–/C57Bl/6J lenses shortly after irradiation that could explain both the resistance of this strain to developing lens opacities and the susceptibility of CD1 background to radiation-induced cataractogenesis through activation of epithelial-mesenchymal transition. [ABSTRACT FROM AUTHOR]

Published

2022

3. Push–pull configuration of high-power MOSFETs for generation of nanosecond pulses for electropermeabilization of cells.

Author

Davies, I. W., Merla, C., Casciati, A., Tanori, M., Zambotti, A., Mancuso, M., Bishop, J., White, M., Palego, C., Hancock, C. P., Kulpa, Krzysztof, Weinmann, Frank, Boria, Vicente E., Martín, Teresa, and Burgos, Mateo

Abstract

A power MOSFET-based push–pull configuration nanosecond-pulse generator has been designed, constructed, and characterized to permeabilize cells for biological and medical applications. The generator can deliver pulses with durations ranging from 80 ns up to 1 µ s and pulse amplitudes up to 1.4 kV. The unit has been tested for in vitro experiments on a medulloblastoma cell line. Following the exposure of cells to 100, 200, and 300 ns electric field pulses, permeabilization tests were carried out, and viability tests were conducted to verify the performance of the generator. The maximum temperature rise of the biological load was also calculated based on Joule heating energy conservation and experimental validation. Our results indicate that the developed device has good capabilities to achieve well-controlled electro-manipulation in vitro. [ABSTRACT FROM AUTHOR]

Published

2019

4. Opposite modifying effects of HR and NHEJ deficiency on cancer risk in Ptc1 heterozygous mouse cerebellum.

Author

Tanori, M, Pasquali, E, Leonardi, S, Giardullo, P, Di Majo, V, Taccioli, G, Essers, J, Kanaar, R, Mullenders, L H, Atkinson, M J, Mancuso, M, Saran, A, and Pazzaglia, S

Subjects

MEDULLOBLASTOMA, LABORATORY mice, IONIZING radiation, GENOMES, CEREBELLUM, CANCER risk factors

Abstract

Heterozygous Patched1 (Ptc1+/−) mice are prone to medulloblastoma (MB), and exposure of newborn mice to ionizing radiation dramatically increases the frequency and shortens the latency of MB. In Ptc1+/− mice, MB is characterized by loss of the normal remaining Ptc1 allele, suggesting that genome rearrangements may be key events in MB development. Recent evidence indicates that brain tumors may be linked to defects in DNA-damage repair processes, as various combinations of targeted deletions in genes controlling cell-cycle checkpoints, apoptosis and DNA repair result in MB in mice. Non-homologous end joining (NHEJ) and homologous recombination (HR) contribute to genome stability, and deficiencies in either pathway predispose to genome rearrangements. To test the role of defective HR or NHEJ in tumorigenesis, control and irradiated Ptc1+/− mice with two, one or no functional Rad54 or DNA-protein kinase catalytic subunit (DNA-PKcs) alleles were monitored for MB development. We also examined the effect of Rad54 or DNA-PKcs deletion on the processing of endogenous and radiation-induced double-strand breaks (DSBs) in neural precursors of the developing cerebellum, the cells of origin of MB. We found that, although HR and NHEJ collaborate in protecting cells from DNA damage and apoptosis, they have opposite roles in MB tumorigenesis. In fact, although Rad54 deficiency increased both spontaneous and radiation-induced MB development, DNA-PKcs disruption suppressed MB tumorigenesis. Together, our data provide the first evidence that Rad54-mediated HR in vivo is important for suppressing tumorigenesis by maintaining genomic stability. [ABSTRACT FROM AUTHOR]

Published

2011

5. Role of connexin43 and ATP in long-range bystander radiation damage and oncogenesis in vivo.

Author

Mancuso, M, Pasquali, E, Leonardi, S, Rebessi, S, Tanori, M, Giardullo, P, Borra, F, Pazzaglia, S, Naus, C C, Di Majo, V, and Saran, A

Subjects

CONNEXINS, ADENOSINE triphosphate, IONIZING radiation, CARCINOGENESIS, GENETIC toxicology, TISSUES, NERVOUS system

Abstract

Ionizing radiation is a genotoxic agent and human carcinogen. Recent work has questioned long-held dogmas by showing that cancer-associated genetic alterations occur in cells and tissues not directly exposed to radiation, questioning the robustness of the current system of radiation risk assessment. In vitro, diverse mechanisms involving secreted soluble factors, gap junction intercellular communication (GJIC) and oxidative metabolism are proposed to mediate these indirect effects. In vivo, the mechanisms behind long-range 'bystander' responses remain largely unknown. Here, we investigate the role of GJIC in propagating radiation stress signals in vivo, and in mediating radiation-associated bystander tumorigenesis in mouse central nervous system using a mouse model in which intercellular communication is downregulated by targeted deletion of the connexin43 (Cx43) gene. We show that GJIC is critical for transmission of oncogenic radiation damage to the non-targeted cerebellum, and that a mechanism involving adenosine triphosphate release and upregulation of Cx43, the major GJIC constituent, regulates transduction of oncogenic damage to unirradiated tissues in vivo. Our data provide a novel hypothesis for transduction of distant bystander effects and suggest that the highly branched nervous system, similar to the vascular network, has an important role. [ABSTRACT FROM AUTHOR]

Published

2011

6. Modulation of basal and squamous cell carcinoma by endogenous estrogen in mouse models of skin cancer.

Author

Mancuso, M., Gallo, D., Leonardi, S., Pierdomenico, M., Pasquali, E., De Stefano, I., Rebessi, S., Tanori, M., Scambia, G., Di Majo, V., Covelli, V., Pazzaglia, S., and Saran, A.

Subjects

BASAL cell carcinoma, CARCINOGENESIS, ESTROGEN, PAPILLOMA, CARCINOGENS

Abstract

Patched1 heterozygous mice (Ptch1+/−) are useful for basal cell carcinoma (BCC) studies, being remarkably susceptible to BCC induction by ultraviolet or ionizing radiation. Analogously, skin carcinogenesis-susceptible (Car-S) mice are elective for studies of papilloma and squamous cell carcinoma (SCC) induction. We previously reported a striking effect of gender on BCC induction in Ptch1+/− mice, with total resistance of females; likewise, Car-S females show increased skin tumor resistance relative to males. Here, we investigated the protective role of endogenous estrogen in skin keratinocyte tumorigenesis. Control (CN) and ovariectomized Ptch1+/− or Car-S females were irradiated for BCC induction or topically treated with chemical carcinogens for SCC induction. Susceptibility to BCC or SCC was dramatically increased in ovariectomized Ptch1+/− and Car-S females and restored to levels observed in males. Remarkably, progression of initially benign papillomas to malignant SCC occurred only in ovariectomized Car-S females. We explored the mechanisms underlying tumor progression and report overexpression of estrogen receptor (ER)-α, downregulation of ERβ and upregulation of cyclin D1 in papillomas from ovariectomized Car-S relative to papillomas from CN females. Thus, an imbalanced ERα/ERβ expression may be associated with estrogen-mediated modulation of non-melanoma skin carcinogenesis, with a key role played by cyclin D1. Our findings underscore a highly protective role of endogenous estrogen against skin tumorigenesis by diverse agents in two independent mouse models of skin cancer. [ABSTRACT FROM PUBLISHER]

Published

2009

7. Two-hit model for progression of medulloblastoma preneoplasia in Patched heterozygous mice.

Author

Pazzaglia, S., Tanori, M., Mancuso, M., Gessi, M., Pasquali, E., Leonardi, S., Oliva, M A., Rebessi, S., Di Majo, V., Covelli, V., Giangaspero, F., and Saran, A.

Subjects

MEDULLOBLASTOMA, LABORATORY mice, CHROMOSOMES, CARCINOGENESIS, ONCOGENES, GENES

Abstract

Inactivation of one Ptc1 allele predisposes humans and mice to spontaneous medulloblastoma development, and irradiation of newborn Ptc1 heterozygous mice results in dramatic increase of medulloblastoma incidence. While a role for loss of wild-type (wt) Ptc1 (LOH) in radiation-induced medulloblastomas from Ptc1neo67/+ mice is well established, the importance of this event in spontaneous medulloblastomas is still unclear. Here, we demonstrate that biallelic Ptc1 loss plays a crucial role in spontaneous medulloblastomas, as shown by high rate of wt Ptc1 loss in spontaneous tumors. In addition, remarkable differences in chromosomal events involving the Ptc1 locus in spontaneous and radiation-induced medulloblastomas suggest distinct mechanisms for Ptc1 loss. To assess when, during tumorigenesis, Ptc1 loss occurs, we characterized cerebellar abnormalities that precede tumor appearance in Ptc1neo67/+ mice. We show that inactivation of only one copy of Ptc1 is sufficient to give rise to abnormal cerebellar proliferations with different degree of altered cell morphology, but lacking potential to progress to neoplasia. Furthermore, we identify biallelic Ptc1 loss as the event causally related to the transition from the preneoplastic stage to full blown medulloblastoma. These results underscore the utility of the Ptc1neo67/+ mouse model for studies on the mechanisms of medulloblastoma and for development of new therapeutic strategies.Oncogene (2006) 25, 5575–5580. doi:10.1038/sj.onc.1209544; published online 24 April 2006 [ABSTRACT FROM AUTHOR]

Published

2006

8. Linking DNA damage to medulloblastoma tumorigenesis in patched heterozygous knockout mice.

Author

Pazzaglia, S., Tanori, M., Mancuso, M., Rebessi, S., Leonardi, S., Di Majo, V., Covelli, V., Atkinson, M. J., Hahn, H., and Saran, A.

Subjects

DNA damage, MEDULLOBLASTOMA, CEREBELLAR tumors, GENETIC mutation, PRECANCEROUS conditions, APOPTOSIS, CELL death

Abstract

Hemizygous Ptc1 mice have many features of Gorlin syndrome, including predisposition to medulloblastoma development. Ionizing radiation synergize with Ptc1 mutation to induce medulloblastoma only in neonatally exposed mice. To explore the mechanisms underlying age-dependent susceptibility, we irradiated Ptcneo67/+ mice at postnatal day 1 (P1) or 10 (P10). We observed a dramatic difference in medulloblastoma incidence, which ranged from 81% in the cerebellum irradiated at P1 to 3% in the cerebellum irradiated at P10. A stricking difference was also detected in the frequency of cerebellar preneoplastic lesions (100 versus 14%). Our data also show significantly lower induction of apoptosis in the cerebellum of medulloblastoma-susceptible (P1) compared to -resistant (P10) mice, strongly suggesting that medulloblastoma formation in Ptc1 mutants may be associated with resistance to radiation-induced cell killing. Furthermore, in marked contrast with P10 mice, cerebellum at P1 displays substantially increased activation of the cell survival-promoting Akt/Pkb protein, and markedly decreased p53 levels in response to radiation-induced genotoxic stress. Overall, these results show that developing cerebellar granule neuron precursors' (CGNPs) radiosensitivity to radiation-induced cell death increases with progressing development and inversely correlates with their ability to neoplastically transform.Oncogene (2006) 25, 1165–1173. doi:10.1038/sj.onc.1209032; published online 9 January 2006 [ABSTRACT FROM AUTHOR]

Published

2006

9. G-quadruplex ligand RHPS4 radiosensitizes glioblastoma xenograft in vivo through a differential targeting of bulky differentiated- and stem-cancer cells.

Author

Berardinelli, F., Tanori, M., Muoio, D., Buccarelli, M., di Masi, A., Leone, S., Ricci-Vitiani, L., Pallini, R., Mancuso, M., and Antoccia, A.

Subjects

MESSENGER RNA, DNA repair, CHROMOSOME abnormalities, IONIZING radiation, CELL death

Abstract

Background: Glioblastoma is the most aggressive and most lethal primary brain tumor in the adulthood. Current standard therapies are not curative and novel therapeutic options are urgently required. Present knowledge suggests that the continued glioblastoma growth and recurrence is determined by glioblastoma stem-like cells (GSCs), which display self-renewal, tumorigenic potential, and increased radio- and chemo-resistance. The G-quadruplex ligand RHPS4 displays in vitro radiosensitizing effect in GBM radioresistant cells through the targeting and dysfunctionalization of telomeres but RHPS4 and Ionizing Radiation (IR) combined treatment efficacy in vivo has not been explored so far. Methods: RHPS4 and IR combined effects were tested in vivo in a heterotopic mice xenograft model and in vitro in stem-like cells derived from U251MG and from four GBM patients. Cell growth assays, cytogenetic analysis, immunoblotting, gene expression and cytofluorimetric analysis were performed in order to characterize the response of differentiated and stem-like cells to RHPS4 and IR in single and combined treatments. Results: RHPS4 administration and IR exposure is very effective in blocking tumor growth in vivo up to 65 days. The tumor volume reduction and the long-term tumor control suggested the targeting of the stem cell compartment. Interestingly, RHPS4 treatment was able to strongly reduce cell proliferation in GSCs but, unexpectedly, did not synergize with IR. Lack of radiosensitization was supported by the GSCs telomeric-resistance observed as the total absence of telomere-involving chromosomal aberrations. Remarkably, RHPS4 treatment determined a strong reduction of CHK1 and RAD51 proteins and transcript levels suggesting that the inhibition of GSCs growth is determined by the impairment of the replication stress (RS) response and DNA repair. Conclusions: We propose that the potent antiproliferative effect of RHPS4 in GSCs is not determined by telomeric dysfunction but is achieved by the induction of RS and by the concomitant depletion of CHK1 and RAD51, leading to DNA damage and cell death. These data open to novel therapeutic options for the targeting of GSCs, indicating that the combined inhibition of cell-cycle checkpoints and DNA repair proteins provides the most effective means to overcome resistance of GSC to genotoxic insults. [ABSTRACT FROM AUTHOR]

Published

2019