Your search keyword '"Camila A. M. Silva"' showing total 8 results

1. Genomics and epidemiology of the P.1 SARS-CoV-2 lineage in Manaus, Brazil

Author

Esmenia C. Rocha, Vitor H. Nascimento, Pedro S. Peixoto, Thomas A. Mellan, Lucas A M Franco, Henrique Hoeltgebaum, Michaela A. C. Vollmer, Oliver Ratmann, Leonardo José Tadeu de Araújo, Nuno R. Faria, Philippe Lemey, Raphael Sonabend, Myuki A E Crispim, Nelson Gaburo, Charles Whittaker, Joice do P. Silva, Ruben J.G. Hulswit, Ricardo P Schnekenberg, Cecilia da C. Camilo, Mariana C. Pinho, Darlan da Silva Candido, Neil M. Ferguson, Helem M. dos Santos, Ester Cerdeira Sabino, Patrick G T Walker, Hannah M. Schlüter, Carlos A. Prete, Thais M. Coletti, Erika R. Manuli, Oliver G. Pybus, Samir Bhatt, Alessandro C. S. Ferreira, Mariana S. Ramundo, Danielle A G Zauli, Aline B. de Lima, Jaqueline Goes de Jesus, Iwona Hawryluk, Frederico S V Malta, Marc A. Suchard, Leandro Marques de Souza, Seth Flaxman, Moritz U. G. Kraemer, James A. Hay, Valentina S. Del Caro, Rosinaldo M. F. Filho, Axel Gandy, Pamela S Andrade, Andrew Rambaut, Ingra Morales Claro, Ana L. P. dos Santos, Christopher Dye, José Luiz Proença-Módena, Swapnil Mishra, Daniel J Laydon, William Marciel de Souza, Renato Santana Aguiar, Xenia Miscouridou, Camila A. M. Silva, Maria S. Vidal, John T. McCrone, Maria Perpétuo Socorro Sampaio Carvalho, Nicholas J. Loman, Giulia M. Ferreira, Bruce Walker Nelson, Chieh-Hsi Wu, Thomas A. Bowden, Melodie Monod, Helen Coupland, Rafael Henrique Moraes Pereira, Flavia C. S. Sales, Sergei L Kosakovsky Pond, Nelson Abrahim Fraiji, Bill & Melinda Gates Foundation, Wellcome Trust, and Medical Research Council (MRC)

Subjects

DYNAMICS, 0301 basic medicine, MATEMÁTICA APLICADA, Lineage (genetic), General Science & Technology, LOCAL TRANSMISSION, Genomics, Genome, Viral, Communicable Diseases, Emerging, Genome, DNA sequencing, 03 medical and health sciences, 0302 clinical medicine, Molecular evolution, Humans, 030212 general & internal medicine, Molecular clock, Molecular Epidemiology, SITES, Science & Technology, RECEPTOR-BINDING DOMAIN, Multidisciplinary, Molecular epidemiology, biology, SARS-CoV-2, MOLECULAR CLOCK, COVID-19, Models, Theoretical, Viral Load, PERFORMANCE, biology.organism_classification, Virology, 3. Good health, Multidisciplinary Sciences, 030104 developmental biology, Epidemiological Monitoring, Mutation, Spike Glycoprotein, Coronavirus, Science & Technology - Other Topics, Angiotensin-Converting Enzyme 2, RESPIRATORY-SYNDROME-CORONAVIRUS, Brazil, Betacoronavirus, Protein Binding

Abstract

Unmitigated spread in Brazil Despite an extensive network of primary care availability, Brazil has suffered profoundly during the severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) pandemic. Using daily data from state health offices, Castro et al. analyzed the pattern of spread of COVID-19 cases and deaths in the country from February to October 2020. Clusters of deaths before cases became apparent indicated unmitigated spread. SARS-CoV-2 circulated undetected in Brazil for more than a month as it spread north from Sã o Paulo. In Manaus, transmission reached unprecedented levels after a momentary respite in mid-2020. Faria et al. tracked the evolution of a new, more aggressive lineage called P.1, which has 17 mutations, including three (K417T, E484K, and N501Y) in the spike protein. After a period of accelerated evolution, this variant emerged in Brazil during November 2020. Coupled with the emergence of P.1, disease spread was accelerated by stark local inequalities and political upheaval, which compromised a prompt federal response. Science , abh1558 and abh2644, this issue p. 821 and p. 815

Published

2021

2. Neutralisation of SARS-CoV-2 lineage P.1 by antibodies elicited through natural SARS-CoV-2 infection or vaccination with an inactivated SARS-CoV-2 vaccine: an immunological study

Author

Maria Luiza Moretti, Rafael Elias Marques, Mariene R. Amorim, Cecilia da C. Camilo, Gabriela Fabiano de Souza, Pamela S Andrade, Mariana C. Pinho, Audrey Basso Zangirolami, Pierina Lorencini Parise, Carolina Costa-Lima, Lais D. Coimbra, Marcelo A. Mori, Luciana S. Mofatto, Ingra Morales Claro, Nuno R. Faria, Grazielle C. Maktura, Clarice Weis Arns, Myuki A E Crispim, Bruno Deltreggia Benites, Magnun N. N. Santos, Erika R. Manuli, Lucas A M Franco, Mariana S. Ramundo, Darlan da Silva Candido, Camila L. Simeoni, Natalia S Brunetti, José Luiz Proença-Módena, Marcelo Addas-Carvalho, Christopher Dye, Marco Aurélio Ramirez Vinolo, Alessandro S. Farias, Esmenia C. Rocha, Oliver G. Pybus, Thais M. Coletti, Nelson Gaburo, Adriana S. S. Duarte, Stéfanie Primon Muraro, Ester Cerdeira Sabino, Arilson Bernardo dos Santos Pereira Gomes, Michael S. Diamond, Priscilla P. Barbosa, Fernando Rosado Spilki, Karina Bispo-dos-Santos, Fabiana Granja, Flavia C. S. Sales, Daniel A. Toledo-Teixeira, Vitor A. Costa, Rodrigo Nogueira Angerami, William Marciel de Souza, Renata Sesti-Costa, Jaqueline Goes de Jesus, Henrique Marques-Souza, Leandro Marques de Souza, Giulia M. Ferreira, Camila A. M. Silva, Lucas I. Buscaratti, Medical Research Council-São Paulo Research Foundation (FAPESP), Wellcome Trust, and Medical Research Council (MRC)

Subjects

Microbiology (medical), COVID-19 Vaccines, Lineage (genetic), biology, SARS-CoV-2, Vaccination, COVID-19, Articles, Antibodies, Viral, Antibodies, Neutralizing, Microbiology, Virology, United States, Virus, Neutralization, Titer, Infectious Diseases, Immune system, Polyclonal antibodies, biology.protein, Humans, Antibody, Brazil

Abstract

Background Mutations accrued by SARS-CoV-2 lineage P.1—first detected in Brazil in early January, 2021—include amino acid changes in the receptor-binding domain of the viral spike protein that also are reported in other variants of concern, including B.1.1.7 and B.1.351. We aimed to investigate whether isolates of wild-type P.1 lineage SARS-CoV-2 can escape from neutralising antibodies generated by a polyclonal immune response. Methods We did an immunological study to assess the neutralising effects of antibodies on lineage P.1 and lineage B isolates of SARS-CoV-2, using plasma samples from patients previously infected with or vaccinated against SARS-CoV-2. Two specimens (P.1/28 and P.1/30) containing SARS-CoV-2 lineage P.1 (as confirmed by viral genome sequencing) were obtained from nasopharyngeal and bronchoalveolar lavage samples collected from patients in Manaus, Brazil, and compared against an isolate of SARS-CoV-2 lineage B (SARS.CoV2/SP02.2020) recovered from a patient in Brazil in February, 2020. Isolates were incubated with plasma samples from 21 blood donors who had previously had COVID-19 and from a total of 53 recipients of the chemically inactivated SARS-CoV-2 vaccine CoronaVac: 18 individuals after receipt of a single dose and an additional 20 individuals (38 in total) after receipt of two doses (collected 17–38 days after the most recent dose); and 15 individuals who received two doses during the phase 3 trial of the vaccine (collected 134–230 days after the second dose). Antibody neutralisation of P.1/28, P.1/30, and B isolates by plasma samples were compared in terms of median virus neutralisation titre (VNT50, defined as the reciprocal value of the sample dilution that showed 50% protection against cytopathic effects). Findings In terms of VNT50, plasma from individuals previously infected with SARS-CoV-2 had an 8·6 times lower neutralising capacity against the P.1 isolates (median VNT50 30 [IQR Interpretation SARS-CoV-2 lineage P.1 might escape neutralisation by antibodies generated in response to polyclonal stimulation against previously circulating variants of SARS-CoV-2. Continuous genomic surveillance of SARS-CoV-2 combined with antibody neutralisation assays could help to guide national immunisation programmes. Funding São Paulo Research Foundation, Brazilian Ministry of Science, Technology and Innovation and Funding Authority for Studies, Medical Research Council, National Council for Scientific and Technological Development, National Institutes of Health. Translation For the Portuguese translation of the abstract see Supplementary Materials section.

Published

2021

3. Local Transmission of SARS-CoV-2 Lineage B.1.1.7, Brazil, December 2020

Author

Camila A. M. Silva, José Eduardo Levi, Jaqueline Goes de Jesus, Ingra Morales Claro, Oliver G. Pybus, Nuno R. Faria, Mariana S. Ramundo, Flavia C. S. Sales, Cristina Mendes de Oliveira, Ester Cerdeira Sabino, Luciano Cesar Scarpelli, Gustavo Campana, Erika R. Manuli, and Darlan da Silva Candido

Subjects

Microbiology (medical), Adult, Male, 2019-20 coronavirus outbreak, Lineage (genetic), Epidemiology, lineage B.1.1.7, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), 030231 tropical medicine, lcsh:Medicine, Genome, Viral, Biology, lcsh:Infectious and parasitic diseases, 2019 novel coronavirus disease, genomic, 03 medical and health sciences, Young Adult, respiratory infections, 0302 clinical medicine, Phylogenetics, parasitic diseases, Local Transmission of SARS-CoV-2 Lineage B.1.1.7, Brazil, December 2020, Research Letter, Humans, lcsh:RC109-216, viruses, 030212 general & internal medicine, Phylogeny, Travel, Phylogenetic tree, Transmission (medicine), SARS-CoV-2, Genomic sequencing, lcsh:R, transmission, COVID-19, Virology, zoonoses, Infectious Diseases, coronavirus disease, surveillance, Female, Coronavirus Infections, Brazil, severe acute respiratory syndrome coronavirus 2

Abstract

In December 2020, research surveillance detected the B.1.1.7 lineage of severe acute respiratory syndrome coronavirus 2 in Sao Paulo, Brazil. Rapid genomic sequencing and phylogenetic analysis revealed 2 distinct introductions of the lineage. One patient reported no international travel. There may be more infections with this lineage in Brazil than reported.

Published

2021

4. Levels of SARS-CoV-2 Lineage P.1 Neutralization by Antibodies Elicited after Natural Infection and Vaccination

Author

William M. de Souza, Mariene R. Amorim, Renata Sesti-Costa, Lais D. Coimbra, Daniel Augusto de Toledo-Teixeira, Pierina L. Parise, Priscilla P. Barbosa, Karina Bispo-dos-Santos, Luciana S. Mofatto, Camila L. Simeoni, Natalia S. Brunetti, Ingra M. Claro, Adriana S. S. Duarte, Thais M. Coletti, Audrey B. Zangirolami, Carolina Costa-Lima, Arilson Bernardo S. P. Gomes, Lucas I. Buscaratti, Flavia C. Sales, Vitor A. Costa, Lucas A.M. Franco, Darlan S. Candido, Oliver G. Pybus, Jaqueline G. de Jesus, Camila A. M. Silva, Mariana S. Ramundo, Giulia M. Ferreira, Mariana C. Pinho, Leandro M. Souza, Esmenia C. Rocha, Pamela S. Andrade, Myuki A.E. Crispim, Grazielle C. Maktura, Erika R. Manuli, Magnun N.N. Santos, Cecilia C. Camilo, Rodrigo N. Angerami, Maria L. Moretti, Fernando R. Spilki, Clarice W. Arns, Marcelo Addas-Carvalho, Bruno D. Benites, Marcelo A. Mori, Nelson Gaburo, Christopher Dye, Chieh-Hsi Wu, Henrique Marques-Souza, Rafael E. Marques, Alessandro Farias, Michael S. Diamond, Nuno R. Faria, Ester C. Sabino, Fabiana Granja, and Jose Luiz Proenca-Modena

Subjects

Lineage (genetic), biology, Coronavirus disease 2019 (COVID-19), business.industry, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Virology, Neutralization, Virus, Vaccination, Immunization, biology.protein, Medicine, Antibody, business

Abstract

Background: A new SARS-CoV-2 lineage, named P.1 (20J/501Y.V3), has recently been detected in Brazil. Mutations accrued by the P.1 lineage include amino acid changes in the receptor-binding domain of the spike protein that also are reported in variants of concern in the United Kingdom (B.1.1.7) and South Africa (B.1.325). Methods: We isolated two P.1-containing specimens from nasopharyngeal and bronchoalveolar lavage samples of patients of Manaus, Brazil. We measured neutralization of the P.1 virus after incubation with the plasma of 19 COVID-19 convalescent blood donors and recipients of the chemically-inactivated CoronaVac vaccine and compared these results to neutralization of a SARS-CoV-2 B-lineage previously circulating in Brazil. Findings: The immune plasma of COVID-19 convalescent blood donors had 6-fold less neutralizing capacity against the P.1 than against the B-lineage. Moreover, five months after booster immunization with CoronaVac, plasma from vaccinated individuals failed to efficiently neutralize P.1 lineage isolates. Interpretation: These data indicate that the P.1 lineage may escape from neutralizing antibodies generated in response to polyclonal stimulation against previously circulating variants of SARS-CoV-2. Funding: Sao Paulo Research Foundation, MCTI/FINEP, Medical Research Council, National Council for Scientific and Technological Development, National Institutes of Health. Conflict of Interest: M.S.D. is a consultant for Inbios, Vir Biotechnology, NGMBiopharmaceuticals, and Carnival Corporation, and on the Scientific Advisory Boards of Moderna and Immunome. The Diamond laboratory has received funding support in sponsored research agreements from Moderna, Vir Biotechnology, and Emergent BioSolutions. Ethical Approval: All procedures followed the ethical standards of the responsible committee on humanexperimentation and approved by the ethics committees from the University of Campinas, Brazil (Approval number CONEP 4.021.484 for plasma collection of blood donors, CAEE32078620.4.0000.5404 and 30227920.9.0000.5404 for the sampling of vaccinated and viral genome sequencing, respectively). All patient data were anonymized before study inclusion.Informed consent was obtained from all subjects for being included in the study.

Published

2021

5. Inflammasome activation in COVID-19 patients

Author

Natalia B. do Amaral, Keyla Sg Sa, Fabiani Gai Frantz, Adriene Y. Ishimoto, Juliana E Toller-Kawahisa, Amanda Becerra, Italo A. Castro, Rodrigo Luppino-Assad, Debora B. Perucello, Fernando Crivelenti Vilar, Letícia Yamawaka de Almeida, Flávio P. Veras, Fernando Q. Cunha, Thiago M. Cunha, Augusto V. Gonçalves, Daniele C. Nascimento, Sergio Cl Almeida, Dario S. Zamboni, Marjorie Cornejo Pontelli, Fabiola Reis de Oliveira, Rene Dr de Oliveira, Mikhael Hf de Lima, Samuel L. Oliveira, Rodrigo de Carvalho Santana, Paulo Louzada-Junior, Letícia Pastorelli Bonjorno, Maria Isabel Fernandes Lopes, José C. Alves-Filho, Maria Auxiliadora-Martins, Eurico Arruda, Maira N. Benatti, Ronaldo B. Martins, Marcela C Giannini, Warrison A. Andrade, Fábio Cury de Barros, Diego B. Caetite, Sabrina Setembre Batah, Tamara S Rodrigues, Camila A. M. Silva, Li Siyuan, Tiana Kohlsdorf, Larissa D. Cunha, Alexandre Todorovic Fabro, and Ricardo M. C. Castro

Subjects

Coronavirus disease 2019 (COVID-19), business.industry, Autopsy, Inflammasome, Inflammation, Disease, Peripheral blood mononuclear cell, Pathophysiology, Immunology, Inflammatory molecules, medicine, medicine.symptom, business, medicine.drug

Abstract

Severe cases of COVID-19 are characterized by a strong inflammatory process that may ultimately lead to organ failure and patient death. The NLRP3 inflammasome is a molecular platform that promotes inflammation via cleavage and activation of key inflammatory molecules including active caspase-1 (Casp1p20), IL-1β and IL-18. Although the participation of the inflammasome in COVID-19 has been highly speculated, the inflammasome activation and participation in the outcome of the disease is unknown. Here we demonstrate that the NLRP3 inflammasome is activated in response to SARS-CoV-2 infection and it is active in COVID-19, influencing the clinical outcome of the disease. Studying moderate and severe COVID-19 patients, we found active NLRP3 inflammasome in PBMCs and tissues of post-mortem patients upon autopsy. Inflammasome-derived products such as Casp1p20 and IL-18 in the sera correlated with the markers of COVID-19 severity, including IL-6 and LDH. Moreover, higher levels of IL-18 and Casp1p20 are associated with disease severity and poor clinical outcome. Our results suggest that the inflammasome is key in the pathophysiology of the disease, indicating this platform as a marker of disease severity and a potential therapeutic target for COVID-19.

Published

2020

6. Evolution and epidemic spread of SARS-CoV-2 in Brazil

Author

Marcílio Jorge Fumagalli, Camila A. M. Silva, Átila Duque Rossi, Mauro M. Teixeira, Chieh-Hsi Wu, William Marciel de Souza, Pedro S. Peixoto, Carlos A. Prete, Thomas A. Mellan, Angelica Zaninelli Schreiber, Renan P. Souza, Samir Bhatt, Rennan G. Moreira, Jaqueline Goes de Jesus, Josy Hubner, Mandev S. Gill, Philippe Lemey, Mauricio W. Perroud, Celso Francisco Hernandes Granato, Andrei C. Sposito, Patricia Asfora Falabella Leme, Nicholas J. Loman, Giulia M. Ferreira, Julien Thézé, José Luiz Proença-Módena, Mariane Talon de Menezes, Fabiana Granja, Louis du Plessis, Márcia Teixeira Garcia, Darlan da Silva Candido, Sarah C. Hill, Ronaldo da Silva Francisco, Luiz Carlos de Almeida, Rafael Henrique Moraes Pereira, Nelson Gaburo, Lewis F Buss, Mariana S. Ramundo, Ana Tereza Ribeiro de Vasconcelos, Magnun N. N. Santos, Ester Cerdeira Sabino, Samuel M. Nicholls, Andreza Aruska de Souza Santos, Luiz Max Carvalho, Oliver J. Brady, Carolina S. Lazari, Luciana C. Resende-Moreira, Ingra Morales Claro, José Eduardo Levi, Oliver G. Pybus, Flavia C. S. Sales, Camila Zolini de Sá, Cristiano Xavier Lima, Amilcar Tanuri, Neil M. Ferguson, Helder I. Nakaya, Swapnil Mishra, Henrique Hoeltgebaum, Maria Luiza Moretti, Simon Dellicour, Thais M. Coletti, Alessandro C. S. Ferreira, Jordan Ashworth, Cecila Salete Alencar, Silvia Figueiredo Costa, Carlos Kaue Vieira Braga, Carolina M. Voloch, Renato Santana Aguiar, Ana Paula de C Guimarães, Andrew Rambaut, Alexandra L. Gerber, Nuno R. Faria, Filipe R. R. Moreira, Maurício Lacerda Nogueira, Camila L. Simeoni, Terezinha M. P. P. Castineiras, Erika R. Manuli, Mariene R. Amorim, Julia Forato, Université libre de Bruxelles (ULB), University of Oxford [Oxford], Laboratorio Nacional de Computação Cientifica [Rio de Janeiro] (LNCC / MCT), Unité Mixte de Recherche d'Épidémiologie des maladies Animales et zoonotiques (UMR EPIA), VetAgro Sup - Institut national d'enseignement supérieur et de recherche en alimentation, santé animale, sciences agronomiques et de l'environnement (VAS)-Institut National de Recherche pour l’Agriculture, l’Alimentation et l’Environnement (INRAE), Catholic University of Leuven - Katholieke Universiteit Leuven (KU Leuven), Yerkes National Primate Research Center [Lawrenceville, GA], Emory University [Atlanta, GA], Comissão de Coordenação e Desenvolvimento Regional do Alentejo, Universidade de São Paulo (USP), University of Campinas [Campinas] (UNICAMP), IBM Research - Brazil, IBM Brazil, Instituto de Ciencias Biologicas [Minas Gerais], Universidade Federal de Minas Gerais [Belo Horizonte] (UFMG), University of London, Rega Institute for Medical Research [Leuven, België], University of Southampton, University of Edinburgh, University of Birmingham [Birmingham], Wellcome Trust, and Medical Research Council-São Paulo Research Foundation (FAPESP)

Subjects

0301 basic medicine, Urban Population, Virus transmission, Epidemiology, [SDV]Life Sciences [q-bio], Basic Reproduction Number, CORONAVIRUS, law.invention, 0302 clinical medicine, COVID-19 Testing, law, Socioeconomics, Clade, Phylogeny, [SDV.MHEP.ME]Life Sciences [q-bio]/Human health and pathology/Emerging diseases, Travel, Multidisciplinary, biology, 3. Good health, Multidisciplinary Sciences, Europe, Phylogeography, Transmission (mechanics), Geography, Science & Technology - Other Topics, ACCURATE, Coronavirus Infections, Brazil, General Science & Technology, Evolution, Genomic data, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), 030231 tropical medicine, Pneumonia, Viral, Genome, Viral, Evolution, Molecular, 03 medical and health sciences, Betacoronavirus, Spatio-Temporal Analysis, Brazil-UK Centre for Arbovirus Discovery, Diagnosis, Genomics and Epidemiology (CADDE) Genomic Network, Report, Epidemic spread, Humans, Cities, Pandemics, Air travel, Science & Technology, Models, Statistical, Models, Genetic, Clinical Laboratory Techniques, SARS-CoV-2, COVID-19, Bayes Theorem, biology.organism_classification, 030104 developmental biology, Basic reproduction number, Demography, Reports

Abstract

Brazil currently has one of the fastest growing SARS-CoV-2 epidemics in the world. Due to limited available data, assessments of the impact of non-pharmaceutical interventions (NPIs) on virus transmission and epidemic spread remain challenging. We investigate the impact of NPIs in Brazil using epidemiological, mobility and genomic data. Mobility-driven transmission models for São Paulo and Rio de Janeiro cities show that the reproduction number (Rt) reached below 1 following NPIs but slowly increased to values between 1 to 1.3 (1.0–1.6). Genome sequencing of 427 new genomes and analysis of a geographically representative genomic dataset from 21 of the 27 Brazilian states identified >100 international introductions of SARS-CoV-2 in Brazil. We estimate that three clades introduced from Europe emerged between 22 and 27 February 2020, and were already well-established before the implementation of NPIs and travel bans. During this first phase of the epidemic establishment of SARS-CoV-2 in Brazil, we find that the virus spread mostly locally and within-state borders. Despite sharp decreases in national air travel during this period, we detected a 25% increase in the average distance travelled by air passengers during this time period. This coincided with the spread of SARS-CoV-2 from large urban centers to the rest of the country. In conclusion, our results shed light on the role of large and highly connected populated centres in the rapid ignition and establishment of SARS-CoV-2, and provide evidence that current interventions remain insufficient to keep virus transmission under control in Brazil.One Sentence SummaryJoint analysis of genomic, mobility and epidemiological novel data provide unique insight into the spread and transmission of the rapidly evolving epidemic of SARS-CoV-2 in Brazil.

Published

2020

7. Rapid viral metagenomics using SMART-9N amplification and nanopore sequencing

Author

José Eduardo Levi, Thais M. Coletti, Darlan da Silva Candido, Camila A. M. Silva, Anderson Vicente de Paula, Mariana C. Pinho, Alvina Clara Felix, Esper G. Kallas, Nicholas J. Loman, Ester Cerdeira Sabino, Nuno R. Faria, Ingra M. Claro, Ian Nunes Valença, Flavia C. S. Sales, Joshua Quick, William Marciel de Souza, Erika R. Manuli, José Luiz Proença-Módena, Pamela S Andrade, Mariene R. Amorim, Mariana S. Ramundo, and Jaqueline G. de Jesus

Subjects

Viral metagenomics, biology, technology, industry, and agriculture, Medicine (miscellaneous), RNA virus, Computational biology, Amplicon, biology.organism_classification, Genome, humanities, General Biochemistry, Genetics and Molecular Biology, DNA sequencing, Metagenomics, Multiplex polymerase chain reaction, Nanopore sequencing

Abstract

Emerging and re-emerging viruses are a global health concern. Genome sequencing as an approach for monitoring circulating viruses is currently hampered by complex and expensive methods. Untargeted, metagenomic nanopore sequencing can provide genomic information to identify pathogens, prepare for or even prevent outbreaks. SMART (Switching Mechanism at the 5′ end of RNA Template) is a popular method for RNA-Seq but most current methods rely on oligo-dT priming to target polyadenylated mRNA molecules. We have developed two random primed SMART-Seq approaches, ‘SMART-9N’, and a version compatible with barcoded PCR primers available from Oxford Nanopore Technologies, ‘Rapid SMART-9N’, for the detection, characterization, and whole-genome sequencing of RNA viruses. The methods were developed using viral isolates, clinical samples, and compared to a gold-standard amplicon-based method. From a Zika virus isolate the SMART-9N approach recovered 10kb of the 10.8kb RNA genome in a single nanopore read. We also obtained full genome coverage at a high depth coverage using the Rapid SMART-9N, which takes only 10 minutes and costs up to 45% less than other methods. We found the limits of detection of these methods to be 6e00 focus forming units (FFU)/mL with 99.02% and 87.58% genome coverage for SMART-9N and Rapid SMART-9N respectively. Yellow fever virus plasma samples and SARS-CoV-2 nasopharyngeal samples previously confirmed by RT-qPCR with a broad range of Ct-values were selected for validation. Both methods produced greater genome coverage when compared to the multiplex PCR approach and we obtained the longest single read of this study (18.5 kb) with a SARS-CoV-2 clinical sample, 60% of the virus genome using the Rapid SMART-9N method. This work demonstrates that SMART-9N and Rapid SMART-9N are sensitive, low input, and long-read compatible alternatives for RNA virus detection and genome sequencing and Rapid SMART-9N improves the cost, time, and complexity of laboratory work.

Published

2021

8. Paclitaxel Reduces Tumor Growth by Reprogramming Tumor-Associated Macrophages to an M1 Profile in a TLR4-Dependent Manner

Author

Roberto C. P. Lima-Júnior, Thiago M. Cunha, Caio Abner Leite, Francisco Fábio Bezerra de Oliveira, José C. Alves-Filho, Fernando Q. Cunha, Camila A. M. Silva, Janaina A. Pereira, Carlos W. S. Wanderley, Jose Mauricio Mota, João Paulo Mesquita Luiz, Paula Ramos Viacava, David F. Colón, Cássia Regina Silva, Rangel L. Silva, and Cesar A. Speck-Hernandez

Subjects

0301 basic medicine, MACRÓFAGOS, Cancer Research, Skin Neoplasms, Paclitaxel, medicine.medical_treatment, Antineoplastic Agents, Breast Neoplasms, 03 medical and health sciences, chemistry.chemical_compound, Mice, 0302 clinical medicine, Immune system, Cell Line, Tumor, Neoplasms, medicine, Macrophage, Animals, Humans, Melanoma, Oligonucleotide Array Sequence Analysis, Ovarian Neoplasms, Mice, Inbred BALB C, Gene Expression Profiling, Macrophages, NF-kappa B, Cancer, Immunotherapy, Macrophage Activation, medicine.disease, Gene Expression Regulation, Neoplastic, Mice, Inbred C57BL, Toll-Like Receptor 4, 030104 developmental biology, Oncology, chemistry, 030220 oncology & carcinogenesis, Immune System, TLR4, Cancer research, Female, Ovarian cancer, Signal Transduction

Abstract

Paclitaxel is an antineoplastic agent widely used to treat several solid tumor types. The primary mechanism of action of paclitaxel is based on microtubule stabilization inducing cell-cycle arrest. Here, we use several tumor models to show that paclitaxel not only induces tumor cell-cycle arrest, but also promotes antitumor immunity. In vitro, paclitaxel reprogrammed M2-polarized macrophages to the M1-like phenotype in a TLR4-dependent manner, similarly to LPS. Paclitaxel also modulated the tumor-associated macrophage (TAM) profile in mouse models of breast and melanoma tumors; gene expression analysis showed that paclitaxel altered the M2-like signature of TAMs toward an M1-like profile. In mice selectively lacking TLR4 on myeloid cells, for example, macrophages (LysM-Cre+/−/TLR4fl/fl), the antitumor effect of paclitaxel was attenuated. Gene expression analysis of tumor samples from patients with ovarian cancer before and after treatment with paclitaxel detected an enrichment of genes linked to the M1 macrophage activation profile (IFNγ-stimulated macrophages). These findings indicate that paclitaxel skews TAMs toward an immunocompetent profile via TLR4, which might contribute to the antitumor effect of paclitaxel and provide a rationale for new combination regimens comprising paclitaxel and immunotherapies as an anticancer treatment. Significance: This study provides new evidence that the antitumor effect of paclitaxel occurs in part via reactivation of the immune response against cancer, guiding tumor-associated macrophages toward the M1-like antitumor phenotype. Graphical Abstract: http://cancerres.aacrjournals.org/content/canres/78/20/5891/F1.large.jpg. Cancer Res; 78(20); 5891–900. ©2018 AACR. See related commentary by Garassino et al., p. 5729

Published

2017