Your search keyword '"Natascha Santacroce"' showing total 11 results

1. Tracking and characterization of partial and full epithelial-mesenchymal transition cells in a mouse model of metastatic breast cancer

Author

Fabiana Lüönd, Natascha Santacroce, Christian Beisel, Laurent Guérard, Thomas R. Bürglin, Gerhard Christofori, and Nami Sugiyama

Subjects

Cell Biology, Single Cell, Flow Cytometry/Mass Cytometry, Cancer, RNAseq, Microscopy, Science (General), Q1-390

Abstract

Summary: The various stages of epithelial-mesenchymal transition (EMT) generate phenotypically heterogeneous populations of cells. Here, we detail a dual recombinase lineage tracing system using a transgenic mouse model of metastatic breast cancer to trace and characterize breast cancer cells at different EMT stages. We describe analytical steps to label cancer cells at an early partial or a late full EMT state, followed by tracking their behavior in tumor slice cultures. We then characterize their transcriptome by five-cell RNA sequencing.For complete details on the use and execution of this protocol, please refer to Luond et al. (2021). : Publisher’s note: Undertaking any experimental protocol requires adherence to local institutional guidelines for laboratory safety and ethics.

Published

2022

2. Quantification of the spread of SARS-CoV-2 variant B.1.1.7 in Switzerland

Author

Chaoran Chen, Sarah Ann Nadeau, Ivan Topolsky, Marc Manceau, Jana S. Huisman, Kim Philipp Jablonski, Lara Fuhrmann, David Dreifuss, Katharina Jahn, Christiane Beckmann, Maurice Redondo, Christoph Noppen, Lorenz Risch, Martin Risch, Nadia Wohlwend, Sinem Kas, Thomas Bodmer, Tim Roloff, Madlen Stange, Adrian Egli, Isabella Eckerle, Laurent Kaiser, Rebecca Denes, Mirjam Feldkamp, Ina Nissen, Natascha Santacroce, Elodie Burcklen, Catharine Aquino, Andreia Cabral de Gouvea, Maria Domenica Moccia, Simon Grüter, Timothy Sykes, Lennart Opitz, Griffin White, Laura Neff, Doris Popovic, Andrea Patrignani, Jay Tracy, Ralph Schlapbach, Emmanouil T. Dermitzakis, Keith Harshman, Ioannis Xenarios, Henri Pegeot, Lorenzo Cerutti, Deborah Penet, Anthony Blin, Melyssa Elies, Christian L. Althaus, Christian Beisel, Niko Beerenwinkel, Martin Ackermann, and Tanja Stadler

Subjects

Pandemic, SARS-CoV-2, COVID-19, B.1.1.7, Transmission advantage, Infectious and parasitic diseases, RC109-216

Abstract

Background: In December 2020, the United Kingdom (UK) reported a SARS-CoV-2 Variant of Concern (VoC) which is now named B.1.1.7. Based on initial data from the UK and later data from other countries, this variant was estimated to have a transmission fitness advantage of around 40–80 % (Volz et al., 2021; Leung et al., 2021; Davies et al., 2021). Aim: This study aims to estimate the transmission fitness advantage and the effective reproductive number of B.1.1.7 through time based on data from Switzerland. Methods: We generated whole genome sequences from 11.8 % of all confirmed SARS-CoV-2 cases in Switzerland between 14 December 2020 and 11 March 2021. Based on these data, we determine the daily frequency of the B.1.1.7 variant and quantify the variant’s transmission fitness advantage on a national and a regional scale. Results: We estimate B.1.1.7 had a transmission fitness advantage of 43–52 % compared to the other variants circulating in Switzerland during the study period. Further, we estimate B.1.1.7 had a reproductive number above 1 from 01 January 2021 until the end of the study period, compared to below 1 for the other variants. Specifically, we estimate the reproductive number for B.1.1.7 was 1.24 [1.07–1.41] from 01 January until 17 January 2021 and 1.18 [1.06–1.30] from 18 January until 01 March 2021 based on the whole genome sequencing data. From 10 March to 16 March 2021, once B.1.1.7 was dominant, we estimate the reproductive number was 1.14 [1.00–1.26] based on all confirmed cases. For reference, Switzerland applied more non-pharmaceutical interventions to combat SARS-CoV-2 on 18 January 2021 and lifted some measures again on 01 March 2021. Conclusion: The observed increase in B.1.1.7 frequency in Switzerland during the study period is as expected based on observations in the UK. In absolute numbers, B.1.1.7 increased exponentially with an estimated doubling time of around 2–3.5 weeks. To monitor the ongoing spread of B.1.1.7, our plots are available online.

Published

2021

3. Swiss public health measures associated with reduced SARS-CoV-2 transmission using genome data

Author

Sarah A. Nadeau, Timothy G. Vaughan, Christiane Beckmann, Ivan Topolsky, Chaoran Chen, Emma Hodcroft, Tobias Schär, Ina Nissen, Natascha Santacroce, Elodie Burcklen, Pedro Ferreira, Kim Philipp Jablonski, Susana Posada-Céspedes, Vincenzo Capece, Sophie Seidel, Noemi Santamaria de Souza, Julia M. Martinez-Gomez, Phil Cheng, Philipp P. Bosshard, Mitchell P. Levesque, Verena Kufner, Stefan Schmutz, Maryam Zaheri, Michael Huber, Alexandra Trkola, Samuel Cordey, Florian Laubscher, Ana Rita Gonçalves, Sébastien Aeby, Trestan Pillonel, Damien Jacot, Claire Bertelli, Gilbert Greub, Karoline Leuzinger, Madlen Stange, Alfredo Mari, Tim Roloff, Helena Seth-Smith, Hans H. Hirsch, Adrian Egli, Maurice Redondo, Olivier Kobel, Christoph Noppen, Louis du Plessis, Niko Beerenwinkel, Richard A. Neher, Christian Beisel, and Tanja Stadler

Subjects

360 Social problems & social services, 360 Soziale Probleme, Sozialdienste, 610 Medicine & health, General Medicine, 610 Medizin und Gesundheit

Abstract

Genome sequences from evolving infectious pathogens allow quantification of case introductions and local transmission dynamics. We sequenced 11,357 severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) genomes from Switzerland in 2020—the sixth largest effort globally. Using a representative subset of these data, we estimated viral introductions to Switzerland and their persistence over the course of 2020. We contrasted these estimates with simple null models representing the absence of certain public health measures. We show that Switzerland’s border closures decoupled case introductions from incidence in neighboring countries. Under a simple model, we estimate an 86 to 98% reduction in introductions during Switzerland’s strictest border closures. Furthermore, the Swiss 2020 partial lockdown roughly halved the time for sampled introductions to die out. Last, we quantified local transmission dynamics once introductions into Switzerland occurred using a phylodynamic model. We found that transmission slowed 35 to 63% upon outbreak detection in summer 2020 but not in fall. This finding may indicate successful contact tracing over summer before overburdening in fall. The study highlights the added value of genome sequencing data for understanding transmission dynamics.

Published

2023

4. Swiss public health measures associated with reduced SARS-CoV-2 transmission using genome data

Author

Richard A. Neher, Chaoran Chen, Michael Huber, Claire Bertelli, Vincenzo Capece, Maryam Zaheri, Christoph Noppen, Olivier Kobel, Tobias Schaer, Sarah Nadeau, Stefan Schmutz, Mitchell P. Levesque, Ivan Topolsky, Gilbert Greub, Hans H. Hirsch, Niko Beerenwinkel, Christian Beisel, Philipp P. Bosshard, Ina Nissen, Susana Posada-Cespedes, Tim Roloff, Ana Rita Gonçalves, Christiane Beckmann, Maurice Redondo, Damien Jacot, Timothy G. Vaughan, Adrian Egli, Alexandra Trkola, Verena Kufner, Samuel Cordey, Julia M. Martinez-Gomez, Kim Philipp Jablonski, Alfredo Mari, Natascha Santacroce, Pedro Ferreira, Karoline Leuzinger, Madlen Stange, Phil F. Cheng, Noemi Santamaria de Souza, Trestan Pillonel, Emma B. Hodcroft, Sébastien Aeby, Elodie Burcklen, Tanja Stadler, Florian Laubscher, Helena M. B. Seth-Smith, and Sophie Seidel

Subjects

medicine.medical_specialty, Coronavirus disease 2019 (COVID-19), Public health, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Outbreak, Biology, Genome, DNA sequencing, law.invention, Transmission (mechanics), Evolutionary biology, law, medicine, Contact tracing

Abstract

Genome sequences from evolving infectious pathogens allow quantification of case introductions and local transmission dynamics. We sequenced 11,357 SARS-CoV-2 genomes from Switzerland in 2020 - the 6th largest effort globally. Using a representative subset of these data, we estimated viral introductions to Switzerland and their persistence over the course of 2020. We contrast these estimates with simple null models representing the absence of certain public health measures. We show that Switzerland’s border closures de-coupled case introductions from incidence in neighboring countries. Under a simple model, we estimate an 86 - 98% reduction in introductions during Switzerland’s strictest border closures. Furthermore, the Swiss 2020 partial lockdown roughly halved the time for sampled introductions to die out. Finally, we quantified local transmission dynamics once introductions into Switzerland occurred, using a novel phylodynamic model. We find that transmission slowed 35 – 63% upon outbreak detection in summer 2020, but not in fall. This finding may indicate successful contact tracing over summer before overburdening in fall. The study highlights the added value of genome sequencing data for understanding transmission dynamics.One Sentence SummaryPhylogenetic and phylodynamic methods quantify the drop in case introductions and local transmission with implementation of public health measures.

Published

2021

5. Quantification of the spread of SARS-CoV-2 variant B.1.1.7 in Switzerland

Author

Christoph Noppen, Doris Popovic, Christian L. Althaus, Lorenz Risch, Olivier Kobel, Deborah Penet, Sinem Kas, Martin Ackermann, Chaoran Chen, Ivan Topolsky, Lara Fuhrmann, Ina Nissen, Katharina Jahn, Rebecca Denes, Melyssa Elies, Christiane Beckmann, Keith Harshman, Christian Beisel, Tim Roloff, Simon Grüter, Natascha Santacroce, Kim Philipp Jablonski, Nadia Wohlwend, Maria Domenica Moccia, Catharine Aquino, Adrian Egli, Niko Beerenwinkel, Lennart Opitz, Maurice Redondo, Henri Pegeot, Jana S. Huisman, Thomas Bodmer, Laurent Kaiser, Ioannis Xenarios, Ralph Schlapbach, Andreia Cabral de Gouvea, Madlen Stange, Sarah Nadeau, Laura Neff, Jay Tracy, David Dreifuss, Elodie Burcklen, Tanja Stadler, Griffin White, Isabella Eckerle, Marc Manceau, Anthony Blin, Lorenzo Cerutti, Mirjam Feldkamp, Emmanouil T. Dermitzakis, Martin Risch, Andrea Patrignani, and Timothy Sykes

Subjects

2019-20 coronavirus outbreak, Transmission (mechanics), Surveillance data, Coronavirus disease 2019 (COVID-19), law, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Statistics, Point estimation, Biology, law.invention

Abstract

BackgroundIn December 2020, the United Kingdom (UK) reported a SARS-CoV-2 Variant of Concern (VoC) which is now named B.1.1.7. Based on initial data from the UK and later data from other countries, this variant was estimated to have a transmission fitness advantage of around 40-80% [1, 2, 3].AimThis study aims to estimate the transmission fitness advantage and the effective reproductive number of B.1.1.7 through time based on data from Switzerland.MethodsWe generated whole genome sequences from 11.8% of all confirmed SARS-CoV-2 cases in Switzerland between 14 December 2020 and 11 March 2021. Based on these data, we determine the daily frequency of the B.1.1.7 variant and quantify the variant’s transmission fitness advantage on a national and a regional scale.ResultsWe estimate B.1.1.7 had a transmission fitness advantage of 43-52% compared to the other variants circulating in Switzerland during the study period. Further, we estimate B.1.1.7 had a reproductive number above 1 from 01 January 2021 until the end of the study period, compared to below 1 for the other variants. Specifically, we estimate the reproductive number for B.1.1.7 was 1.24 [1.07-1.41] from 01 January until 17 January 2021 and 1.18 [1.06-1.30] from 18 January until 01 March 2021 based on the whole genome sequencing data. From 10 March to 16 March 2021, once B.1.1.7 was dominant, we estimate the reproductive number was 1.14 [1.00-1.26] based on all confirmed cases. For reference, Switzerland applied more non-pharmaceutical interventions to combat SARS-CoV-2 on 18 January 2021 and lifted some measures again on 01 March 2021.ConclusionThe observed increase in B.1.1.7 frequency in Switzerland during the study period is as expected based on observations in the UK. In absolute numbers, B.1.1.7 increased exponentially with an estimated doubling time of around 2-3.5 weeks. To monitor the ongoing spread of B.1.1.7, our plots are available online.

Published

2021

6. Establishing standardized immune phenotyping of metastatic melanoma by digital pathology

Author

Bettina Sobottka, Marta Nowak, Anja Laura Frei, Martina Haberecker, Samuel Merki, Mitchell P. Levesque, Reinhard Dummer, Holger Moch, Viktor Hendrik Koelzer, Rudolf Aebersold, Melike Ak, Faisal S. Al-Quaddoomi, Jonas Albinus, Ilaria Alborelli, Sonali Andani, Per-Olof Attinger, Marina Bacac, Daniel Baumhoer, Beatrice Beck-Schimmer, Niko Beerenwinkel, Christian Beisel, Lara Bernasconi, Anne Bertolini, Bernd Bodenmiller, Ximena Bonilla, Ruben Casanova, Stéphane Chevrier, Natalia Chicherova, Maya D'Costa, Esther Danenberg, Natalie Davidson, Monica-Andreea Drăganmoch, Stefanie Engler, Martin Erkens, Katja Eschbach, Cinzia Esposito, André Fedier, Pedro Ferreira, Joanna Ficek, Bruno Frey, Sandra Goetze, Linda Grob, Gabriele Gut, Detlef Günther, Pirmin Haeuptle, Viola Heinzelmann-Schwarz, Sylvia Herter, Rene Holtackers, Tamara Huesser, Anja Irmisch, Francis Jacob, Andrea Jacobs, Tim M. Jaeger, Katharina Jahn, Alva R. James, Philip M. Jermann, André Kahles, Abdullah Kahraman, Werner Kuebler, Jack Kuipers, Christian P. Kunze, Christian Kurzeder, Kjong-Van Lehmann, Sebastian Lugert, Gerd Maass, Markus G. Manz, Philipp Markolin, Julien Mena, Ulrike Menzel, Julian M. Metzler, Nicola Miglino, Emanuela S. Milani, Simone Muenst, Riccardo Murri, Charlotte K.Y. Ng, Stefan Nicolet, Patrick G.A. Pedrioli, Lucas Pelkmans, Salvatore Piscuoglio, Michael Prummer, Mathilde Ritter, Christian Rommel, María L. Rosano-González, Gunnar Rätsch, Natascha Santacroce, Jacobo Sarabia del Castillo, Ramona Schlenker, Petra C. Schwalie, Severin Schwan, Tobias Schär, Gabriela Senti, Franziska Singer, Sujana Sivapatham, Berend Snijder, Vipin T. Sreedharan, Stefan Stark, Daniel J. Stekhoven, Alexandre P.A. Theocharides, Tinu M. Thomas, Markus Tolnay, Vinko Tosevski, Nora C. Toussaint, Mustafa A. Tuncel, Marina Tusup, Audrey Van Drogen, Marcus Vetter, Tatjana Vlajnic, Sandra Weber, Walter P. Weber, Rebekka Wegmann, Michael Weller, Fabian Wendt, Norbert Wey, Andreas Wicki, Mattheus HE Wildschut, Bernd Wollscheid, Shuqing Yu, Johanna Ziegler, Marc Zimmermann, Martin Zoche, Gregor Zuend, University of Zurich, Sobottka-Brillout, Bettina, and Koelzer, Viktor Hendrik

Subjects

Pathology, medicine.medical_specialty, Stromal cell, 610 Medicine & health, Disease, Predictive markers, Article, Pathology and Forensic Medicine, 1307 Cell Biology, Immune system, 10049 Institute of Pathology and Molecular Pathology, 1312 Molecular Biology, Medicine, Compartment (pharmacokinetics), Molecular Biology, Melanoma, business.industry, 10177 Dermatology Clinic, Digital pathology, 10060 Epidemiology, Biostatistics and Prevention Institute (EBPI), Cell Biology, Biomarker (cell), 2734 Pathology and Forensic Medicine, 10032 Clinic for Oncology and Hematology, Cohort, Imaging the immune system, business, CD8

Abstract

CD8+ tumor-infiltrating T cells can be regarded as one of the most relevant predictive biomarkers in immune-oncology. Highly infiltrated tumors, referred to as inflamed (clinically “hot”), show the most favorable response to immune checkpoint inhibitors in contrast to tumors with a scarce immune infiltrate called immune desert or excluded (clinically “cold”). Nevertheless, quantitative and reproducible methods examining their prevalence within tumors are lacking. We therefore established a computational diagnostic algorithm to quantitatively measure spatial densities of tumor-infiltrating CD8+ T cells by digital pathology within the three known tumor compartments as recommended by the International Immuno-Oncology Biomarker Working Group in 116 prospective metastatic melanomas of the Swiss Tumor Profiler cohort. Workflow robustness was confirmed in 33 samples of an independent retrospective validation cohort. The introduction of the intratumoral tumor center compartment proved to be most relevant for establishing an immune diagnosis in metastatic disease, independent of metastatic site. Cut-off values for reproducible classification were defined and successfully assigned densities into the respective immune diagnostic category in the validation cohort with high sensitivity, specificity, and precision. We provide a robust diagnostic algorithm based on intratumoral and stromal CD8+ T-cell densities in the tumor center compartment that translates spatial densities of tumor-infiltrating CD8+ T cells into the clinically relevant immune diagnostic categories “inflamed”, “excluded”, and “desert”. The consideration of the intratumoral tumor center compartment allows immune phenotyping in the clinically highly relevant setting of metastatic lesions, even if the invasive margin compartment is not captured in biopsy material., The authors present a robust diagnostic algorithm based on digital pathology and image analysis that quantifies intratumoral and stromal CD8+ T-cell densities in the tumor center and invasive margin compartment in metastatic melanoma. Spatial CD8+ T-cell densities are translated into the clinically relevant immune diagnostic categories “inflamed”, “excluded”, and “desert”. Their approach also allows efficient immune phenotyping of metastatic lesions, on biopsy material or even in the absence of material from the invasive margin.

Published

2021

7. The Tumor Profiler Study: integrated, multi-omic, functional tumor profiling for clinical decision support

Author

René Holtackers, Simone Muenst, Martin Zoche, Rudolf Aebersold, Stéphane Chevrier, Tobias Schär, Bettina Sobottka, Marc Zimmermann, Abdullah Kahraman, Lucas Pelkmans, Faisal Alquaddoomi, Philip Jermann, Natascha Santacroce, Andreas Wicki, Norbert Wey, Nora C. Toussaint, Monica-Andreea Drăgan, Mattheus H.E. Wildschut, Ruben Casanova, Shuqing Yu, Markus Tolnay, Marcus Vetter, Mustafa Anil Tuncel, Ximena Bonilla, Stefan Nicolet, Gabriele Gut, Stefan G. Stark, Philipp Markolin, Bruno S. Frey, Ramona Schlenker, Rebekka Wegmann, Walter P. Weber, Lara Bernasconi, Emanuela S. Milani, Viktor H. Koelzer, Christian Rommel, Christian P. Kunze, Sylvia Herter, Cinzia Esposito, Gabriela Senti, Michael Prummer, Katja Eschbach, Bernd Wollscheid, Riccardo Murri, Salvatore Piscuoglio, Mathilde Ritter, Mitchell P. Levesque, Christian Beisel, Tim M. Jaeger, Viola Heinzelmann-Schwarz, Gunnar Rätsch, Severin Schwan, Marina Bacac, Reinhard Dummer, Joanna Ficek, Sandra Goetze, Tatjana Vlajnic, Martin Erkens, Ilaria Alborelli, Ulrike Menzel, Vinko Tosevski, Markus G. Manz, Werner Kuebler, Detlef Günther, Julian M. Metzler, Daniel J. Stekhoven, Christian Kurzeder, Anja Frei, Tamara Huesser, Marta Nowak, Melike Ak, Francis Jacob, Gregor Zuend, Berend Snijder, Martina Haberecker, Pirmin Haeuptle, Anja Irmisch, Maya D'Costa, Linda Grob, Natalia Chicherova, Bernd Bodenmiller, Johanna Ziegler, Per-Olof Attinger, Jack Kuipers, Katharina Jahn, Nicola Miglino, Natalie R. Davidson, Jacobo Sarabia del Castillo, André Fedier, Fabian Wendt, Esther Danenberg, Pedro Ferreira, María Lourdes Rosano-Gonzalez, Sebastian Lugert, Andrea Jacobs, Charlotte K.Y. Ng, Alva Rani James, Tinu M. Thomas, André Kahles, Gerd Maass, Julien Mena, Jonas B. Albinus, Daniel Baumhoer, Sonali Andani, Petra C. Schwalie, Anne Bertolini, Marina Tusup, Franziska Singer, Alexandre Theocharides, Sandra Weber, Beatrice Beck-Schimmer, Sujana Sivapatham, Kjong-Van Lehmann, Stefanie Engler, Holger Moch, Niko Beerenwinkel, Vipin T. Sreedharan, Michael Weller, Audrey Van Drogen, Patrick G. A. Pedrioli, University of Zurich, Rätsch, Gunnar, and Levesque, Mitchell Paul

Subjects

0301 basic medicine, Decision support system, Cancer Research, Computer science, Observational Trial, Clinical Decision-Making, 610 Medicine & health, Computational biology, Clinical decision support system, 1307 Cell Biology, 03 medical and health sciences, 0302 clinical medicine, Neoplasms, 10049 Institute of Pathology and Molecular Pathology, Humans, Profiling (information science), 1306 Cancer Research, Prospective Studies, Precision Medicine, business.industry, Computational Biology, 10177 Dermatology Clinic, 10060 Epidemiology, Biostatistics and Prevention Institute (EBPI), Cell Biology, Decision Support Systems, Clinical, 030104 developmental biology, Oncology, 030220 oncology & carcinogenesis, 10032 Clinic for Oncology and Hematology, 2730 Oncology, Personalized medicine, business, 11493 Department of Quantitative Biomedicine

Abstract

The application and integration of molecular profiling technologies create novel opportunities for personalized medicine. Here, we introduce the Tumor Profiler Study, an observational trial combining a prospective diagnostic approach to assess the relevance of in-depth tumor profiling to support clinical decision-making with an exploratory approach to improve the biological understanding of the disease.

Published

2021

8. Quantifying SARS-CoV-2 spread in Switzerland based on genomic sequencing data

Author

Elodie Burcklen, Tanja Stadler, Verena Kufner, Alfredo Mari, Samuel Cordey, Sarah Nadeau, Mitchell P. Levesque, Tobias Schaer, Michael Huber, Susana Posada-Cespedes, Richard A. Neher, Pedro Ferreira, Julia M. Martinez-Gomez, Adrian Egli, Emma B. Hodcroft, Christoph Noppen, Alexandra Trkola, Helena M.B. Seth-Smith, Timothy G. Vaughan, Christian Beisel, Ina Nissen, Olivier Kobel, Kim Philipp Jablonski, Niko Beerenwinkel, Philipp P. Bosshard, Ivan Topolsky, Madlen Stange, Natascha Santacroce, Ana Rita Gonçalves, Christiane Beckmann, Tim Roloff, Maryam Zaheri, Hans H. Hirsch, Sophie Seidel, Phil F. Cheng, Stefan Schmutz, Karoline Leuzinger, Maurice Redondo, Vincenzo Capece, Noemi Santamaria de Souza, and Florian Laubscher

Subjects

2019-20 coronavirus outbreak, Transmission (mechanics), law, Evolutionary biology, Genomic data, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Lineage (evolution), Genomic sequencing, Epidemic spread, Biology, Genome, law.invention

Abstract

Pathogen genomes provide insights into their evolution and epidemic spread. We sequenced 1,439 SARS-CoV-2 genomes from Switzerland, representing 3-7% of all confirmed cases per week. Using these data, we demonstrate that no one lineage became dominant, pointing against evolution towards general lower virulence. On an epidemiological level, we report no evidence of cryptic transmission before the first confirmed case. We find many early viral introductions from Germany, France, and Italy and many recent introductions from Germany and France. Over the summer, we quantify the number of non-traceable infections stemming from introductions, quantify the effective reproductive number, and estimate the degree of undersampling. Our framework can be applied to quantify evolution and epidemiology in other locations or for other pathogens based on genomic data.One Sentence SummaryWe quantify SARS-CoV-2 spread in Switzerland based on genome sequences from our nation-wide sequencing effort.

Published

2020

9. Within-patient genetic diversity of SARS-CoV-2

Author

Christian Beisel, Ivan Topolsky, Jack Kuipers, Ina Nissen, Sophie Seidel, Christiane Beckmann, Fritz Bayer, Nico Borgsmüller, Kim Philipp Jablonski, Noemi Santamaria de Souza, Vincenzo Capece, Christoph Noppen, Sarah Nadeau, Niko Beerenwinkel, Olivier Kobel, Susana Posada-Cespedes, Martin Pirkl, Maurice Redondo, Tobias Schär, Pedro Ferreira, Natascha Santacroce, Arthur Dondi, Monica-Andreea Drăgan, Aashil A. Batavia, Elodie Burcklen, Tanja Stadler, Katharina Jahn, and Lisa Lamberti

Subjects

Genetic diversity, Genetic heterogeneity, media_common.quotation_subject, respiratory system, Biology, medicine.disease_cause, Genome, Virus, Evolutionary biology, Pandemic, medicine, human activities, Gene, Coronavirus, Diversity (politics), media_common

Abstract

SARS-CoV-2, the virus responsible for the current COVID-19 pandemic, is evolving into different genetic variants by accumulating mutations as it spreads globally. In addition to this diversity of consensus genomes across patients, RNA viruses can also display genetic diversity within individual hosts, and co-existing viral variants may affect disease progression and the success of medical interventions. To systematically examine the intra-patient genetic diversity of SARS-CoV-2, we processed a large cohort of 3939 publicly-available deeply sequenced genomes with specialised bioinformatics software, along with 749 recently sequenced samples from Switzerland. We found that the distribution of diversity across patients and across genomic loci is very unbalanced with a minority of hosts and positions accounting for much of the diversity. For example, the D614G variant in the Spike gene, which is present in the consensus sequences of 67.4% of patients, is also highly diverse within hosts, with 29.7% of the public cohort being affected by this coexistence and exhibiting different variants. We also investigated the impact of several technical and epidemiological parameters on genetic heterogeneity and found that age, which is known to be correlated with poor disease outcomes, is a significant predictor of viral genetic diversity.Author SummarySince it arose in late 2019, the new coronavirus (SARS-CoV-2) behind the COVID-19 pandemic has mutated and evolved during its global spread. Individual patients may host different versions, or variants, of the virus, hallmarked by different mutations. We examine the diversity of genetic variants coexisting within patients across a cohort of 3939 publicly accessible samples and 749 recently sequenced samples from Switzerland. We find that a small number of patients carry most of the diversity, and that patients with more diversity tend to be older. We also find that most of the diversity is concentrated in certain regions and positions of the virus genome. In particular, we find that a variant reported to increase infectivity is among the most diverse positions. Our study provides a large-scale survey of within-patient diversity of the SARS-CoV-2 genome.

Published

2020

10. Distinct contributions of partial and full EMT to breast cancer malignancy

Author

Gerhard Christofori, Fabiana Lüönd, Natascha Santacroce, Carolina Hager, Fengyuan Tang, Nami Sugiyama, Stefanie Tiede, Thomas R. Bürglin, Robert Ivanek, Christian Beisel, Ruben Bill, Jacco van Rheenen, and Laura Bornes

Subjects

Epithelial-Mesenchymal Transition, Lung Neoplasms, Cell, Antineoplastic Agents, Apoptosis, Breast Neoplasms, Mice, SCID, Biology, Malignancy, General Biochemistry, Genetics and Molecular Biology, Metastasis, Mice, Breast cancer, Cell Movement, Mice, Inbred NOD, Live cell imaging, Biomarkers, Tumor, Tumor Cells, Cultured, medicine, Animals, Humans, Neoplasm Invasiveness, Molecular Biology, Cell Proliferation, Sequence Analysis, RNA, Mesenchymal stem cell, Cell Biology, medicine.disease, Xenograft Model Antitumor Assays, Metastatic breast cancer, Gene Expression Regulation, Neoplastic, medicine.anatomical_structure, Drug Resistance, Neoplasm, embryonic structures, Cancer cell, Cancer research, Female, Developmental Biology

Abstract

Epithelial-mesenchymal transition (EMT) is a transient, reversible process of cell de-differentiation where cancer cells transit between various stages of an EMT continuum, including epithelial, partial EMT, and mesenchymal cell states. We have employed Tamoxifen-inducible dual recombinase lineage tracing systems combined with live imaging and 5-cell RNA sequencing to track cancer cells undergoing partial or full EMT in the MMTV-PyMT mouse model of metastatic breast cancer. In primary tumors, cancer cells infrequently undergo EMT and mostly transition between epithelial and partial EMT states but rarely reach full EMT. Cells undergoing partial EMT contribute to lung metastasis and chemoresistance, whereas full EMT cells mostly retain a mesenchymal phenotype and fail to colonize the lungs. However, full EMT cancer cells are enriched in recurrent tumors upon chemotherapy. Hence, cancer cells in various stages of the EMT continuum differentially contribute to hallmarks of breast cancer malignancy, such as tumor invasion, metastasis, and chemoresistance., Developmental Cell, 56 (23), ISSN:1534-5807, ISSN:1878-1551

Published

2021

11. Quantification of the spread of SARS-CoV-2 variant B.1.1.7 in Switzerland

Author

Chaoran Chen, Isabella Eckerle, Marc Manceau, Maria Domenica Moccia, Lennart Opitz, Adrian Egli, Lorenz Risch, Sarah Nadeau, Griffin White, Martin Ackermann, Laura Neff, Sinem Kas, Anthony Blin, Ina Nissen, Thomas Bodmer, Keith Harshman, Katharina Jahn, Jana S. Huisman, Andrea Patrignani, Tim Roloff, Niko Beerenwinkel, Elodie Burcklen, Tanja Stadler, Ralph Schlapbach, Melyssa Elies, Rebecca Denes, Simon Grüter, Christiane Beckmann, Kim Philipp Jablonski, Christian Beisel, Timothy Sykes, Christoph Noppen, Doris Popovic, Lorenzo Cerutti, Nadia Wohlwend, Henri Pegeot, Emmanouil T. Dermitzakis, Catharine Aquino, Jay Tracy, Andreia Cabral de Gouvea, David Dreifuss, Martin Risch, Mirjam Feldkamp, Lara Fuhrmann, Natascha Santacroce, Maurice Redondo, Christian L. Althaus, Deborah Penet, Laurent Kaiser, Ivan Topolsky, Madlen Stange, and Ioannis Xenarios

Subjects

2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), Epidemiology, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), 610 Medicine & health, Infectious and parasitic diseases, RC109-216, Biology, Time based, Microbiology, Article, law.invention, law, 360 Social problems & social services, Virology, Humans, Transmission advantage, B.1.1.7, ddc:616, Pandemic, SARS-CoV-2, Public Health, Environmental and Occupational Health, COVID-19, United Kingdom, Infectious Diseases, Transmission (mechanics), ddc:540, Parasitology, Switzerland, Demography

Abstract

Background: In December 2020, the United Kingdom (UK) reported a SARS-CoV-2 Variant of Concern (VoC) which is now named B.1.1.7. Based on initial data from the UK and later data from other countries, this variant was estimated to have a transmission fitness advantage of around 40–80 % (Volz et al., 2021; Leung et al., 2021; Davies et al., 2021). Aim: This study aims to estimate the transmission fitness advantage and the effective reproductive number of B.1.1.7 through time based on data from Switzerland. Methods: We generated whole genome sequences from 11.8 % of all confirmed SARS-CoV-2 cases in Switzerland between 14 December 2020 and 11 March 2021. Based on these data, we determine the daily frequency of the B.1.1.7 variant and quantify the variant's transmission fitness advantage on a national and a regional scale. Results: We estimate B.1.1.7 had a transmission fitness advantage of 43–52 % compared to the other variants circulating in Switzerland during the study period. Further, we estimate B.1.1.7 had a reproductive number above 1 from 01 January 2021 until the end of the study period, compared to below 1 for the other variants. Specifically, we estimate the reproductive number for B.1.1.7 was 1.24 [1.07–1.41] from 01 January until 17 January 2021 and 1.18 [1.06–1.30] from 18 January until 01 March 2021 based on the whole genome sequencing data. From 10 March to 16 March 2021, once B.1.1.7 was dominant, we estimate the reproductive number was 1.14 [1.00–1.26] based on all confirmed cases. For reference, Switzerland applied more non-pharmaceutical interventions to combat SARS-CoV-2 on 18 January 2021 and lifted some measures again on 01 March 2021. Conclusion: The observed increase in B.1.1.7 frequency in Switzerland during the study period is as expected based on observations in the UK. In absolute numbers, B.1.1.7 increased exponentially with an estimated doubling time of around 2–3.5 weeks. To monitor the ongoing spread of B.1.1.7, our plots are available online., Epidemics, 37, ISSN:1878-0067, ISSN:1755-4365