Alzheimer's disease (AD) is a neurodegenerative disorder characterized by a severe and progressive neuronal loss leading to cognitive dysfunctions. Previous reports, based on the use of chemical inhibitors, have connected the stress kinase p38α to neuroinflammation, neuronal death and synaptic dysfunction. To explore the specific role of neuronal p38α signalling in the appearance of pathological symptoms, we have generated mice that combine expression of the 5XFAD transgenes to induce AD symptoms with the downregulation of p38α only in neurons (5XFAD/p38α-N). We found that the neuronal-specific deletion of p38α improves the memory loss and long-term potentiation impairment induced by 5XFAD transgenes. Furthermore, 5XFAD/p38α-N mice display reduced amyloid-β accumulation, improved neurogenesis, and important changes in brain cytokine expression compared with 5XFAD mice. Our results implicate neuronal p38α signalling in the synaptic plasticity dysfunction and memory impairment observed in 5XFAD mice, by regulating both amyloid-β deposition in the brain and the relay of this accumulation to mount an inflammatory response, which leads to the cognitive deficits. ; Spanish Ministerio de Economia y Competitividad (MINECO). S.C. was partly supported by the European Union Seventh Framework Programme (FP7/Marie Curie Actions/COFUND). IRB Barcelona is the recipient of a Severo Ochoa Award of Excellence from MINECO (Government of Spain) ; Peer Reviewed
Six1 is a developmental transcriptional regulator frequently overexpressed in human tumors. Recent results show that SIX1 also acts as a repressor of cell senescence, an antiproliferative response with a key role in tumor suppression, among other physiological and pathological settings. Here, we set to study the impact of SIX1 gain of function in transformation and tumorigenesis of fibroblasts, in connection with senescence. Using transcriptomic, histological, and functional analyses in murine tumors and cells of fibroblast origin, we show that SIX1 has a strong pro-tumorigenic action in this model, linked to the repression of a senescence-related gene signature and the induction of an undifferentiated phenotype mediated, at least in part, by the regulation of the stemness factor Sox2. Moreover, functional analyses with human glioma cell lines also show that SIX1 controls SOX2 expression, senescence and self-renewal in this model. Collectively, our results support a general link of SIX1 with senescence and SOX2-mediated cell plasticity in tumors. ; This work was supported by grants SAF2015-65960P (MINECO-FEDER) to IP, and CP16/00039, PI16/01580 (Instituto Salud Carlos III-FEDER) to AM. JA-I is the recipient of a predoctoral fellowship (PRE20160375) from the Department of Education, University and Research of the Basque Government. ; Peer reviewed
Geroprotectors, a class of drugs targeting multiple deficits occurring with age, necessitate the development of new animal models to test their efficacy. The COST Action MouseAGE is a European network whose aim is to reach consensus on the translational path required for geroprotectors, interventions targeting the biology of ageing. In our previous work we identified frailty and loss of resilience as a potential target for geroprotectors. Frailty is the result of an accumulation of deficits, which occurs with age and reduces the ability to respond to adverse events (physical resilience). Modelling frailty and physical resilience in mice is challenging for many reasons. There is no consensus on the precise definition of frailty and resilience in patients or on how best to measure it. This makes it difficult to evaluate available mouse models. In addition, the characterization of those models is poor. Here we review potential models of physical resilience, focusing on those where there is some evidence that the administration of acute stressors requires integrative responses involving multiple tissues and where aged mice showed a delayed recovery or a worse outcome then young mice in response to the stressor. These models include sepsis, trauma, drug- and radiation exposure, kidney and brain ischemia, exposure to noise, heat and cold shock. ; This article is based upon work from COST Action (BM1402: MouseAGE), supported by COST (European Cooperation in Science and Technology) and European Union Research and Innovation Program Horizon 2020 (GrantAgreement Number 730879). This work was supported by the Austrian Research Fund (FWF: P30623-B26), the Spanish MINECO (SAF2016-77703), the European Regional Development Fund, and the MRC-Arthritis Research UK Centre for Integrated Research into Musculoskeletal Ageing. ; Peer reviewed
Transcriptomic data of dermal cell fractions are deposited in NCBI's Gene Expression Omnibus (Edgar et al., 2002) under accession number GEO: GSE67693. ; The dermal Panniculus carnosus (PC) muscle is important for wound contraction in lower mammals and represents an interesting model of muscle regeneration due to its high cell turnover. The resident satellite cells (the bona fide muscle stem cells) remain poorly characterized. Here we analyzed PC satellite cells with regard to developmental origin and purported function. Lineage tracing shows that they originate in Myf5(+), Pax3/Pax7(+) cell populations. Skin and muscle wounding increased PC myofiber turnover, with the satellite cell progeny being involved in muscle regeneration but with no detectable contribution to the wound-bed myofibroblasts. Since hematopoietic stem cells fuse to PC myofibers in the absence of injury, we also studied the contribution of bone marrow-derived cells to the PC satellite cell compartment, demonstrating that cells of donor origin are capable of repopulating the PC muscle stem cell niche after irradiation and bone marrow transplantation but may not fully acquire the relevant myogenic commitment. ; We thank investigators for monoclonal antibodies A4.1025 (H.M. Blau) and F5D (W.E. Wright), which were obtained from the Developmental Studies Hybridoma Bank (developed under the auspices of the NICHD and maintained by The University of Iowa, Department of Biology, Iowa City, IA). Special thanks to G. Cossu for critical reading of the manuscript. We are also grateful to F. Costantini, C.-M. Fan, C. Lepper, M.J. Sánchez-Sanz, H. Sakai, and S. Tajbakhsh for kindly providing study materials; S. Lamarre of the GeT-Biochip facility for help in the microarray data; D. Ortiz de Urbina, J.C. Mazabuel, and A. Guisasola for help with irradiation protocol; and A. Aduriz, A. Pavón, and M. P. López-Mato for help with FACS analyses. This work was supported by grants from Instituto de Salud Carlos III (ISCIII; PS09/00660, PI13/02172, and PI14/7436), Gobierno Vasco (SAIO12-PE12BN008) from Spain and the European Union (POCTEFA-INTERREG IV A program; REFBIO13/BIOD/006 and REFBIO13/BIOD/009). N.N.G. received a studentship from the Department of Education, University and Research of the Basque Government (PRE2013-1-1168). P.G.P. received fellowships from the Department of Health of the Basque government (2013011016), EMBO (Short-Term; ASTF 542–2013), and Boehringer Ingelheim Fonds. M.L.M. and J.J.C. were supported by a Marie Curie Career Integration Grant from the European Commission (PEOPLE-CIG/1590). A.I. was supported by the Programa I3SNS (CES09/015) from ISCIII and by Osakidetza-Servicio Vasco de Salud (Spain). M.G. and S.A.M. contributed equally to this work. ; Peer-reviewed ; Publisher Version
The elucidation of mechanisms involved in resistance to therapies is essential to improve the survival of patients with malignant gliomas. A major feature possessed by glioma cells that may aid their ability to survive therapy and reconstitute tumors is the capacity for self-renewal. We show here that glioma stem cells (GSCs) express low levels of MKP1, a dual-specificity phosphatase, which acts as a negative inhibitor of JNK, ERK1/2, and p38 MAPK, while induction of high levels of MKP1 expression are associated with differentiation of GSC. Notably, we find that high levels of MKP1 correlate with a subset of glioblastoma patients with better prognosis and overall increased survival. Gain of expression studies demonstrated that elevated MKP1 impairs self-renewal and induces differentiation of GSCs while reducing tumorigenesis in vivo. Moreover, we identified that MKP1 is epigenetically regulated and that it mediates the anti-tumor activity of histone deacetylase inhibitors (HDACIs) alone or in combination with temozolomide. In summary, this study identifies MKP1 as a key modulator of the interplay between GSC self-renewal and differentiation and provides evidence that the activation of MKP1, through epigenetic regulation, might be a novel therapeutic strategy to overcome therapy resistance in glioblastoma. ; O.A. (BFI_2011_195), L.G.-R. (PRE_2013_1_760), L.M.-C. (PRE_2014_1_92), and J.A.-I. (PRE_2016_1_0375) were each recipient of a predoctoral fellowship from the Department of Education, University and Research of the Basque Government, and P.A. from the Spanish Association Against Cancer (AECC Gipuzkoa). This work was supported by grants from the Instituto de Salud Carlos III and FEDER Funds (PI13/02277, PI14/01495, PI15/00186, CP16/00039, PI16/01580, DTS16/084), European Union (Marie Curie CIG 2012/712404, REFBIO13/BIOD/009, and 011), and AICR/WCR [13–1270]. ; Peer reviewed
The elucidation of mechanisms involved in resistance to therapies is essential to improve the survival of patients with malignant gliomas. A major feature possessed by glioma cells that may aid their ability to survive therapy and reconstitute tumors is the capacity for self-renewal. We show here that glioma stem cells (GSCs) express low levels of MKP1, a dual-specificity phosphatase, which acts as a negative inhibitor of JNK, ERK1/2, and p38 MAPK, while induction of high levels of MKP1 expression are associated with differentiation of GSC. Notably, we find that high levels of MKP1 correlate with a subset of glioblastoma patients with better prognosis and overall increased survival. Gain of expression studies demonstrated that elevated MKP1 impairs self-renewal and induces differentiation of GSCs while reducing tumorigenesis in vivo. Moreover, we identified that MKP1 is epigenetically regulated and that it mediates the anti-tumor activity of histone deacetylase inhibitors (HDACIs) alone or in combination with temozolomide. In summary, this study identifies MKP1 as a key modulator of the interplay between GSC self-renewal and differentiation and provides evidence that the activation of MKP1, through epigenetic regulation, might be a novel therapeutic strategy to overcome therapy resistance in glioblastoma. ; This work was supported by grants from the Instituto de Salud Carlos III and FEDER Funds (PI13/02277, PI14/01495, PI15/00186, CP16/00039, PI16/01580, DTS16/084), European Union (Marie Curie CIG 2012/712404, REFBIO13/BIOD/009, and 011), and AICR/WCR [13–1270].
Patient stratification has been instrumental for the success of targeted therapies in breast cancer. However, the molecular basis of metastatic breast cancer and its therapeutic vulnerabilities remain poorly understood. Here we show that PML is a novel target in aggressive breast cancer. The acquisition of aggressiveness and metastatic features in breast tumours is accompanied by the elevated PML expression and enhanced sensitivity to its inhibition. Interestingly, we find that STAT3 is responsible, at least in part, for the transcriptional upregulation of PML in breast cancer. Moreover, PML targeting hampers breast cancer initiation and metastatic seeding. Mechanistically, this biological activity relies on the regulation of the stem cell gene SOX9 through interaction of PML with its promoter region. Altogether, we identify a novel pathway sustaining breast cancer aggressiveness that can be therapeutically exploited in combination with PML-based stratification. ; The work of A.C. is supported by the Ramón y Cajal award, the Basque Department of Industry, Tourism and Trade (Etortek), Health (2012111086) and Education (PI2012-03), Marie Curie (277043), Movember Foundation (GAP1), ISCIII (PI10/01484, PI13/00031), FERO (VIII Fellowship) and ERC (336343). N.M.-M. and P.A. are supported by the Spanish Association Against Cancer (AECC), AECC JP Vizcaya and Guipuzcoa, respectively. J.U. and F.S. are Juan de la Cierva Researchers (MINECO). L.A., A.A.-A. and L.V.-J. are supported by the Basque Government of education. M.L.-M.C. acknowledges SAF2014-54658-R and Asociación Española contra el Cancer. R.B. acknowledges Spanish MINECO (BFU2014-52282-P, Consolider BFU2014-57703-REDC), the Departments of Education and Industry of the Basque Government (PI2012/42) and the Bizkaia County. M.S., V.S. and J.B. acknowledge Banco Bilbao Vizcaya Argentaria (BBVA) Foundation (Tumour Biomarker Research Program). M.S. and J.B. are supported by NIH grant P30 CA008748. M.dM.V. is supported by the Institute of Health Carlos III (PI11/02251, PI14/01328) and Basque Government, Health Department (2014111145). A.M. is supported by ISCIII (CP10/00539, PI13/02277) and Marie Curie CIG 2012/712404. V.S. is supported by the SCIII (PI13/01714, CP14/00228), the FERO Foundation and the Catalan Agency AGAUR (2014 SGR 1331). R.R.G. research support is provided by the Spanish Ministry of Science and Innovation grant SAF2013-46196, BBVA Foundation, the Generalitat de Catalunya (2014 SGR 535), Institució Catalana de Recerca i Estudis Avançats, the Spanish Ministerio de Economia y Competitividad (MINECO) and FEDER funds (SAF2013-46196). ; This is the final version of the article. It first appeared from Nature Publishing Group via http://dx.doi.org/10.1038/ncomms12595
Targeted therapies and the consequent adoption of "personalized" oncology have achieved notable successes in some cancers; however, significant problems remain with this approach. Many targeted therapies are highly toxic, costs are extremely high, and most patients experience relapse after a few disease-free months. Relapses arise from genetic heterogeneity in tumors, which harbor therapy-resistant immortalized cells that have adopted alternate and compensatory pathways (i.e., pathways that are not reliant upon the same mechanisms as those which have been targeted). To address these limitations, an international task force of 180 scientists was assembled to explore the concept of a low-toxicity "broadspectrum" therapeutic approach that could simultaneously target many key pathways and mechanisms. Using cancer hallmark phenotypes and the tumor microenvironment to account for the various aspects of relevant cancer biology, interdisciplinary teams reviewed each hallmark area and nominated a wide range of high-priority targets (74 in total) that could be modified to improve patient outcomes. For these targets, corresponding low-toxicity therapeutic approaches were then suggested, many of which were phytochemicals. Proposed actions on each target and all of the approaches were further reviewed for known effects on other hallmark areas and the tumor microenvironment Potential contrary or procarcinogenic effects were found for 3.9% of the relationships between targets and hallmarks, and mixed evidence of complementary and contrary relationships was found for 7.1%. Approximately 67% of the relationships revealed potentially complementary effects, and the remainder had no known relationship. Among the approaches, 1.1% had contrary, 2.8% had mixed and 62.1% had complementary relationships. These results suggest that a broad-spectrum approach should be feasible from a safety standpoint. This novel approach has potential to be relatively inexpensive, it should help us address stages and types of cancer that lack conventional treatment, and it may reduce relapse risks. A proposed agenda for future research is offered. (C) 2015 The Authors. Published by Elsevier Ltd. ; Funding Agencies|Terry Fox Foundation Grant [TF-13-20]; UAEU Program for Advanced Research (UPAR) [31S118]; NIH [AR47901, R21CA188818, R15 CA137499-01, F32CA177139, P20RR016477, P20GM103434, R01CA170378, U54CA149145, U54CA143907, R01-HL107652, R01CA166348, R01GM071725, R01 CA109335-04A1, 109511R01CA151304CA168997 A11106131R03CA1711326 1P01AT003961RO1 CA100816P01AG034906 R01AG020642P01AG034906-01A1R01HL108006]; NIH NRSA Grant [F31CA154080]; NIH (NIAID) R01: Combination therapies for chronic HBV, liver disease, and cancer [AI076535]; Sky Foundation Inc. Michigan; University of Glasgow; Beatson Oncology Centre Fund; Spanish Ministry of Economy and Competitivity, ISCIII [PI12/00137, RTICC: RD12/0036/0028]; FEDER from Regional Development European Funds (European Union), Consejeria de Ciencia e Innovacion [CTS-6844, CTS-1848]; Consejeria de Salud of the Junta de Andalucia [PI-0135-2010, PI-0306-2012]; ISCIII [PIE13/0004]; FEDER funds; United Soybean Board; NIH NCCAM Grant [K01AT007324]; NIH NCI Grant [R33 CA161873-02]; Michael Cuccione Childhood Cancer Foundation Graduate Studentship; Ovarian and Prostate Cancer Research Trust, UK; West Virginia Higher Education Policy Commission/Division of Science Research; National Institutes of Health; Italian Association for Cancer Research (AIRC) [IG10636, 15403]; GRACE Charity, UK; Breast Cancer Campaign, UK; Michael Cuccione Childhood Cancer Foundation Postdoctoral Fellowship; Connecticut State University; Swedish Research Council; Swedish Research Society; University of Texas Health Science Centre at Tyler, Elsa U. Pardee Foundation; CPRIT; Cancer Prevention and Research Institute of Texas; NIH National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK); NIH National Institute on Alcohol Abuse and Alcoholism (NIAAA); Gilead and Shire Pharmaceuticals; NIH/NCI [1R01CA20009, 5R01CAl27258-05, R21CA184788, NIH P30 CA22453, NCI RO1 28704]; Scottish Governments Rural and Environment Science and Analytical Services Division; National Research Foundation; United Arab Emirates University; Terry Fox Foundation; Novartis Pharmaceutical; Aveo Pharmaceutical; Roche; Bristol Myers Squibb; Bayer Pharmaceutical; Pfizer; Kyowa Kirin; NIH/NIAID Grant [A1076535]; Auckland Cancer Society; Cancer Society of New Zealand; NIH Public Service Grant from the National Cancer Institute [CA164095]; Medical Research Council CCU-Program Grant on cancer metabolism; EU Marie Curie Reintegration Grant [MC-CIG-303514]; Greek National funds through the Operational Program Educational and Lifelong Learning of the National Strategic Reference Framework (NSRF)-Research Funding Program THALES [MIS 379346]; COST Action CM1201 `Biomimetic Radical Chemistry; Duke University Molecular Cancer Biology T32 Training Grant; National Sciences Engineering and Research Council Undergraduate Student Research Award in Canada; Charles University in Prague projects [UNCE 204015, PRVOUK P31/2012]; Czech Science Foundation projects [15-03834Y, P301/12/1686]; Czech Health Research Council AZV project [15-32432A]; Internal Grant Agency of the Ministry of Health of the Czech Republic project [NT13663-3/2012]; National Institute of Aging [P30AG028716-01]; NIH/NCI training grants to Duke University [T32-CA059365-19, 5T32-CA059365]; Ministry of Education, Culture, Sports, Science and Technology, Japan [24590493]; Ministry of Health and Welfare [CCMP101-RD-031, CCMP102-RD-112]; Tzu-Chi University of Taiwan [61040055-10]; Svenska Sallskapet for Medicinsk Forskning; Cancer Research Wales; Albert Hung Foundation; Fong Family Foundation; Welsh Government A4B scheme; NIH NCI; University of Glasgow, Beatson Oncology Centre Fund, CRUK [C301/A14762]; NIH Intramural Research Program; National Science Foundation; American Cancer Society; National Cancer Center [NCC-1310430-2]; National Research Foundation [NRF-2005-0093837]; Sol Goldman Pancreatic Cancer Research Fund Grant [80028595]; Lustgarten Fund Grant [90049125, NIHR21CA169757]; Alma Toorock Memorial for Cancer Research; National Research Foundation of Korea (NRF); Ministry of Science, ICT & Future Planning (MSIP), Republic of Korea [2011-0017639, 2011-0030001]; Ministry of Education of Taiwan [TMUTOP103005-4]; International Life Sciences Institute; United States Public Health Services Grants [NIH R01CA156776]; VA-BLR&D Merit Review Grant [5101-BX001517-02]; V Foundation; Pancreatic Cancer Action Network; Damon Runyon Cancer Research Foundation; Childrens Cancer Institute Australia; University Roma Tre; Italian Association for Cancer Research (AIRC-Grant) [IG15221]; Carlos III Health Institute; Feder funds [AM: CP10/00539, PI13/02277]; Basque Foundation for Science (IKERBASQUE); Marie Curie CIG Grant [2012/712404]; Canadian Institutes of Health Research; Avon Foundation for Women [OBC-134038]; Canadian Institutes of Health [MSH-136647, MOP 64308]; Bayer Healthcare System G4T (Grants4Targets); NIH NIDDK; NIH NIAAA; Shire Pharmaceuticals; Harvard-MIT Health Sciences and Technology Research Assistantship Award; Italian Ministry of University; University of Italy; Auckland Cancer Society Research Centre (ACSRC); German Federal Ministry of Education and Research (Bundesministerium fur Bildung und Forschung, BMBF) [16SV5536K]; European Commission [FP7 259679 "IDEAL"]; Cinque per Mille dellIRPEF-Finanziamento della Ricerca Sanitaria; European Union Seventh Framework Programme (FP7) [278570]; AIRC [10216, 13837]; European Communitys Seventh Framework Program FP7 [311876]; Canadian Institute for Health Research [MOP114962, MOP125857]; Fonds de Recherche Quebec Sante [22624]; Terry Fox Research Institute [1030]; FEDER; MICINN [SAF2012-32810]; Junta de Castilla y Leon [BIO/SA06/13]; ARIMMORA project [FP7-ENV-2011]; European Union; NIH NIDDK [K01DK077137, R03DK089130]; NIH NCI grants [R01CA131294, R21 CA155686]; Avon Foundation; Breast Cancer Research Foundation Grant [90047965]; National Institute of Health, NINDS Grant [K08NS083732]; AACR-National Brain Tumor Society Career Development Award for Translational Brain Tumor Research [13-20-23-SIEG]; Department of Science and Technology, New Delhi, India [SR/FT/LS-063/2008]; Yorkshire Cancer Research; Wellcome Trust, UK; Italian Ministry of Economy and Finance Project CAMPUS-QUARC, within program FESR Campania Region; National Cancer Institute [5P01CA073992]; IDEA Award from the Department of Defense [W81XWH-12-1-0515]; Huntsman Cancer Foundation; University of Miami Clinical and Translational Science Institute (CTSI) Pilot Research Grant [CTSI-2013-P03]; SEEDS You Choose Awards; DoD [W81XVVH-11-1-0272, W81XWH-13-1-0182]; Kimmel Translational Science Award [SKF-13-021]; ACS Scholar award [122688-RSG-12-196-01-TBG]; National Cancer Institute, Pancreatic Cancer Action Network, Pew Charitable Trusts; American Diabetes Association; Elsa U. Pardee Foundation; Scientific Research Foundation for the Returned Oversea Scholars, State Education Ministry and Scientific and Technological Innovation Project, Harbin [2012RFLX5011]; United States National Institutes of Health [ES019458]; California Breast Cancer Research Program [17UB-8708]; National Institutes of Health through the RCMI-Center for Environmental Health [G1200MD007581]; NIH/National Heart, Lung, and Blood Institute Training Grant [T32HL098062]; European FP7-TuMIC [HEALTH-F2-2008-201662]; Italian Association for Cancer research (AIRC) Grant IG [11963]; Regione Campania L.R:N.5; European National Funds [PON01-02388/1 2007-2013]
