Peri-Implant Bone Loss and Overload: A Systematic Review Focusing on Occlusal Analysis through Digital and Analogic Methods.

The present review aimed to assess the possible relationship between occlusal overload and peri-implant bone loss. In accordance with the PRISMA guidelines, the MEDLINE, Scopus, and Cochrane databases were searched from January 1985 up to and including December 2021. The search strategy applied was: (dental OR oral) AND implants AND (overload OR excessive load OR occlusal wear) AND (bone loss OR peri-implantitis OR failure). Clinical studies that reported quantitative analysis of occlusal loads through digital contacts and/or occlusal wear were included. The studies were screened for eligibility by two independent reviewers. The quality of the included studies was assessed using the Risk of Bias in Non-randomized Studies of Interventions (ROBINS-I) tool. In total, 492 studies were identified in the search during the initial screening. Of those, 84 were subjected to full-text evaluation, and 7 fulfilled the inclusion criteria (4 cohort studies, 2 cross-sectional, and 1 case-control). Only one study used a digital device to assess excessive occlusal forces. Four out of seven studies reported a positive correlation between the overload and the crestal bone loss. All of the included studies had moderate to serious overall risk of bias, according to the ROBINS-I tool. In conclusion, the reported data relating the occlusal analysis to the peri-implant bone level seem to reveal an association, which must be further investigated using new digital tools that can help to standardize the methodology

F-actin dynamics regulates mammalian organ growth and cell fate maintenance.

BACKGROUND & AIMS: In vitro, several data indicate that cell function can be regulated by the mechanical properties of cells and of the microenvironment. Cells measure these features by developing forces via their actomyosin cytoskeleton, and respond accordingly by transducing forces into biochemical signals that instruct cell behavior. Among these, the transcriptional coactivators YAP/TAZ recently emerged as key factors mediating multiple responses to actomyosin contractility. However, whether mechanical cues regulate adult liver tissue homeostasis, and whether this occurs through YAP/TAZ, remains largely unaddressed. METHODS & RESULTS: Here we show that the F-actin capping protein CAPZ is a critical negative regulator of actomyosin contractility and mechanotransduction. Capzb inactivation alters stress fiber and focal adhesion dynamics leading to enhanced myosin activity, increased cellular traction forces, and increased liver stiffness. In vitro, this rescues YAP from inhibition by a small geometry; in vivo, inactivation of Capzb in the adult mouse liver induces YAP activation in parallel to the Hippo pathway, causing extensive hepatocyte proliferation and leading to striking organ overgrowth. Moreover, Capzb is required for the maintenance of the differentiated hepatocyte state, for metabolic zonation, and for gluconeogenesis. In keeping with changes in tissue mechanics, inhibition of the contractility regulator ROCK, or deletion of the Yap1 mechanotransducer, reverse the phenotypes emerging in Capzb-null livers. CONCLUSIONS: These results indicate a previously unrecognized role for CAPZ in tuning the mechanical properties of cells and tissues, which is required in hepatocytes for the maintenance of the differentiated hepatocyte state and to regulate organ size. More in general, it indicates for the first time a physiological role of mechanotransduction in maintaining tissue homeostasis in mammals. LAY SUMMARY: The mechanical properties of cells and tissues (i.e. whether they are soft or stiff) are thought to be important regulators of cell behavior. A recent advancement in our understanding of these phenomena has been the identification of YAP and TAZ as key factors mediating the biological responses of cells to mechanical signals in vitro. However, whether the mechanical properties of cells and/or the mechanical regulation of YAP/TAZ are relevant for mammalian tissue physiology remains unknown. Here we challenge this issue by genetic inactivation of CAPZ, a protein that regulates the cytoskeleton, i.e. the cells' scaffold by which they sense mechanical cues. We found that inactivation of CAPZ alters cells' and liver tissue's mechanical properties, leading to YAP hyperactivation. In turn, this profoundly alters liver physiology, causing organ overgrowth, defects in liver cell differentiation and metabolism. These results reveal a previously uncharacterized role for mechanical signals for the maintenance of adult liver homeostasis.This work was supported by AIRC (Associazione Italiana per la Ricerca sul Cancro) Investigator Grant 15307, WCR (Worldwide Cancer Research) Grant 15-1192, CARIPARO Eccellenza Program 2017 and University of Padua BIRD Grant to SD, AIRC ‘Hard ROCK Café’ Fellowship to GS, Marie Sklodowska-Curie Individual Fellowship (796547) to AG, AIRC Special Program Molecular Clinical Oncology ‘5 per mille’ 10016 to SB, UK Medical Research Council and Sackler Foundation Doctoral Training Grant RG70550 to ACL, UK Medical Research Council Career Development Award G1100312/1 and an Isaac Newton Trust Research Grant 17.24(p) to KF

F-actin dynamics regulates mammalian organ growth and cell fate maintenance.

BACKGROUND & AIMS: In vitro, several data indicate that cell function can be regulated by the mechanical properties of cells and of the microenvironment. Cells measure these features by developing forces via their actomyosin cytoskeleton, and respond accordingly by transducing forces into biochemical signals that instruct cell behavior. Among these, the transcriptional coactivators YAP/TAZ recently emerged as key factors mediating multiple responses to actomyosin contractility. However, whether mechanical cues regulate adult liver tissue homeostasis, and whether this occurs through YAP/TAZ, remains largely unaddressed. METHODS & RESULTS: Here we show that the F-actin capping protein CAPZ is a critical negative regulator of actomyosin contractility and mechanotransduction. Capzb inactivation alters stress fiber and focal adhesion dynamics leading to enhanced myosin activity, increased cellular traction forces, and increased liver stiffness. In vitro, this rescues YAP from inhibition by a small geometry; in vivo, inactivation of Capzb in the adult mouse liver induces YAP activation in parallel to the Hippo pathway, causing extensive hepatocyte proliferation and leading to striking organ overgrowth. Moreover, Capzb is required for the maintenance of the differentiated hepatocyte state, for metabolic zonation, and for gluconeogenesis. In keeping with changes in tissue mechanics, inhibition of the contractility regulator ROCK, or deletion of the Yap1 mechanotransducer, reverse the phenotypes emerging in Capzb-null livers. CONCLUSIONS: These results indicate a previously unrecognized role for CAPZ in tuning the mechanical properties of cells and tissues, which is required in hepatocytes for the maintenance of the differentiated hepatocyte state and to regulate organ size. More in general, it indicates for the first time a physiological role of mechanotransduction in maintaining tissue homeostasis in mammals. LAY SUMMARY: The mechanical properties of cells and tissues (i.e. whether they are soft or stiff) are thought to be important regulators of cell behavior. A recent advancement in our understanding of these phenomena has been the identification of YAP and TAZ as key factors mediating the biological responses of cells to mechanical signals in vitro. However, whether the mechanical properties of cells and/or the mechanical regulation of YAP/TAZ are relevant for mammalian tissue physiology remains unknown. Here we challenge this issue by genetic inactivation of CAPZ, a protein that regulates the cytoskeleton, i.e. the cells' scaffold by which they sense mechanical cues. We found that inactivation of CAPZ alters cells' and liver tissue's mechanical properties, leading to YAP hyperactivation. In turn, this profoundly alters liver physiology, causing organ overgrowth, defects in liver cell differentiation and metabolism. These results reveal a previously uncharacterized role for mechanical signals for the maintenance of adult liver homeostasis.This work was supported by AIRC (Associazione Italiana per la Ricerca sul Cancro) Investigator Grant 15307, WCR (Worldwide Cancer Research) Grant 15-1192, CARIPARO Eccellenza Program 2017 and University of Padua BIRD Grant to SD, AIRC ‘Hard ROCK Café’ Fellowship to GS, Marie Sklodowska-Curie Individual Fellowship (796547) to AG, AIRC Special Program Molecular Clinical Oncology ‘5 per mille’ 10016 to SB, UK Medical Research Council and Sackler Foundation Doctoral Training Grant RG70550 to ACL, UK Medical Research Council Career Development Award G1100312/1 and an Isaac Newton Trust Research Grant 17.24(p) to KF

The transcriptional regulator ZNF398 mediates pluripotency and epithelial character downstream of TGF-beta in human PSCs

Human pluripotent stem cells (hPSCs) have the capacity to give rise to all differentiated cells of the adult. TGF-beta is used routinely for expansion of conventional hPSCs as flat epithelial colonies expressing the transcription factors POU5F1/OCT4, NANOG, SOX2. Here we report a global analysis of the transcriptional programme controlled by TGF-beta followed by an unbiased gain-of-function screening in multiple hPSC lines to identify factors mediating TGF-beta activity. We identify a quartet of transcriptional regulators promoting hPSC self-renewal including ZNF398, a human-specific mediator of pluripotency and epithelial character in hPSCs. Mechanistically, ZNF398 binds active promoters and enhancers together with SMAD3 and the histone acetyltransferase EP300, enabling transcription of TGF-beta targets. In the context of somatic cell reprogramming, inhibition of ZNF398 abolishes activation of pluripotency and epithelial genes and colony formation. Our findings have clear implications for the generation of bona fide hPSCs for regenerative medicine.</p

EphB6 Regulates TFEB-Lysosomal Pathway and Survival of Disseminated Indolent Breast Cancer Cells

Late relapse of disseminated cancer cells is a common feature of breast and prostate tumors. Several intrinsic and extrinsic factors have been shown to affect quiescence and reawakening of disseminated dormant cancer cells (DDCCs); however, the signals and processes sustaining the survival of DDCCs in a foreign environment are still poorly understood. We have recently shown that crosstalk with lung epithelial cells promotes survival of DDCCs of estrogen receptor-positive (ER+) breast tumors. By using a lung organotypic system and in vivo dissemination assays, here we show that the TFEB-lysosomal axis is activated in DDCCs and that it is modulated by the pro-survival ephrin receptor EphB6. TFEB lysosomal direct targets are enriched in DDCCs in vivo and correlate with relapse in ER+ breast cancer patients. Direct coculture of DDCCs with alveolar type I-like lung epithelial cells and dissemination in the lung drive lysosomal accumulation and EphB6 induction. EphB6 contributes to survival, TFEB transcriptional activity, and lysosome formation in DDCCs in vitro and in vivo. Furthermore, signaling from EphB6 promotes the proliferation of surrounding lung parenchymal cells in vivo. Our data provide evidence that EphB6 is a key factor in the crosstalk between disseminated dormant cancer cells and the lung parenchyma and that the TFEB-lysosomal pathway plays an important role in the persistence of DDCCs

The Hippo transducer TAZ confers cancer stem cell-related traits on breast cancer cells.

none15Cancer stem cells (CSCs) are proposed to drive tumor initiation and progression. Yet, our understanding of the cellular and molecular mechanisms that underlie CSC properties is limited. Here we show that the activity of TAZ, a transducer of the Hippo pathway, is required to sustain self-renewal and tumor-initiation capacities in breast CSCs. TAZ protein levels and activity are elevated in prospective CSCs and in poorly differentiated human tumors and have prognostic value. Gain of TAZ endows self-renewal capacity to non-CSCs. In epithelial cells, TAZ forms a complex with the cell-polarity determinant Scribble, and loss of Scribble--or induction of the epithelial-mesenchymal transition (EMT)--disrupts the inhibitory association of TAZ with the core Hippo kinases MST and LATS. This study links the CSC concept to the Hippo pathway in breast cancer and reveals a mechanistic basis of the control of Hippo kinases by cell polarity.mixedCordenonsi M;Zanconato F;Azzolin L;Forcato M;Rosato A;Frasson C;Inui M;Montagner M;Parenti AR;Poletti A;Daidone MG;Dupont S;Basso G;Bicciato S;Piccolo SCordenonsi, Michelangelo; Zanconato, Francesca; Azzolin, Luca; Forcato, M; Rosato, Antonio; Frasson, Chiara; Inui, M; Montagner, Marco; Parenti, ANNA ROSITA; Poletti, A; Daidone, Mg; Dupont, Sirio; Basso, Giuseppe; Bicciato, S; Piccolo, Stefan

Mitochondrial fission links ECM mechanotransduction to metabolic redox homeostasis and metastatic chemotherapy resistance.

Metastatic breast cancer cells disseminate to organs with a soft microenvironment. Whether and how the mechanical properties of the local tissue influence their response to treatment remains unclear. Here we found that a soft extracellular matrix empowers redox homeostasis. Cells cultured on a soft extracellular matrix display increased peri-mitochondrial F-actin, promoted by Spire1C and Arp2/3 nucleation factors, and increased DRP1- and MIEF1/2-dependent mitochondrial fission. Changes in mitochondrial dynamics lead to increased production of mitochondrial reactive oxygen species and activate the NRF2 antioxidant transcriptional response, including increased cystine uptake and glutathione metabolism. This retrograde response endows cells with resistance to oxidative stress and reactive oxygen species-dependent chemotherapy drugs. This is relevant in a mouse model of metastatic breast cancer cells dormant in the lung soft tissue, where inhibition of DRP1 and NRF2 restored cisplatin sensitivity and prevented disseminated cancer-cell awakening. We propose that targeting this mitochondrial dynamics- and redox-based mechanotransduction pathway could open avenues to prevent metastatic relapse