Oncological translational research in the Spanish national health system: the INTRO study

Under the auspices of the Foundation for Excellence and Quality in Oncology (ECO), the Translational Research in Oncology Medical Services Study (INTRO) was conducted with the aim of describing the current state of, and future expectations for translational cancer research in Spanish medical centres. The first step in the investigation was intended to analyse the current condition of the national Medical Oncology Services network by examining different aspects of the oncology research field. A descriptive and observational multicentre study was performed at a statewide level; information was collected by surveying a cross-section of all those responsible for Medical Oncology Services in Spain. The survey was completed by key informants, who were selected independently by each service, between September 2010 and April 2011. We were able to gather comprehensive data from a total of 27 Spanish hospitals. These data enabled us to describe the allocation of human and material resources devoted to clinical and translational research across the Medical Oncology Services and to describe the organisational and functional components of these services and units. These data included information pertaining to the activities developed, their funding sources, and their functional dependence on other internal or external bodies. Finally, we explored the degree of dissemination and use of some specific techniques used for the genetic diagnosis of cancer, which have recently been introduced in Medical Oncology within the Spanish healthcare system. A wide range of variability exists between different oncology services in Spanish hospitals. Time should be spent reflecting on the need and opportunities for improvement in the development of translational research within the field of oncology.Caballero, C.; Jantus-Lewintre, E.; Carrato, A.; García Foncillas, J.; Gascon, P.; Blasco, A.; Moreno Nogueira, JA.... (2014). Oncological translational research in the Spanish national health system: the INTRO study. Clinical and Translational Oncology. 16(8):686-695. doi:10.1007/s12094-013-1138-6S686695168Díaz-Rubio E. Translational research in clinical oncology: challenges and opportunities. Farm Hosp. 2010;34(Supl.1):1–7.Marincola FM. Translational medicine: a two-way road. J Transl Med. 2003;1(1):1.Ablin RJ, Marincola FM, Natali PG. The “excellence in translational medicine” and “bedside-to-bench” awards 2008–09. J Transl Med. 2010;13(8):95.García-Sáenz JA, Bueno C, SanPedro T, Díaz-Rubio E. La nueva oncología médica: aportación de la biología molecular al diagnóstico y tratamiento del cáncer. In: Díaz-Rubio E, editor. Tomo IV. Madrid: You and Us; 2006. p. 1–24.ORDEN SCO/709/2002, Boletín Oficial del Estado, 3 de abril de 2003, núm. 80, pp. 12742–12746. http://www.boe.es/boe/dias/2002/04/03/pdfs/A12742-12746.pdf . Accessed 30 sept 2013.Soto-Martínez JL, Baselga-Torres J, Carrato-Mena A. La investigación Translacional en Oncología Médica. En Primer Libro blanco de la Oncología Médica en España. Dosier 2006. Madrid: Editorial Dispublic SL; 2007. p. 177–99.Ministerio de Sanidad y Consumo. Agencia de Calidad del Sistema Nacional de Salud. Estrategia en Cáncer del Sistema Nacional de Salud. 2006. http://www.msc.es/organizacion/ sns/planCalidadSNS/docs/estratCancerSNS.pdf. Accessed 30 sept 2013.Lenfant C. Shattuck lecture–clinical research to clinical practice-lost in translation? N Engl J Med. 2003;349(9):868–74.Laurence J. Translating translational research. Transl Res. 2006;148(1):1–3.Lemieux-Charles L, McGuire WL. What do we know about health care team effectiveness? A review of the literature. Med Care Res Rev. 2006;63(3):263–300.Oandasan I, Baker RG, Barker K, Bosco C, D’Amour D, Jones L, et al. Teamwork in health care: promoting effective teamwork in healthcare in Canada; policy synthesis and recommendations. June 2006. http://www.chsrf.ca/Migrated/PDF/teamwork-synthesis-report_e.pdf . Accessed 30 Sep 2013.Mankoff SP, Brander C, Ferrone S, Marincola FM. Lost in Translation: obstacles to translational medicine. J Transl Med. 2004;2(1):14.Curran T. Lost in translation: the future of cancer research? Clin Cancer Res. 2005;11(13):4644.Valladares Y. Memoria y actas del primer congreso de investigación sobre el cáncer en España. Madrid; 1983.Vicente J. Apuntes para una historia de la Oncología en España. Los orígenes. Oncología. 2000;23(7):310–7.Legido-Quigley H, Otero L, la Parra D, Alvarez-Dardet C, Martin-Moreno JM, McKee M. Will austerity cuts dismantle the Spanish healthcare system? BMJ. 2013;13(346):f2363

Identification of a novel synthetic lethal vulnerability in non-small cell lung cancer by co-targeting TMPRSS4 and DDR1

Finding novel targets in non-small cell lung cancer (NSCLC) is highly needed and identification of synthetic lethality between two genes is a new approach to target NSCLC. We previously found that TMPRSS4 promotes NSCLC growth and constitutes a prognostic biomarker. Here, through large-scale analyses across 5 public databases we identified consistent co-expression between TMPRSS4 and DDR1. Similar to TMPRSS4, DDR1 promoter was hypomethylated in NSCLC in 3 independent cohorts and hypomethylation was an independent prognostic factor of disease-free survival. Treatment with 5-azacitidine increased DDR1 levels in cell lines, suggesting an epigenetic regulation. Cells lacking TMPRSS4 were highly sensitive to the cytotoxic effect of the DDR1 inhibitor dasatinib. TMPRSS4/DDR1 double knock-down (KD) cells, but not single KD cells suffered a G0/G1 cell cycle arrest with loss of E2F1 and cyclins A and B, increased p21 levels and a larger number of cells in apoptosis. Moreover, double KD cells were highly sensitized to cisplatin, which caused massive apoptosis (~40%). In vivo studies demonstrated tumor regression in double KD-injected mice. In conclusion, we have identified a novel vulnerability in NSCLC resulting from a synthetic lethal interaction between DDR1 and TMPRSS4

Identification of novel synthetic lethal vulnerability in non small cell lung cancer by co targeting TMPRSS4 and DDR1

Finding novel targets in non-small cell lung cancer (NSCLC) is highly needed and identification of synthetic lethality between two genes is a new approach to target NSCLC. We previously found that TMPRSS4 promotes NSCLC growth and constitutes a prognostic biomarker. Here, through large-scale analyses across 5 public databases we identified consistent co-expression between TMPRSS4 and DDR1. Similar to TMPRSS4, DDR1 promoter was hypomethylated in NSCLC in 3 independent cohorts and hypomethylation was an independent prognostic factor of disease-free survival. Treatment with 5-azacitidine increased DDR1 levels in cell lines, suggesting an epigenetic regulation. Cells lacking TMPRSS4 were highly sensitive to the cytotoxic effect of the DDR1 inhibitor dasatinib. TMPRSS4/DDR1 double knock-down (KD) cells, but not single KD cells suffered a G0/G1 cell cycle arrest with loss of E2F1 and cyclins A and B, increased p21 levels and a larger number of cells in apoptosis. Moreover, double KD cells were highly sensitized to cisplatin, which caused massive apoptosis (~40%). In vivo studies demonstrated tumor regression in double KD-injected mice. In conclusion, we have identified a novel vulnerability in NSCLC resulting from a synthetic lethal interaction between DDR1 and TMPRSS4

Prospective Exploratory Analysis of Angiogenic Biomarkers in Peripheral Blood in Advanced NSCLC Patients Treated With Bevacizumab Plus Chemotherapy: The ANGIOMET Study

Finding angiogenic prognostic markers in advanced non-small-cell lung cancer is still an unmet medical need. We explored a set of genetic variants in the VEGF-pathway as potential biomarkers to predict clinical outcomes of patients with non-small-cell lung cancer treated with chemotherapy plus bevacizumab. We prospectively analyzed the relationship between VEGF-pathway components with both pathological and prognostic variables in response to chemotherapy plus bevacizumab in 168 patients with non-squamous non-small-cell lung cancer. Circulating levels of VEGF and VEGFR2 and expression of specific endothelial surface markers and single-nucleotide polymorphisms in VEGF-pathway genes were analyzed. The primary clinical endpoint was progression-free survival. Secondary endpoints included overall survival and objective tumor response. VEGFR-1 rs9582036 variants AA/AC were associated with increased progression-free survival (p = 0.012 and p = 0.035, respectively), and with improved overall survival (p = 0.019) with respect to CC allele. Patients with VEGF-A rs3025039 harboring allele TT had also reduced mortality risk (p = 0.049) compared with the CC allele. The VEGF-A rs833061 variant was found to be related with response to treatment, with 61.1% of patients harboring the CC allele achieving partial treatment response. High pre-treatment circulating levels of VEGF-A were associated with shorter progression-free survival (p = 0.036). In conclusion, in this prospective study, genetic variants in VEGFR-1 and VEGF-A and plasma levels of VEGF-A were associated with clinical benefit, progression-free survival, or overall survival in a cohort of advanced non-squamous non-small-cell lung cancer patients receiving chemotherapy plus antiangiogenic therapy. © Copyright © 2021 Jantus-Lewintre, Massutí Sureda, González Larriba, Rodríguez-Abreu, Juan, Blasco, Dómine, Provencio Pulla, Garde, Álvarez, Maestu, Pérez de Carrión, Artal, Rolfo, de Castro, Guillot, Oramas, de las Peñas, Ferrera, Martínez, Serra, Rosell and Camps

HMGB1 Expression Levels Correlate with Response to Immunotherapy in Non-Small Cell Lung Cancer

Maria González-Cao,1 Xueting Cai,2 Jilian Wilhelmina Paulina Bracht,3 Xuan Han,2 Yang Yang,2 Carlos Pedraz-Valdunciel,4 Teresa Morán,5 Javier García-Corbacho,6 Andrés Aguilar,1 Reyes Bernabé,7 Pedro De Marchi,8,9 Luciane Sussuchi da Silva,8 Leticia Ferro Leal,8 Rui Manuel Reis,8,10,11 Jordi Codony-Servat,4 Eloisa Jantus-Lewintre,12– 14 Miguel Angel Molina-Vila,4 Peng Cao,2,15 Rafael Rosell1,16 1Translational Cancer Research Unit, Instituto Oncológico Dr Rosell, Dexeus University Hospital, Barcelona, Spain; 2Integrated Traditional Chinese and Western Medicine Department of Affiliated Hospital, Nanjing University of Chinese Medicine, Nanjing, Jiangsu, People’s Republic of China; 3Amsterdam University Medical Center (UMC), Amsterdam, The Netherlands; 4Laboratory of Oncology, Pangaea Oncology, Quirón Dexeus University Hospital, Barcelona, Spain; 5Medical Oncology Department, Catalan Institute of Oncology (ICO), Germans Trias i Pujol Hospital, Badalona, Spain; 6Medical Oncology Department (Hospital Clinic)/Translational Genomics and Targeted Therapies in Solid Tumors (IDIBAPs), Barcelona, Spain; 7Medical Oncology Department, Hospital Universitario Virgen del Rocío, Sevilla, Spain; 8Molecular Oncology Research Center; Barretos Cancer Hospital, Barretos, Brazil; 9Oncoclinicas, Rio de Janeiro, Brazil; 10Life and Health Sciences Research Institute (ICVS), School of Medicine, University of Minho, Braga, Portugal; 11ICVS/3b’s – PT Government Associate Laboratory, Braga/Guimarães, Portugal; 12Valencian Community Foundation Principe Felipe Research Center, Laboratory of Molecular Oncology, Valencia, Spain; 13Centro de Investigación Biomédica en Red (CIBERONC), Madrid, Spain; 14Universitat Politècnica de Valencia, Biotechnology Department, Valencia, Spain; 15College of Pharmacy, Nanjing University of Chinese Medicine, Nanjing, Jiangsu, People’s Republic of China; 16Laboratory of Molecular Biology, Germans Trias i Pujol Health Sciences Institute and Hospital (IGTP), Badalona, SpainCorrespondence: Rafael Rosell, Laboratory of Molecular Biology, Germans Trias i Pujol Health Sciences Institute and Hospital (IGTP), Camí de les Escoless/n, Badalona, Barcelona, 08916, Spain, Tel +34 930330520, Email [email protected] Peng Cao, College of Pharmacy, Nanjing University of Chinese Medicine, Nanjing, 210023, People’s Republic of China, Tel +86 85608666, Email [email protected]: High-mobility group box 1 protein (HMGB1) is subject to exportin 1 (XPO1)-dependent nuclear export, and it is involved in functions implicated in resistance to immunotherapy. We investigated whether HMGB1 mRNA expression was associated with response to immune checkpoint inhibitors (ICI) in non-small cell lung cancer (NSCLC).Patients and Methods: RNA was isolated from pretreatment biopsies of patients with advanced NSCLC treated with ICI. Gene expression analysis of several genes, including HMGB1, was conducted using the NanoString Counter analysis system (PanCancer Immune Profiling Panel). Western blotting analysis and cell viability assays in EGFR and KRAS mutant cell lines were carried out. Evaluation of the antitumoral effect of ICI in combination with XPO1 blocker (selinexor) and trametinib was determined in a murine Lewis lung carcinoma model.Results: HMGB1 mRNA levels in NSCLC patients treated with ICI correlated with progression-free survival (PFS) (median PFS 9.0 versus 18.0 months, P=0.008, hazard ratio=0.30 in high versus low HMGB1). After TNF-α stimulation, HMGB1 accumulates in the cytoplasm of PC9 cells, but this accumulation can be prevented by using selinexor or antiretroviral drugs. Erlotinib or osimertinib with selinexor in EGFR-mutant cells and trametinib plus selinexor in KRAS mutant abolish tumor cell proliferation. Selinexor with a PD-1 inhibitor with or without trametinib abrogates the tumor growth in the murine Lewis lung cancer model.Conclusion: An in-depth exploration of the functions of HMGB1 mRNA and protein is expected to uncover new potential targets and provide a basis for treating metastatic NSCLC in combination with ICI.Keywords: HMGB1, immunotherapy, non-small cell lung cancer, Lewis lung cancer murine model, K-Ras mutation

Type-Specific HPV Prevalence in Cervical Cancer and High-Grade Lesions in Latin America and the Caribbean: Systematic Review and Meta-Analysis

BACKGROUND: Cervical cancer is a major public health problem in Latin America and the Caribbean (LA&C), showing some of the highest incidence and mortality rates worldwide. Information on HPV type distribution in high-grade cervical lesions (HSIL) and invasive cervical cancer (ICC) is crucial to predict the future impact of HPV16/18 vaccines and screening programmes, and to establish an appropriate post-vaccinal virologic surveillance. The aim was to assess the prevalence of HPV types in HSIL and ICC in studies in LA&C. METHODS AND FINDINGS: We performed a systematic review, following the MOOSE guidelines for systematic reviews of observational studies, and the PRISMA statement for reporting systematic reviews and meta-analyses. Inclusion criteria were at least ten cases of HSIL/ICC, and HPV-type elicitation. The search, without language restrictions, was performed in MEDLINE, Cochrane Library, EMBASE, LILACS from inception date to December 2009, proceedings, reference lists and consulting experts. A meta-analysis was performed using arc-sine transformations to stabilize the variance of simple proportions. Seventy-nine studies from 18 countries were identified, including 2446 cases of HSIL and 5540 of ICC. Overall, 46.5% of HSIL cases harbored HPV 16 and 8.9% HPV18; in ICC, 53.2% of cases harbored HPV 16 and 13.2% HPV 18. The next five most common types, in decreasing frequency, were HPV 31, 58, 33, 45, and 52. Study's limitations comprise the cross-sectional design of most included studies and their inherent risk of bias, the lack of representativeness, and variations in the HPV type-specific sensitivity of different PCR protocols. CONCLUSIONS: This study is the broadest summary of HPV type distribution in HSIL and ICC in LA&C to date. These data are essential for local decision makers regarding HPV screening and vaccination policies. Continued HPV surveillance would be useful, to assess the potential for changing type-specific HPV prevalence in the post-vaccination era in Latin America

Identification of TRPC6 as a possible candidate target gene within an amplicon at 11q21-q22.2 for migratory capacity in head and neck squamous cell carcinomas

Abstract: Background: Cytogenetic and gene expression analyses in head and neck squamous cell carcinomas (HNSCC) have allowed identification of genomic aberrations that may contribute to cancer pathophysiology. Nevertheless, the molecular consequences of numerous genetic alterations still remain unclear. Methods: To identify novel genes implicated in HNSCC pathogenesis, we analyzed the genomic alterations present in five HNSCC-derived cell lines by array CGH, and compared high level focal gene amplifications with gene expression levels to identify genes whose expression is directly impacted by these genetic events. Next, we knocked down TRPC6, one of the most highly amplified and over-expressed genes, to characterize the biological roles of TRPC6 in carcinogenesis. Finally, real time PCR was performed to determine TRPC6 gene dosage and mRNA levels in normal mucosa and human HNSCC tissues. Results: The data showed that the HNSCC-derived cell lines carry most of the recurrent genomic abnormalities previously described in primary tumors. High-level genomic amplifications were found at four chromosomal sites (11q21-q22.2, 18p11.31-p11.21, 19p13.2-p13.13, and 21q11) with associated gene expression changes in selective candidate genes suggesting that they may play an important role in the malignant behavior of HNSCC. One of the most dramatic alterations of gene transcription involved the TRPC6 gene (located at 11q21-q22.2) which has been recently implicated in tumour invasiveness. siRNA-induced knockdown of TRPC6 expression in HNSCC-derived cells dramatically inhibited HNSCC-cell invasion but did not significantly alter cell proliferation. Importantly, amplification and concomitant overexpression of TRPC6 was also found in HNSCC tumour samples. Conclusions: Altogether, these data show that TRPC6 is likely to be a target for 11q21-22.2 amplification that confers enhanced invasive behavior to HNSCC cells. Therefore, TRPC6 may be a promising therapeutic target in the treatment of HNSCC.This work was supported by Instituto de Salud Carlos III-Fondo de Investigacion Sanitaria [FIS PI11/929 to M.-D.C and C. S.]; Red Tematica de Investigacion Cooperativa en Cancer [RD12/0036/0015] Instituto de Salud Carlos III (ISCIII), Spanish Ministry of Economy and Competitiveness & European Regional Development Fund (ERDF); and Obra Social CajAstur-Instituto Universitario de Oncologia del Principado de Asturias.Bernaldo De Quirós, S.; Merlo, A.; Secades, P.; Zambrano, I.; Saenz De Santa María, I.; Ugidos, N.; Jantus Lewintre, E.... (2013). Identification of TRPC6 as a possible candidate target gene within an amplicon at 11q21-q22.2 for migratory capacity in head and neck squamous cell carcinomas. 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Update on biomarkers for the detection of lung cancer

Eloisa Jantus-Lewintre,1 Marta Usó,1 Elena Sanmartín,1 Carlos Camps,1–31Molecular Oncology Laboratory, Fundación para la Investigación del Hospital General Universitario, Valencia, Spain; 2Deparment of Medical Oncology, Consorcio Hospital General Universitario, Valencia, Spain; 3Department of Medicine, Universitat de València, Valencia, SpainAbstract: Patients at risk for lung cancer may have subclinical disease for years before presentation. The diagnosis of this disease is primarily based on symptoms, and detection often occurs after curative intervention is no longer possible. At present, no lung cancer early-detection biomarker is clinically available. This study reviews the most recent advances in early detection and molecular diagnostic biomarkers for the detection of lung cancer. This review includes an overview of the various biological specimens and matrices in which these biomarkers could be analyzed, as well as the diverse strategies and approaches for identifying new biomarkers that are currently being explored. Several novel and attractive biomarker candidates for the early detection of lung cancer exist. A remarkable shift is taking place from research based on single markers to analyzing signatures that are more complex in order to take advantage of new high-throughput technologies. However, it is still necessary to validate the most promising markers and the standardization of procedures that will lead to specific clinical applications.Keywords: biomarker, detection, lung cancer, diagnosi