Your search keyword '"Ott, Isabel M."' showing total 116 results

1. DengueSeq: a pan-serotype whole genome amplicon sequencing protocol for dengue virus

Author

Vogels, Chantal B. F., Hill, Verity, Breban, Mallery I., Chaguza, Chrispin, Paul, Lauren M., Sodeinde, Afeez, Taylor-Salmon, Emma, Ott, Isabel M., Petrone, Mary E., Dijk, Dennis, Jonges, Marcel, Welkers, Matthijs R. A., Locksmith, Timothy, Dong, Yibo, Tarigopula, Namratha, Tekin, Omer, Schmedes, Sarah, Bunch, Sylvia, Cano, Natalia, Jaber, Rayah, Panzera, Charles, Stryker, Ian, Vergara, Julieta, Zimler, Rebecca, Kopp, Edgar, Heberlein, Lea, Herzog, Kaylee S., Fauver, Joseph R., Morrison, Andrea M., Michael, Scott F., and Grubaugh, Nathan D.

Published

2024

2. Distinguishing features of long COVID identified through immune profiling

Author

Klein, Jon, Wood, Jamie, Jaycox, Jillian R., Dhodapkar, Rahul M., Lu, Peiwen, Gehlhausen, Jeff R., Tabachnikova, Alexandra, Greene, Kerrie, Tabacof, Laura, Malik, Amyn A., Silva Monteiro, Valter, Silva, Julio, Kamath, Kathy, Zhang, Minlu, Dhal, Abhilash, Ott, Isabel M., Valle, Gabrielee, Peña-Hernández, Mario, Mao, Tianyang, Bhattacharjee, Bornali, Takahashi, Takehiro, Lucas, Carolina, Song, Eric, McCarthy, Dayna, Breyman, Erica, Tosto-Mancuso, Jenna, Dai, Yile, Perotti, Emily, Akduman, Koray, Tzeng, Tiffany J., Xu, Lan, Geraghty, Anna C., Monje, Michelle, Yildirim, Inci, Shon, John, Medzhitov, Ruslan, Lutchmansingh, Denyse, Possick, Jennifer D., Kaminski, Naftali, Omer, Saad B., Krumholz, Harlan M., Guan, Leying, Dela Cruz, Charles S., van Dijk, David, Ring, Aaron M., Putrino, David, and Iwasaki, Akiko

Published

2023

3. Multiplex qPCR Discriminates Variants of Concern to Enhance Global Surveillance of SARS-CoV-2

Author

Vogels, Chantal B. F., primary, Breban, Mallery I., additional, Ott, Isabel M., additional, Alpert, Tara, additional, Petrone, Mary E., additional, Watkins, Anne E., additional, Kalinich, Chaney C., additional, Earnest, Rebecca, additional, Rothman, Jessica E., additional, de Jesus, Jaqueline Goes, additional, Claro, Ingra Morales, additional, Ferreira, Giulia Magalhães, additional, Crispim, Myuki A. E., additional, Singh, Lavanya, additional, Tegally, Houriiyah, additional, Anyaneji, Ugochukwu J., additional, Hodcroft, Emma B., additional, Mason, Christopher E., additional, Khullar, Gaurav, additional, Metti, Jessica, additional, Dudley, Joel T., additional, MacKay, Matthew J., additional, Nash, Megan, additional, Wang, Jianhui, additional, Liu, Chen, additional, Hui, Pei, additional, Murphy, Steven, additional, Neal, Caleb, additional, Laszlo, Eva, additional, Landry, Marie L., additional, Muyombwe, Anthony, additional, Downing, Randy, additional, Razeq, Jafar, additional, de Oliveira, Tulio, additional, Faria, Nuno R., additional, Sabino, Ester C., additional, Neher, Richard A., additional, Fauver, Joseph R., additional, and Grubaugh, Nathan D., additional

Published

2023

4. Method versatility in RNA extraction-free PCR detection of SARS-CoV-2 in saliva samples

Author

Allicock, Orchid M., Yolda-Carr, Devyn, Earnest, Rebecca, Breban, Mallery I., Vega, Noel, Ott, Isabel M., Kalinich, Chaney, Alpert, Tara, Petrone, Mary E, and Wyllie, Anne L.

Published

2023

5. Combining genomic and epidemiological data to compare the transmissibility of SARS-CoV-2 variants Alpha and Iota

Author

Petrone, Mary E., Rothman, Jessica E., Breban, Mallery I., Ott, Isabel M., Russell, Alexis, Lasek-Nesselquist, Erica, Badr, Hamada, Kelly, Kevin, Omerza, Greg, Renzette, Nicholas, Watkins, Anne E., Kalinich, Chaney C., Alpert, Tara, Brito, Anderson F., Earnest, Rebecca, Tikhonova, Irina R., Castaldi, Christopher, Kelly, John P., Shudt, Matthew, Plitnick, Jonathan, Schneider, Erasmus, Murphy, Steven, Neal, Caleb, Laszlo, Eva, Altajar, Ahmad, Pearson, Claire, Muyombwe, Anthony, Downing, Randy, Razeq, Jafar, Niccolai, Linda, Wilson, Madeline S., Anderson, Margaret L., Wang, Jianhui, Liu, Chen, Hui, Pei, Mane, Shrikant, Taylor, Bradford P., Hanage, William P., Landry, Marie L., Peaper, David R., Bilguvar, Kaya, Fauver, Joseph R., Vogels, Chantal B. F., Gardner, Lauren M., Pitzer, Virginia E., St. George, Kirsten, Adams, Mark D., and Grubaugh, Nathan D.

Published

2022

6. Lineage abundance estimation for SARS-CoV-2 in wastewater using transcriptome quantification techniques

Author

Baaijens, Jasmijn A., Zulli, Alessandro, Ott, Isabel M., Nika, Ioanna, van der Lugt, Mart J., Petrone, Mary E., Alpert, Tara, Fauver, Joseph R., Kalinich, Chaney C., Vogels, Chantal B. F., Breban, Mallery I., Duvallet, Claire, McElroy, Kyle A., Ghaeli, Newsha, Imakaev, Maxim, Mckenzie-Bennett, Malaika F., Robison, Keith, Plocik, Alex, Schilling, Rebecca, Pierson, Martha, Littlefield, Rebecca, Spencer, Michelle L., Simen, Birgitte B., Hanage, William P., Grubaugh, Nathan D., Peccia, Jordan, and Baym, Michael

Published

2022

7. SalivaDirect: A simplified and flexible platform to enhance SARS-CoV-2 testing capacity

Author

Anastasio, Kelly, Askenase, Michael H., Batsu, Maria, Bickerton, Sean, Brower, Kristina, Bucklin, Molly L., Cahill, Staci, Cao, Yiyun, Courchaine, Edward, DeIuliis, Giuseppe, Earnest, Rebecca, Geng, Bertie, Goldman-Israelow, Benjamin, Handoko, Ryan, Khoury-Hanold, William, Kim, Daniel, Knaggs, Lynda, Kuang, Maxine, Lapidus, Sarah, Lim, Joseph, Linehan, Melissa, Lu-Culligan, Alice, Martin, Anjelica, Matos, Irene, McDonald, David, Minasyan, Maksym, Nakahata, Maura, Naushad, Nida, Nouws, Jessica, Obaid, Abeer, Odio, Camila, Oh, Ji Eun, Omer, Saad, Park, Annsea, Park, Hong-Jai, Peng, Xiaohua, Petrone, Mary, Prophet, Sarah, Rice, Tyler, Rose, Kadi-Ann, Sewanan, Lorenzo, Sharma, Lokesh, Shaw, Albert C., Shepard, Denise, Smolgovsky, Mikhail, Sonnert, Nicole, Strong, Yvette, Todeasa, Codruta, Valdez, Jordan, Velazquez, Sofia, Vijayakumar, Pavithra, White, Elizabeth B., Yang, Yexin, Vogels, Chantal B.F., Watkins, Anne E., Harden, Christina A., Brackney, Doug E., Shafer, Jared, Wang, Jianhui, Caraballo, César, Kalinich, Chaney C., Ott, Isabel M., Fauver, Joseph R., Kudo, Eriko, Lu, Peiwen, Venkataraman, Arvind, Tokuyama, Maria, Moore, Adam J., Muenker, M. Catherine, Casanovas-Massana, Arnau, Fournier, John, Bermejo, Santos, Campbell, Melissa, Datta, Rupak, Nelson, Allison, Dela Cruz, Charles S., Ko, Albert I., Iwasaki, Akiko, Krumholz, Harlan M., Matheus, J.D., Hui, Pei, Liu, Chen, Farhadian, Shelli F., Sikka, Robby, Wyllie, Anne L., and Grubaugh, Nathan D.

Published

2021

8. Stability of SARS-CoV-2 RNA in Nonsupplemented Saliva

Author

Ott, Isabel M., Strine, Madison S., Watkins, Anne E., Boot, Maikel, Kalinich, Chaney C., Harden, Christina A., Vogels, Chantal B.F., Casanovas-Massana, Arnau, Moore, Adam J., Muenker, M. Catherine, Nakahata, Maura, Tokuyama, Maria, Nelson, Allison, Fournier, John, Bermejo, Santos, Campbell, Melissa, Datta, Rupak, Dela Cruz, Charles S., Farhadian, Shelli F., Ko, Albert I., Iwasaki, Akiko, Grubaugh, Nathan D., Wilen, Craig B., and Wyllie, Anne L.

Subjects

Salivary diagnostics -- Genetic aspects -- Economic aspects -- Methods, Health

Abstract

Despite increased diagnostic testing capacity for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), testing in many countries, including the United States, is still inadequate for slowing the coronavirus disease (COVID-19) [...]

Published

2021

9. Coast-to-Coast Spread of SARS-CoV-2 during the Early Epidemic in the United States

Author

Fauver, Joseph R., Petrone, Mary E., Hodcroft, Emma B., Shioda, Kayoko, Ehrlich, Hanna Y., Watts, Alexander G., Vogels, Chantal B.F., Brito, Anderson F., Alpert, Tara, Muyombwe, Anthony, Razeq, Jafar, Downing, Randy, Cheemarla, Nagarjuna R., Wyllie, Anne L., Kalinich, Chaney C., Ott, Isabel M., Quick, Joshua, Loman, Nicholas J., Neugebauer, Karla M., Greninger, Alexander L., Jerome, Keith R., Roychoudhury, Pavitra, Xie, Hong, Shrestha, Lasata, Huang, Meei-Li, Pitzer, Virginia E., Iwasaki, Akiko, Omer, Saad B., Khan, Kamran, Bogoch, Isaac I., Martinello, Richard A., Foxman, Ellen F., Landry, Marie L., Neher, Richard A., Ko, Albert I., and Grubaugh, Nathan D.

Published

2020

10. Analytical sensitivity and efficiency comparisons of SARS-CoV-2 RT–qPCR primer–probe sets

Author

Vogels, Chantal B. F., Brito, Anderson F., Wyllie, Anne L., Fauver, Joseph R., Ott, Isabel M., Kalinich, Chaney C., Petrone, Mary E., Casanovas-Massana, Arnau, Catherine Muenker, M., Moore, Adam J., Klein, Jonathan, Lu, Peiwen, Lu-Culligan, Alice, Jiang, Xiaodong, Kim, Daniel J., Kudo, Eriko, Mao, Tianyang, Moriyama, Miyu, Oh, Ji Eun, Park, Annsea, Silva, Julio, Song, Eric, Takahashi, Takehiro, Taura, Manabu, Tokuyama, Maria, Venkataraman, Arvind, Weizman, Orr-El, Wong, Patrick, Yang, Yexin, Cheemarla, Nagarjuna R., White, Elizabeth B., Lapidus, Sarah, Earnest, Rebecca, Geng, Bertie, Vijayakumar, Pavithra, Odio, Camila, Fournier, John, Bermejo, Santos, Farhadian, Shelli, Dela Cruz, Charles S., Iwasaki, Akiko, Ko, Albert I., Landry, Marie L., Foxman, Ellen F., and Grubaugh, Nathan D.

Published

2020

11. Longitudinal analyses reveal immunological misfiring in severe COVID-19

Author

Lucas, Carolina, Wong, Patrick, Klein, Jon, Castro, Tiago B. R., Silva, Julio, Sundaram, Maria, Ellingson, Mallory K., Mao, Tianyang, Oh, Ji Eun, Israelow, Benjamin, Takahashi, Takehiro, Tokuyama, Maria, Lu, Peiwen, Venkataraman, Arvind, Park, Annsea, Mohanty, Subhasis, Wang, Haowei, Wyllie, Anne L., Vogels, Chantal B. F., Earnest, Rebecca, Lapidus, Sarah, Ott, Isabel M., Moore, Adam J., Muenker, M. Catherine, Fournier, John B., Campbell, Melissa, Odio, Camila D., Casanovas-Massana, Arnau, Herbst, Roy, Shaw, Albert C., Medzhitov, Ruslan, Schulz, Wade L., Grubaugh, Nathan D., Dela Cruz, Charles, Farhadian, Shelli, Ko, Albert I., Omer, Saad B., and Iwasaki, Akiko

Published

2020

12. DengueSeq: A pan-serotype whole genome amplicon sequencing protocol for dengue virus

Author

Vogels, Chantal B.F., primary, Hill, Verity, additional, Breban, Mallery I., additional, Chaguza, Chrispin, additional, Paul, Lauren M., additional, Sodeinde, Afeez, additional, Taylor-Salmon, Emma, additional, Ott, Isabel M., additional, Petrone, Mary E., additional, Dijk, Dennis, additional, Jonges, Marcel, additional, Welkers, Matthijs R.A., additional, Locksmith, Timothy, additional, Dong, Yibo, additional, Tarigopula, Namratha, additional, Tekin, Omer, additional, Schmedes, Sarah, additional, Bunch, Sylvia, additional, Cano, Natalia, additional, Jaber, Rayah, additional, Panzera, Charles, additional, Stryker, Ian, additional, Vergara, Julieta, additional, Zimler, Rebecca, additional, Kopp, Edgar, additional, Heberlein, Lea, additional, Morrison, Andrea M., additional, Michael, Scott F., additional, and Grubaugh, Nathan D., additional

Published

2023

13. Reply to: A finding of sex similarities rather than differences in COVID-19 outcomes

Author

Takahashi, Takehiro, Ellingson, Mallory K., Wong, Patrick, Israelow, Benjamin, Lucas, Carolina, Klein, Jon, Silva, Julio, Mao, Tianyang, Oh, Ji Eun, Tokuyama, Maria, Lu, Peiwen, Venkataraman, Arvind, Park, Annsea, Liu, Feimei, Meir, Amit, Sun, Jonathan, Wang, Eric Y., Casanovas-Massana, Arnau, Wyllie, Anne L., Vogels, Chantal B. F., Earnest, Rebecca, Lapidus, Sarah, Ott, Isabel M., Moore, Adam J., Shaw, Albert, Fournier, John B., Odio, Camila D., Farhadian, Shelli, Dela Cruz, Charles, Grubaugh, Nathan D., Schulz, Wade L., Ring, Aaron M., Ko, Albert I., Omer, Saad B., and Iwasaki, Akiko

Published

2021

14. Detection of pneumococcus during hospitalization for SARS-CoV-2

Author

Watkins, Anne E., primary, Glick, Laura R., additional, Ott, Isabel M., additional, Craft, Samuel B., additional, Yolda-Carr, Devyn, additional, Harden, Christina A., additional, Nakahata, Maura, additional, Farhadian, Shelli F., additional, Grant, Lindsay R., additional, Alexander-Parrish, Ronika, additional, Arguedas, Adriano, additional, Gessner, Bradford D., additional, Weinberger, Daniel M., additional, and Wyllie, Anne L., additional

Published

2022

15. Lineage abundance estimation for SARS-CoV-2 in wastewater using transcriptome quantification techniques

Author

Baaijens, J.A. (author), Zulli, Alessandro (author), Ott, Isabel M. (author), Nika, Ioanna (author), van der Lugt, Mart J. (author), Petrone, Mary E. (author), Alpert, Tara (author), Fauver, Joseph R. (author), Kalinich, Chaney C. (author), Baaijens, J.A. (author), Zulli, Alessandro (author), Ott, Isabel M. (author), Nika, Ioanna (author), van der Lugt, Mart J. (author), Petrone, Mary E. (author), Alpert, Tara (author), Fauver, Joseph R. (author), and Kalinich, Chaney C. (author)

Abstract

Effectively monitoring the spread of SARS-CoV-2 mutants is essential to efforts to counter the ongoing pandemic. Predicting lineage abundance from wastewater, however, is technically challenging. We show that by sequencing SARS-CoV-2 RNA in wastewater and applying algorithms initially used for transcriptome quantification, we can estimate lineage abundance in wastewater samples. We find high variability in signal among individual samples, but the overall trends match those observed from sequencing clinical samples. Thus, while clinical sequencing remains a more sensitive technique for population surveillance, wastewater sequencing can be used to monitor trends in mutant prevalence in situations where clinical sequencing is unavailable., Pattern Recognition and Bioinformatics

Published

2022

16. Rapid emergence of SARS-CoV-2 Omicron variant is associated with an infection advantage over Delta in vaccinated persons

Author

Chaguza, Chrispin, Coppi, Andreas, Earnest, Rebecca, Ferguson, David, Kerantzas, Nicholas, Warner, Frederick, Young, H. Patrick, Breban, Mallery I., Billig, Kendall, Koch, Robert Tobias, Pham, Kien, Kalinich, Chaney C., Ott, Isabel M., Fauver, Joseph R., Hahn, Anne M., Tikhonova, Irina R., Castaldi, Christopher, De Kumar, Bony, Pettker, Christian M., Warren, Joshua L., Weinberger, Daniel M., Landry, Marie L., Peaper, David R., Schulz, Wade, Vogels, Chantal B.F., and Grubaugh, Nathan D.

Published

2022

17. Comparative transmissibility of SARS-CoV-2 variants Delta and Alpha in New England, USA

Author

Earnest, Rebecca, primary, Uddin, Rockib, additional, Matluk, Nicholas, additional, Renzette, Nicholas, additional, Turbett, Sarah E., additional, Siddle, Katherine J., additional, Loreth, Christine, additional, Adams, Gordon, additional, Tomkins-Tinch, Christopher H., additional, Petrone, Mary E., additional, Rothman, Jessica E., additional, Breban, Mallery I., additional, Koch, Robert Tobias, additional, Billig, Kendall, additional, Fauver, Joseph R., additional, Vogels, Chantal B.F., additional, Bilguvar, Kaya, additional, De Kumar, Bony, additional, Landry, Marie L., additional, Peaper, David R., additional, Kelly, Kevin, additional, Omerza, Greg, additional, Grieser, Heather, additional, Meak, Sim, additional, Martha, John, additional, Dewey, Hannah B., additional, Kales, Susan, additional, Berenzy, Daniel, additional, Carpenter-Azevedo, Kristin, additional, King, Ewa, additional, Huard, Richard C., additional, Novitsky, Vlad, additional, Howison, Mark, additional, Darpolor, Josephine, additional, Manne, Akarsh, additional, Kantor, Rami, additional, Smole, Sandra C., additional, Brown, Catherine M., additional, Fink, Timelia, additional, Lang, Andrew S., additional, Gallagher, Glen R., additional, Pitzer, Virginia E., additional, Sabeti, Pardis C., additional, Gabriel, Stacey, additional, MacInnis, Bronwyn L., additional, Tewhey, Ryan, additional, Adams, Mark D., additional, Park, Daniel J., additional, Lemieux, Jacob E., additional, Grubaugh, Nathan D., additional, Altajar, Ahmad, additional, DeJesus, Alexandra, additional, Brito, Anderson, additional, Watkins, Anne E., additional, Muyombwe, Anthony, additional, Blumenstiel, Brendan S., additional, Neal, Caleb, additional, Kalinich, Chaney C., additional, Liu, Chen, additional, Castaldi, Christopher, additional, Pearson, Claire, additional, Bernard, Clare, additional, Nolet, Corey M., additional, Ferguson, David, additional, Buzby, Erika, additional, Laszlo, Eva, additional, Reagan, Faye L., additional, Vicente, Gina, additional, Rooke, Heather M., additional, Munger, Heidi, additional, Johnson, Hillary, additional, Tikhonova, Irina R., additional, Ott, Isabel M., additional, Razeq, Jafar, additional, Meldrim, James C., additional, Brown, Jessica, additional, Wang, Jianhui, additional, Vostok, Johanna, additional, Beauchamp, John P., additional, Grimsby, Jonna L., additional, Hall, Joshua, additional, Messer, Katelyn S., additional, Larkin, Katie L., additional, Vernest, Kyle, additional, Madoff, Lawrence C., additional, Green, Lisa M., additional, Webber, Lori, additional, Gagne, Luc, additional, Ulcena, Maesha A., additional, Ray, Marianne C., additional, Fisher, Marissa E., additional, Barter, Mary, additional, Lee, Matthew D., additional, DeFelice, Matthew T., additional, Cipicchio, Michelle C., additional, Smith, Natasha L., additional, Lennon, Niall J., additional, Fitzgerald, Nicholas A., additional, Kerantzas, Nicholas, additional, Hui, Pei, additional, Harrington, Rachel, additional, Downing, Randy, additional, Haye, Rashida, additional, Lynch, Ryan, additional, Anderson, Scott E., additional, Hennigan, Scott, additional, English, Sean, additional, Cofsky, Seana, additional, Clancy, Selina, additional, Mane, Shrikant, additional, Ash, Stephanie, additional, Baez, Stephanie, additional, Fleming, Steve, additional, Murphy, Steven, additional, Chaluvadi, Sushma, additional, Alpert, Tara, additional, Rivard, Trevor, additional, Schulz, Wade, additional, and Mandese, Zoe M., additional

Published

2022

18. Sex differences in immune responses that underlie COVID-19 disease outcomes

Author

Takahashi, Takehiro, Ellingson, Mallory K., Wong, Patrick, Israelow, Benjamin, Lucas, Carolina, Klein, Jon, Silva, Julio, Mao, Tianyang, Oh, Ji Eun, Tokuyama, Maria, Lu, Peiwen, Venkataraman, Arvind, Park, Annsea, Liu, Feimei, Meir, Amit, Sun, Jonathan, Wang, Eric Y., Casanovas-Massana, Arnau, Wyllie, Anne L., Vogels, Chantal B. F., Earnest, Rebecca, Lapidus, Sarah, Ott, Isabel M., Moore, Adam J., Anastasio, Kelly, Askenase, Michael H., Batsu, Maria, Beatty, Hannah, Bermejo, Santos, Bickerton, Sean, Brower, Kristina, Bucklin, Molly L., Cahill, Staci, Campbell, Melissa, Cao, Yiyun, Courchaine, Edward, Datta, Rupak, DeIuliis, Giuseppe, Geng, Bertie, Glick, Laura, Handoko, Ryan, Kalinich, Chaney, Khoury-Hanold, William, Kim, Daniel, Knaggs, Lynda, Kuang, Maxine, Kudo, Eriko, Lim, Joseph, Linehan, Melissa, Lu-Culligan, Alice, Malik, Amyn A., Martin, Anjelica, Matos, Irene, McDonald, David, Minasyan, Maksym, Mohanty, Subhasis, Muenker, M. Catherine, Naushad, Nida, Nelson, Allison, Nouws, Jessica, Nunez-Smith, Marcella, Obaid, Abeer, Ott, Isabel, Park, Hong-Jai, Peng, Xiaohua, Petrone, Mary, Prophet, Sarah, Rahming, Harold, Rice, Tyler, Rose, Kadi-Ann, Sewanan, Lorenzo, Sharma, Lokesh, Shepard, Denise, Silva, Erin, Simonov, Michael, Smolgovsky, Mikhail, Song, Eric, Sonnert, Nicole, Strong, Yvette, Todeasa, Codruta, Valdez, Jordan, Velazquez, Sofia, Vijayakumar, Pavithra, Wang, Haowei, Watkins, Annie, White, Elizabeth B., Yang, Yexin, Shaw, Albert, Fournier, John B., Odio, Camila D., Farhadian, Shelli, Dela Cruz, Charles, Grubaugh, Nathan D., Schulz, Wade L., Ring, Aaron M., Ko, Albert I., Omer, Saad B., and Iwasaki, Akiko

Subjects

0301 basic medicine, Multidisciplinary, Innate immune system, biology, business.industry, T cell, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Immune system, Immunity, 030220 oncology & carcinogenesis, Immunology, biology.protein, Medicine, Antibody, business, Viral load, Sex characteristics, Cohort study

Abstract

There is increasing evidence that coronavirus disease 2019 (COVID-19) produces more severe symptoms and higher mortality among men than among women1-5. However, whether immune responses against severe acute respiratory syndrome coronavirus (SARS-CoV-2) differ between sexes, and whether such differences correlate with the sex difference in the disease course of COVID-19, is currently unknown. Here we examined sex differences in viral loads, SARS-CoV-2-specific antibody titres, plasma cytokines and blood-cell phenotyping in patients with moderate COVID-19 who had not received immunomodulatory medications. Male patients had higher plasma levels of innate immune cytokines such as IL-8 and IL-18 along with more robust induction of non-classical monocytes. By contrast, female patients had more robust T cell activation than male patients during SARS-CoV-2 infection. Notably, we found that a poor T cell response negatively correlated with patients' age and was associated with worse disease outcome in male patients, but not in female patients. By contrast, higher levels of innate immune cytokines were associated with worse disease progression in female patients, but not in male patients. These findings provide a possible explanation for the observed sex biases in COVID-19, and provide an important basis for the development of a sex-based approach to the treatment and care of male and female patients with COVID-19.

Published

2020

19. Additional file 1 of Lineage abundance estimation for SARS-CoV-2 in wastewater using transcriptome quantification techniques

Author

Baaijens, Jasmijn A., Zulli, Alessandro, Ott, Isabel M., Nika, Ioanna, van der Lugt, Mart J., Petrone, Mary E., Alpert, Tara, Fauver, Joseph R., Kalinich, Chaney C., Vogels, Chantal B. F., Breban, Mallery I., Duvallet, Claire, McElroy, Kyle A., Ghaeli, Newsha, Imakaev, Maxim, Mckenzie-Bennett, Malaika F., Robison, Keith, Plocik, Alex, Schilling, Rebecca, Pierson, Martha, Littlefield, Rebecca, Spencer, Michelle L., Simen, Birgitte B., Hanage, William P., Grubaugh, Nathan D., Peccia, Jordan, and Baym, Michael

Abstract

Additional file 1. Includes all supplementary information, supplementary figures and supplementary tables.

Published

2022

20. Additional file 2 of Lineage abundance estimation for SARS-CoV-2 in wastewater using transcriptome quantification techniques

Author

Baaijens, Jasmijn A., Zulli, Alessandro, Ott, Isabel M., Nika, Ioanna, van der Lugt, Mart J., Petrone, Mary E., Alpert, Tara, Fauver, Joseph R., Kalinich, Chaney C., Vogels, Chantal B. F., Breban, Mallery I., Duvallet, Claire, McElroy, Kyle A., Ghaeli, Newsha, Imakaev, Maxim, Mckenzie-Bennett, Malaika F., Robison, Keith, Plocik, Alex, Schilling, Rebecca, Pierson, Martha, Littlefield, Rebecca, Spencer, Michelle L., Simen, Birgitte B., Hanage, William P., Grubaugh, Nathan D., Peccia, Jordan, and Baym, Michael

Abstract

Additional file 2. Review history.

Published

2022

21. Detection of pneumococcus during hospitalization for SARS-CoV-2

Author

Stahlfeld, Anne, primary, Glick, Laura R, additional, Ott, Isabel M, additional, Craft, Samuel B, additional, Yolda-Carr, Devyn, additional, Harden, Christina A, additional, Nakahata, Maura, additional, Farhadian, Shelli F, additional, Grant, Lindsay R, additional, Alexander-Parrish, Ronika, additional, Arguedas, Adriano, additional, Gessner, Bradford D, additional, Weinberger, Daniel M, additional, and Wyllie, Anne L, additional

Published

2022

22. Method versatility in RNA extraction-free PCR detection of SARS-CoV-2 in saliva samples

Author

Allicock, Orchid M, primary, Yolda-Carr, Devyn, additional, Earnest, Rebecca, additional, Breban, Mallery, additional, Vega, Noel, additional, Ott, Isabel M, additional, Kalinich, Chaney, additional, Alpert, Tara, additional, Petrone, Mary, additional, and Wyllie, Anne L, additional

Published

2021

23. 301. Detection of Pneumococcal Pneumonia During SARS-CoV-2 Infection

Author

Watkins, Anne, primary, Yolda-Carr, Devyn, additional, Ott, Isabel M, additional, Nakahata, Maura, additional, Moore, Adam, additional, Muenker, M Catherine, additional, Tokuyama, Maria, additional, Vogels, Chantal B, additional, Campbell, Melissa, additional, Datta, Rupak, additional, Cruz, Charles Dela, additional, Farhadian, Shelli F, additional, Iwasaki, Akiko, additional, Ko, Albert I, additional, Grubaugh, Nathan D, additional, Alexander-Parrish, Ronika, additional, Arguedas, Adriano, additional, Gessner, Bradford D, additional, Weinberger, Daniel, additional, and Wyllie, Anne, additional

Published

2021

24. 362. Saliva as a Reliable Sample Type for Mass SARS-CoV-2 Testing Strategies

Author

Wyllie, Anne, primary, Vogels, Chantal B, additional, Allicock, Orchid M, additional, Watkins, Anne, additional, Petrone, Mary, additional, Yolda-Carr, Devyn, additional, Harden, Christina, additional, Brackney, Doug, additional, Kalinich, Chaney C, additional, Breban, Mallery I, additional, Ott, Isabel M, additional, Sikka, Robby, additional, Kadiri, Lolahon, additional, and Grubaugh, Nathan D, additional

Published

2021

25. Multiplex qPCR discriminates variants of concern to enhance global surveillance of SARS-CoV-2

Author

Vogels, Chantal BF, Breban, Mallery I, Ott, Isabel M, Alpert, Tara, Petrone, Mary E, Watkins, Anne E, Kalinich, Chaney C, Earnest, Rebecca, Rothman, Jessica E, Goes de Jesus, Jaqueline, Morales Claro, Ingra, Magalhães Ferreira, Giulia, Crispim, Myuki AE, Brazil-UK CADDE Genomic Network, Singh, Lavanya, Tegally, Houriiyah, Anyaneji, Ugochukwu J, Network for Genomic Surveillance in South Africa, Hodcroft, Emma B, Mason, Christopher E, Khullar, Gaurav, Metti, Jessica, Dudley, Joel T, MacKay, Matthew J, Nash, Megan, Wang, Jianhui, Liu, Chen, Hui, Pei, Murphy, Steven, Neal, Caleb, Laszlo, Eva, Landry, Marie L, Muyombwe, Anthony, Downing, Randy, Razeq, Jafar, de Oliveira, Tulio, Faria, Nuno R, Sabino, Ester C, Neher, Richard A, Fauver, Joseph R, and Grubaugh, Nathan D

Abstract

With the emergence of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) variants that may increase transmissibility and/or cause escape from immune responses, there is an urgent need for the targeted surveillance of circulating lineages. It was found that the B.1.1.7 (also 501Y.V1) variant, first detected in the United Kingdom, could be serendipitously detected by the Thermo Fisher TaqPath COVID-19 PCR assay because a key deletion in these viruses, spike Δ69-70, would cause a "spike gene target failure" (SGTF) result. However, a SGTF result is not definitive for B.1.1.7, and this assay cannot detect other variants of concern (VOC) that lack spike Δ69-70, such as B.1.351 (also 501Y.V2), detected in South Africa, and P.1 (also 501Y.V3), recently detected in Brazil. We identified a deletion in the ORF1a gene (ORF1a Δ3675-3677) in all 3 variants, which has not yet been widely detected in other SARS-CoV-2 lineages. Using ORF1a Δ3675-3677 as the primary target and spike Δ69-70 to differentiate, we designed and validated an open-source PCR assay to detect SARS-CoV-2 VOC. Our assay can be rapidly deployed in laboratories around the world to enhance surveillance for the local emergence and spread of B.1.1.7, B.1.351, and P.1.

Published

2021

26. Viral dynamics of acute SARS-CoV-2 infection and applications to diagnostic and public health strategies

Author

Kissler, Stephen M., primary, Fauver, Joseph R., additional, Mack, Christina, additional, Olesen, Scott W., additional, Tai, Caroline, additional, Shiue, Kristin Y., additional, Kalinich, Chaney C., additional, Jednak, Sarah, additional, Ott, Isabel M., additional, Vogels, Chantal B. F., additional, Wohlgemuth, Jay, additional, Weisberger, James, additional, DiFiori, John, additional, Anderson, Deverick J., additional, Mancell, Jimmie, additional, Ho, David D., additional, Grubaugh, Nathan D., additional, and Grad, Yonatan H., additional

Published

2021

27. Combining genomic and epidemiological data to compare the transmissibility of SARS-CoV-2 lineages

Author

Petrone, Mary E., primary, Rothman, Jessica E., additional, Breban, Mallery I., additional, Ott, Isabel M., additional, Russell, Alexis, additional, Lasek-Nesselquist, Erica, additional, Kelly, Kevin, additional, Omerza, Greg, additional, Renzette, Nicholas, additional, Watkins, Anne E., additional, Kalinich, Chaney C., additional, Alpert, Tara, additional, Brito, Anderson F., additional, Earnest, Rebecca, additional, Tikhonova, Irina R., additional, Castaldi, Christopher, additional, Kelly, John P., additional, Shudt, Matthew, additional, Plitnick, Jonathan, additional, Schneider, Erasmus, additional, Murphy, Steven, additional, Neal, Caleb, additional, Laszlo, Eva, additional, Altajar, Ahmad, additional, Pearson, Claire, additional, Muyombwe, Anthony, additional, Downing, Randy, additional, Razeq, Jafar, additional, Niccolai, Linda, additional, Wilson, Madeline S., additional, Anderson, Margaret L., additional, Wang, Jianhui, additional, Liu, Chen, additional, Hui, Pei, additional, Mane, Shrikant, additional, Taylor, Bradford P., additional, Hanage, William P., additional, Landry, Marie L., additional, Peaper, David R., additional, Bilguvar, Kaya, additional, Fauver, Joseph R., additional, Vogels, Chantal B.F., additional, Gardner, Lauren M., additional, Pitzer, Virginia E., additional, George, Kirsten St., additional, Adams, Mark D., additional, and Grubaugh, Nathan D., additional

Published

2021

28. Diverse Functional Autoantibodies that Underlie Immune Perturbations in COVID-19

Author

Mao, Tianyang, primary, Wang, Eric Y., additional, Klein, Jon, additional, Dai, Yile, additional, Huck, John D., additional, Liu, Feimei, additional, Zheng, Neil S., additional, Zhou, Ting, additional, Goldman-Israelow, Benjamin, additional, Wong, Patrick, additional, Lucas, Carolina, additional, Silva, Julio, additional, Oh, Ji Eun, additional, Song, Eric, additional, Perotti, Emily S., additional, Fischer, Suzanne, additional, Campbell, Melissa, additional, Fournier, John B., additional, Wyllie, Anne L., additional, Vogels, Chantal B. F., additional, Ott, Isabel M., additional, Kalinich, Chaney C., additional, Petrone, Mary E., additional, Watkins, Anne E., additional, Cruz, Charles Dela, additional, Farhadian, Shelli F., additional, Schulz, Wade L., additional, Grubaugh, Nathan D., additional, Ko, Albert I., additional, Iwasaki, Akiko, additional, and Ring, Aaron M., additional

Published

2021

29. Abstract S03-03: Cancer patients display diminished viral RNA clearance and altered T cell responses during SARS-CoV-2 infection

Author

Chiorazzi, Michael, primary, Silva, Erin, additional, Brower, Kristina, additional, Wong, Patrick, additional, Lucas, Carolina, additional, Klein, Jon, additional, Liu, Feimei, additional, Nakahata, Maura, additional, Zhao, Jun, additional, Rahman, Nur-Taz, additional, Odio, Camila, additional, Bermejo, Santos, additional, Farhadian, Shelli F., additional, Dela Cruz, Charles, additional, Casanovas-Massana, Arnau, additional, Fournier, John, additional, Muenker, Catherine, additional, Wyllie, Anne L., additional, Vogels, Chantal B.F., additional, Kalinich, Chaney C., additional, Petrone, Mary E., additional, Ott, Isabel M., additional, Watkins, Anne E., additional, Moore, Adam J., additional, Alpert, Tara, additional, Kluger, Yuval, additional, Ring, Aaron, additional, Grubaugh, Nathan D., additional, Iwasaki, Akiko, additional, Ko, Albert I., additional, and Herbst, Roy S., additional

Published

2021

30. SalivaDirect: A simplified and flexible platform to enhance SARS-CoV-2 testing capacity

Author

Vogels, Chantal B.F., primary, Watkins, Anne E., additional, Harden, Christina A., additional, Brackney, Doug E., additional, Shafer, Jared, additional, Wang, Jianhui, additional, Caraballo, César, additional, Kalinich, Chaney C., additional, Ott, Isabel M., additional, Fauver, Joseph R., additional, Kudo, Eriko, additional, Lu, Peiwen, additional, Venkataraman, Arvind, additional, Tokuyama, Maria, additional, Moore, Adam J., additional, Muenker, M. Catherine, additional, Casanovas-Massana, Arnau, additional, Fournier, John, additional, Bermejo, Santos, additional, Campbell, Melissa, additional, Datta, Rupak, additional, Nelson, Allison, additional, Dela Cruz, Charles S., additional, Ko, Albert I., additional, Iwasaki, Akiko, additional, Krumholz, Harlan M., additional, Matheus, J.D., additional, Hui, Pei, additional, Liu, Chen, additional, Farhadian, Shelli F., additional, Sikka, Robby, additional, Wyllie, Anne L., additional, Grubaugh, Nathan D., additional, Anastasio, Kelly, additional, Askenase, Michael H., additional, Batsu, Maria, additional, Bickerton, Sean, additional, Brower, Kristina, additional, Bucklin, Molly L., additional, Cahill, Staci, additional, Cao, Yiyun, additional, Courchaine, Edward, additional, DeIuliis, Giuseppe, additional, Earnest, Rebecca, additional, Geng, Bertie, additional, Goldman-Israelow, Benjamin, additional, Handoko, Ryan, additional, Khoury-Hanold, William, additional, Kim, Daniel, additional, Knaggs, Lynda, additional, Kuang, Maxine, additional, Lapidus, Sarah, additional, Lim, Joseph, additional, Linehan, Melissa, additional, Lu-Culligan, Alice, additional, Martin, Anjelica, additional, Matos, Irene, additional, McDonald, David, additional, Minasyan, Maksym, additional, Nakahata, Maura, additional, Naushad, Nida, additional, Nouws, Jessica, additional, Obaid, Abeer, additional, Odio, Camila, additional, Oh, Ji Eun, additional, Omer, Saad, additional, Park, Annsea, additional, Park, Hong-Jai, additional, Peng, Xiaohua, additional, Petrone, Mary, additional, Prophet, Sarah, additional, Rice, Tyler, additional, Rose, Kadi-Ann, additional, Sewanan, Lorenzo, additional, Sharma, Lokesh, additional, Shaw, Albert C., additional, Shepard, Denise, additional, Smolgovsky, Mikhail, additional, Sonnert, Nicole, additional, Strong, Yvette, additional, Todeasa, Codruta, additional, Valdez, Jordan, additional, Velazquez, Sofia, additional, Vijayakumar, Pavithra, additional, White, Elizabeth B., additional, and Yang, Yexin, additional

Published

2021

31. An outbreak of SARS‐CoV‐2 on a transplant unit in the early vaccination era.

Author

Roberts, Scott C., Foppiano Palacios, Carlo, Grubaugh, Nathan D., Alpert, Tara, Ott, Isabel M., Breban, Mallery I., Martinello, Richard A., Smith, Cindy, Davis, Matthew W., Mcmanus, Dayna, Tirmizi, Samad, Topal, Jeffrey E., Azar, Marwan M., and Malinis, Maricar

Subjects

COVID-19, SARS-CoV-2, WHOLE genome sequencing, ASYMPTOMATIC patients, INFECTION prevention

Abstract

Background: Solid organ transplant recipients are at increased risk of COVID‐19‐associated morbidity and mortality. Aims: We describe a nosocomial outbreak investigation on an immunocompromised inpatient unit. Methods: Patients positive for SARS‐CoV‐2 were identified. An epidemiologic investigation was assisted with whole genome sequencing of positive samples. Results: Two patients were identified as potential index cases; one presented with diarrhea and was initially not isolated, and the other developed hypoxemia on hospital day 18 before testing positive. Following identification of a SARS‐CoV‐2 cluster, the unit was closed and all patients and staff received surveillance testing revealing eight additional positive patients and staff members. Whole genome sequencing confirmed an outbreak. Enhanced infection prevention practices mitigated further spread. Asymptomatic patients with COVID‐19 were successfully treated with bamlanivimab. Discussion: Preventing SARS‐CoV‐2 outbreaks in transplant units poses unique challenges as patients may have atypical presentations of COVID‐19. Immunocompromised patients who test positive for SARS‐CoV‐2 while asymptomatic may benefit from monoclonal antibody therapy to prevent disease progression. All hospital staff members working with immunocompromised patients should be promptly encouraged to follow infection prevention behaviors and receive SARS‐CoV‐2 vaccination. Conclusion: SARS‐CoV‐2 outbreaks on immunocompromised units can be mitigated through prompt identification of cases and robust infection prevention practices. [ABSTRACT FROM AUTHOR]

Published

2022

32. Viral dynamics of acute SARS-CoV-2 infection

Author

Kissler, Stephen M., primary, Fauver, Joseph R., additional, Mack, Christina, additional, Olesen, Scott W., additional, Tai, Caroline, additional, Shiue, Kristin Y., additional, Kalinich, Chaney C., additional, Jednak, Sarah, additional, Ott, Isabel M., additional, Vogels, Chantal B.F., additional, Wohlgemuth, Jay, additional, Weisberger, James, additional, DiFiori, John, additional, Anderson, Deverick J., additional, Mancell, Jimmie, additional, Ho, David D., additional, Grubaugh, Nathan D., additional, and Grad, Yonatan H., additional

Published

2020

33. Saliva or Nasopharyngeal Swab Specimens for Detection of SARS-CoV-2

Author

Wyllie, Anne L., primary, Fournier, John, additional, Casanovas-Massana, Arnau, additional, Campbell, Melissa, additional, Tokuyama, Maria, additional, Vijayakumar, Pavithra, additional, Warren, Joshua L., additional, Geng, Bertie, additional, Muenker, M. Catherine, additional, Moore, Adam J., additional, Vogels, Chantal B.F., additional, Petrone, Mary E., additional, Ott, Isabel M., additional, Lu, Peiwen, additional, Venkataraman, Arvind, additional, Lu-Culligan, Alice, additional, Klein, Jonathan, additional, Earnest, Rebecca, additional, Simonov, Michael, additional, Datta, Rupak, additional, Handoko, Ryan, additional, Naushad, Nida, additional, Sewanan, Lorenzo R., additional, Valdez, Jordan, additional, White, Elizabeth B., additional, Lapidus, Sarah, additional, Kalinich, Chaney C., additional, Jiang, Xiaodong, additional, Kim, Daniel J., additional, Kudo, Eriko, additional, Linehan, Melissa, additional, Mao, Tianyang, additional, Moriyama, Miyu, additional, Oh, Ji E., additional, Park, Annsea, additional, Silva, Julio, additional, Song, Eric, additional, Takahashi, Takehiro, additional, Taura, Manabu, additional, Weizman, Orr-El, additional, Wong, Patrick, additional, Yang, Yexin, additional, Bermejo, Santos, additional, Odio, Camila D., additional, Omer, Saad B., additional, Dela Cruz, Charles S., additional, Farhadian, Shelli, additional, Martinello, Richard A., additional, Iwasaki, Akiko, additional, Grubaugh, Nathan D., additional, and Ko, Albert I., additional

Published

2020

34. Real-time public health communication of local SARS-CoV-2 genomic epidemiology

Author

Kalinich, Chaney C., primary, Jensen, Cole G., additional, Neugebauer, Peter, additional, Petrone, Mary E., additional, Peña-Hernández, Mario, additional, Ott, Isabel M., additional, Wyllie, Anne L., additional, Alpert, Tara, additional, Vogels, Chantal B. F., additional, Fauver, Joseph R., additional, Grubaugh, Nathan D., additional, and Brito, Anderson F., additional

Published

2020

35. Saliva is more sensitive for SARS-CoV-2 detection in COVID-19 patients than nasopharyngeal swabs

Author

Wyllie, Anne L., primary, Fournier, John, additional, Casanovas-Massana, Arnau, additional, Campbell, Melissa, additional, Tokuyama, Maria, additional, Vijayakumar, Pavithra, additional, Geng, Bertie, additional, Muenker, M. Catherine, additional, Moore, Adam J., additional, Vogels, Chantal B.F., additional, Petrone, Mary E., additional, Ott, Isabel M., additional, Lu, Peiwen, additional, Venkataraman, Arvind, additional, Lu-Culligan, Alice, additional, Klein, Jonathan, additional, Earnest, Rebecca, additional, Simonov, Michael, additional, Datta, Rupak, additional, Handoko, Ryan, additional, Naushad, Nida, additional, Sewanan, Lorenzo R., additional, Valdez, Jordan, additional, White, Elizabeth B., additional, Lapidus, Sarah, additional, Kalinich, Chaney C., additional, Jiang, Xiaodong, additional, Kim, Daniel J., additional, Kudo, Eriko, additional, Linehan, Melissa, additional, Mao, Tianyang, additional, Moriyama, Miyu, additional, Oh, Ji Eun, additional, Park, Annsea, additional, Silva, Julio, additional, Song, Eric, additional, Takahashi, Takehiro, additional, Taura, Manabu, additional, Weizman, Orr-El, additional, Wong, Patrick, additional, Yang, Yexin, additional, Bermejo, Santos, additional, Odio, Camila, additional, Omer, Saad B., additional, Dela Cruz, Charles S., additional, Farhadian, Shelli, additional, Martinello, Richard A., additional, Iwasaki, Akiko, additional, Grubaugh, Nathan D., additional, and Ko, Albert I., additional

Published

2020

36. Analytical sensitivity and efficiency comparisons of SARS-COV-2 qRT-PCR primer-probe sets

Author

Vogels, Chantal B.F., primary, Brito, Anderson F., additional, Wyllie, Anne L., additional, Fauver, Joseph R., additional, Ott, Isabel M., additional, Kalinich, Chaney C., additional, Petrone, Mary E., additional, Casanovas-Massana, Arnau, additional, Muenker, M. Catherine, additional, Moore, Adam J., additional, Klein, Jonathan, additional, Lu, Peiwen, additional, Lu-Culligan, Alice, additional, Jiang, Xiaodong, additional, Kim, Daniel J., additional, Kudo, Eriko, additional, Mao, Tianyang, additional, Moriyama, Miyu, additional, Oh, Ji Eun, additional, Park, Annsea, additional, Silva, Julio, additional, Song, Eric, additional, Takahashi, Takehiro, additional, Taura, Manabu, additional, Tokuyama, Maria, additional, Venkataraman, Arvind, additional, Weizman, Orr-El, additional, Wong, Patrick, additional, Yang, Yexin, additional, Cheemarla, Nagarjuna R., additional, White, Elizabeth B., additional, Lapidus, Sarah, additional, Earnest, Rebecca, additional, Geng, Bertie, additional, Vijayakumar, Pavithra, additional, Odio, Camila, additional, Fournier, John, additional, Bermejo, Santos, additional, Farhadian, Shelli, additional, Dela Cruz, Charles S., additional, Iwasaki, Akiko, additional, Ko, Albert I., additional, Landry, Marie L., additional, Foxman, Ellen F., additional, and Grubaugh, Nathan D., additional

Published

2020

37. Diverse functional autoantibodies in patients with COVID-19

Author

Wang, Eric Y., Mao, Tianyang, Klein, Jon, Dai, Yile, Huck, John D., Jaycox, Jillian R., Liu, Feimei, Zhou, Ting, Israelow, Benjamin, Wong, Patrick, Coppi, Andreas, Lucas, Carolina, Silva, Julio, Oh, Ji Eun, Song, Eric, Perotti, Emily S., Zheng, Neil S., Fischer, Suzanne, Campbell, Melissa, Fournier, John B., Wyllie, Anne L., Vogels, Chantal B. F., Ott, Isabel M., Kalinich, Chaney C., Petrone, Mary E., Watkins, Anne E., Dela Cruz, Charles, Farhadian, Shelli F., Schulz, Wade L., Ma, Shuangge, Grubaugh, Nathan D., Ko, Albert I., Iwasaki, Akiko, and Ring, Aaron M.

Abstract

COVID-19 manifests with a wide spectrum of clinical phenotypes that are characterized by exaggerated and misdirected host immune responses1–6. Although pathological innate immune activation is well-documented in severe disease1, the effect of autoantibodies on disease progression is less well-defined. Here we use a high-throughput autoantibody discovery technique known as rapid extracellular antigen profiling7to screen a cohort of 194 individuals infected with SARS-CoV-2, comprising 172 patients with COVID-19 and 22 healthcare workers with mild disease or asymptomatic infection, for autoantibodies against 2,770 extracellular and secreted proteins (members of the exoproteome). We found that patients with COVID-19 exhibit marked increases in autoantibody reactivities as compared to uninfected individuals, and show a high prevalence of autoantibodies against immunomodulatory proteins (including cytokines, chemokines, complement components and cell-surface proteins). We established that these autoantibodies perturb immune function and impair virological control by inhibiting immunoreceptor signalling and by altering peripheral immune cell composition, and found that mouse surrogates of these autoantibodies increase disease severity in a mouse model of SARS-CoV-2 infection. Our analysis of autoantibodies against tissue-associated antigens revealed associations with specific clinical characteristics. Our findings suggest a pathological role for exoproteome-directed autoantibodies in COVID-19, with diverse effects on immune functionality and associations with clinical outcomes.

Published

2021

38. Detection of SARS-CoV-2 RNA by multiplex RT-qPCR.

Author

Kudo, Eriko, Israelow, Benjamin, Vogels, Chantal B. F., Lu, Peiwen, Wyllie, Anne L., Tokuyama, Maria, Venkataraman, Arvind, Brackney, Doug E., Ott, Isabel M., Petrone, Mary E., Earnest, Rebecca, Lapidus, Sarah, Muenker, M. Catherine, Moore, Adam J., Casanovas-Massana, Arnau, Omer, Saad B., Dela Cruz, Charles S., Farhadian, Shelli F., Ko, Albert I., and Grubaugh, Nathan D.

Subjects

SARS-CoV-2, RNA

Abstract

The current quantitative reverse transcription PCR (RT-qPCR) assay recommended for severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) testing in the United States requires analysis of 3 genomic targets per sample: 2 viral and 1 host. To simplify testing and reduce the volume of required reagents, we devised a multiplex RT-qPCR assay to detect SARS-CoV-2 in a single reaction. We used existing N1, N2, and RP primer and probe sets by the Centers for Disease Control and Prevention, but substituted fluorophores to allow multiplexing of the assay. The cycle threshold (Ct) values of our multiplex RT-qPCR were comparable to those obtained by the single assay adapted for research purposes. Low copy numbers (≥500 copies/reaction) of SARS-CoV-2 RNA were consistently detected by the multiplex RT-qPCR. Our novel multiplex RT-qPCR improves upon current single diagnostics by saving reagents, costs, time, and labor. The current RT-qPCR assay recommended for SARS-CoV-2 testing in the United States requires analysis of three genomic targets per sample: two viral and one host. This study describes a multiplex PCR that saves both reagents and labor while accurately detecting SARS-CoV-2 RNA. [ABSTRACT FROM AUTHOR]

Published

2020

39. Transmissibility of emerging viral zoonoses

Author

Walker, Joseph W., primary, Han, Barbara A., additional, Ott, Isabel M., additional, and Drake, John M., additional

Published

2018

40. Accelerated SARS-CoV-2 intrahost evolution leading to distinct genotypes during chronic infection

Author

Chaguza, Chrispin, Hahn, Anne M., Petrone, Mary E., Zhou, Shuntai, Ferguson, David, Breban, Mallery I., Pham, Kien, Peña-Hernández, Mario A., Castaldi, Christopher, Hill, Verity, Billig, Kendall, Earnest, Rebecca, Fauver, Joseph R., Kalinch, Chaney C., Kerantzas, Nicholas, Koch, Tobias R., De Kumar, Bony, Landry, Marie L., Ott, Isabel M., Peaper, David, Tikhonova, Irina R., Vogels, Chantal B.F., Schulz, Wade, Swanstrom, Ronald I., Roberts, Scott C., and Grubaugh, Nathan D.

Abstract

The chronic infection hypothesis for novel severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) variant emergence is increasingly gaining credence following the appearance of Omicron. Here, we investigate intrahost evolution and genetic diversity of lineage B.1.517 during a SARS-CoV-2 chronic infection lasting for 471 days (and still ongoing) with consistently recovered infectious virus and high viral genome copies. During the infection, we find an accelerated virus evolutionary rate translating to 35 nucleotide substitutions per year, approximately 2-fold higher than the global SARS-CoV-2 evolutionary rate. This intrahost evolution results in the emergence and persistence of at least three genetically distinct genotypes, suggesting the establishment of spatially structured viral populations continually reseeding different genotypes into the nasopharynx. Finally, we track the temporal dynamics of genetic diversity to identify advantageous mutations and highlight hallmark changes for chronic infection. Our findings demonstrate that untreated chronic infections accelerate SARS-CoV-2 evolution, providing an opportunity for the emergence of genetically divergent variants.

Published

2023

41. Intranasal neomycin evokes broad-spectrum antiviral immunity in the upper respiratory tract.

Author

Mao T, Kim J, Peña-Hernández MA, Valle G, Moriyama M, Luyten S, Ott IM, Gomez-Calvo ML, Gehlhausen JR, Baker E, Israelow B, Slade M, Sharma L, Liu W, Ryu C, Korde A, Lee CJ, Silva Monteiro V, Lucas C, Dong H, Yang Y, Gopinath S, Wilen CB, Palm N, Dela Cruz CS, and Iwasaki A

Subjects

Animals, Mice, Humans, COVID-19 immunology, COVID-19 prevention & control, COVID-19 virology, Respiratory Tract Infections immunology, Respiratory Tract Infections drug therapy, Respiratory Tract Infections virology, Respiratory Tract Infections prevention & control, Nasal Mucosa immunology, Nasal Mucosa virology, Nasal Mucosa drug effects, Disease Models, Animal, COVID-19 Drug Treatment, Mesocricetus, Female, Influenza A virus drug effects, Influenza A virus immunology, Neomycin pharmacology, Neomycin administration & dosage, Administration, Intranasal, Antiviral Agents pharmacology, Antiviral Agents administration & dosage, SARS-CoV-2 immunology, SARS-CoV-2 drug effects

Abstract

Respiratory virus infections in humans cause a broad-spectrum of diseases that result in substantial morbidity and mortality annually worldwide. To reduce the global burden of respiratory viral diseases, preventative and therapeutic interventions that are accessible and effective are urgently needed, especially in countries that are disproportionately affected. Repurposing generic medicine has the potential to bring new treatments for infectious diseases to patients efficiently and equitably. In this study, we found that intranasal delivery of neomycin, a generic aminoglycoside antibiotic, induces the expression of interferon-stimulated genes (ISGs) in the nasal mucosa that is independent of the commensal microbiota. Prophylactic or therapeutic administration of neomycin provided significant protection against upper respiratory infection and lethal disease in a mouse model of COVID-19. Furthermore, neomycin treatment protected Mx1 congenic mice from upper and lower respiratory infections with a highly virulent strain of influenza A virus. In Syrian hamsters, neomycin treatment potently mitigated contact transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2). In healthy humans, intranasal application of neomycin-containing Neosporin ointment was well tolerated and effective at inducing ISG expression in the nose in a subset of participants. These findings suggest that neomycin has the potential to be harnessed as a host-directed antiviral strategy for the prevention and treatment of respiratory viral infections., Competing Interests: Competing interests statement:A.I. co-founded and consults for RIGImmune, Xanadu Bio and PanV, consults for Paratus Sciences, InvisiShield Technologies, and is a member of the Board of Directors of Roche Holding Ltd.

Published

2024

42. DengueSeq: A pan-serotype whole genome amplicon sequencing protocol for dengue virus.

Author

Vogels CBF, Hill V, Breban MI, Chaguza C, Paul LM, Sodeinde A, Taylor-Salmon E, Ott IM, Petrone ME, Dijk D, Jonges M, Welkers MRA, Locksmith T, Dong Y, Tarigopula N, Tekin O, Schmedes S, Bunch S, Cano N, Jaber R, Panzera C, Stryker I, Vergara J, Zimler R, Kopp E, Heberlein L, Morrison AM, Michael SF, and Grubaugh ND

Abstract

Background: The increasing burden of dengue virus on public health due to more explosive and frequent outbreaks highlights the need for improved surveillance and control. Genomic surveillance of dengue virus not only provides important insights into the emergence and spread of genetically diverse serotypes and genotypes, but it is also critical to monitor the effectiveness of newly implemented control strategies. Here, we present DengueSeq, an amplicon sequencing protocol, which enables whole-genome sequencing of all four dengue virus serotypes., Results: We developed primer schemes for the four dengue virus serotypes, which can be combined into a pan-serotype approach. We validated both approaches using genetically diverse virus stocks and clinical specimens that contained a range of virus copies. High genome coverage (>95%) was achieved for all genotypes, except DENV2 (genotype VI) and DENV 4 (genotype IV) sylvatics, with similar performance of the serotype-specific and pan-serotype approaches. The limit of detection to reach 70% coverage was 10 1 -10 2 RNA copies/μL for all four serotypes, which is similar to other commonly used primer schemes. DengueSeq facilitates the sequencing of samples without known serotypes, allows the detection of multiple serotypes in the same sample, and can be used with a variety of library prep kits and sequencing instruments., Conclusions: DengueSeq was systematically evaluated with virus stocks and clinical specimens spanning the genetic diversity within each of the four dengue virus serotypes. The primer schemes can be plugged into existing amplicon sequencing workflows to facilitate the global need for expanded dengue virus genomic surveillance., Competing Interests: Competing interests The authors declare that they have no competing interests.

Published

2023

43. Variant abundance estimation for SARS-CoV-2 in wastewater using RNA-Seq quantification.

Author

Baaijens JA, Zulli A, Ott IM, Petrone ME, Alpert T, Fauver JR, Kalinich CC, Vogels CBF, Breban MI, Duvallet C, McElroy K, Ghaeli N, Imakaev M, Mckenzie-Bennett M, Robison K, Plocik A, Schilling R, Pierson M, Littlefield R, Spencer M, Simen BB, Hanage WP, Grubaugh ND, Peccia J, and Baym M

Abstract

Effectively monitoring the spread of SARS-CoV-2 variants is essential to efforts to counter the ongoing pandemic. Wastewater monitoring of SARS-CoV-2 RNA has proven an effective and efficient technique to approximate COVID-19 case rates in the population. Predicting variant abundances from wastewater, however, is technically challenging. Here we show that by sequencing SARS-CoV-2 RNA in wastewater and applying computational techniques initially used for RNA-Seq quantification, we can estimate the abundance of variants in wastewater samples. We show by sequencing samples from wastewater and clinical isolates in Connecticut U.S.A. between January and April 2021 that the temporal dynamics of variant strains broadly correspond. We further show that this technique can be used with other wastewater sequencing techniques by expanding to samples taken across the United States in a similar timeframe. We find high variability in signal among individual samples, and limited ability to detect the presence of variants with clinical frequencies <10%; nevertheless, the overall trends match what we observed from sequencing clinical samples. Thus, while clinical sequencing remains a more sensitive technique for population surveillance, wastewater sequencing can be used to monitor trends in variant prevalence in situations where clinical sequencing is unavailable or impractical.

Published

2021

44. Combining genomic and epidemiological data to compare the transmissibility of SARS-CoV-2 lineages.

Author

Petrone ME, Rothman JE, Breban MI, Ott IM, Russell A, Lasek-Nesselquist E, Kelly K, Omerza G, Renzette N, Watkins AE, Kalinich CC, Alpert T, Brito AF, Earnest R, Tikhonova IR, Castaldi C, Kelly JP, Shudt M, Plitnick J, Schneider E, Murphy S, Neal C, Laszlo E, Altajar A, Pearson C, Muyombwe A, Downing R, Razeq J, Niccolai L, Wilson MS, Anderson ML, Wang J, Liu C, Hui P, Mane S, Taylor BP, Hanage WP, Landry ML, Peaper DR, Bilguvar K, Fauver JR, Vogels CBF, Gardner LM, Pitzer VE, St George K, Adams MD, and Grubaugh ND

Abstract

Emerging SARS-CoV-2 variants have shaped the second year of the COVID-19 pandemic and the public health discourse around effective control measures. Evaluating the public health threat posed by a new variant is essential for appropriately adapting response efforts when community transmission is detected. However, this assessment requires that a true comparison can be made between the new variant and its predecessors because factors other than the virus genotype may influence spread and transmission. In this study, we develop a framework that integrates genomic surveillance data to estimate the relative effective reproduction number (R t ) of co-circulating lineages. We use Connecticut, a state in the northeastern United States in which the SARS-CoV-2 variants B.1.1.7 and B.1.526 co-circulated in early 2021, as a case study for implementing this framework. We find that the R t of B.1.1.7 was 6-10% larger than that of B.1.526 in Connecticut in the midst of a COVID-19 vaccination campaign. To assess the generalizability of this framework, we apply it to genomic surveillance data from New York City and observe the same trend. Finally, we use discrete phylogeography to demonstrate that while both variants were introduced into Connecticut at comparable frequencies, clades that resulted from introductions of B.1.1.7 were larger than those resulting from B.1.526 introductions. Our framework, which uses open-source methods requiring minimal computational resources, may be used to monitor near real-time variant dynamics in a myriad of settings.

Published

2021

45. Multiplex qPCR discriminates variants of concern to enhance global surveillance of SARS-CoV-2.

Author

Vogels CBF, Breban MI, Ott IM, Alpert T, Petrone ME, Watkins AE, Kalinich CC, Earnest R, Rothman JE, Goes de Jesus J, Morales Claro I, Magalhães Ferreira G, Crispim MAE, Singh L, Tegally H, Anyaneji UJ, Hodcroft EB, Mason CE, Khullar G, Metti J, Dudley JT, MacKay MJ, Nash M, Wang J, Liu C, Hui P, Murphy S, Neal C, Laszlo E, Landry ML, Muyombwe A, Downing R, Razeq J, de Oliveira T, Faria NR, Sabino EC, Neher RA, Fauver JR, and Grubaugh ND

Subjects

COVID-19 diagnosis, COVID-19 genetics, DNA Primers, Humans, Multiplex Polymerase Chain Reaction methods, Mutation, Polyproteins genetics, Viral Proteins genetics, COVID-19 virology, SARS-CoV-2 genetics

Abstract

With the emergence of Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) variants that may increase transmissibility and/or cause escape from immune responses, there is an urgent need for the targeted surveillance of circulating lineages. It was found that the B.1.1.7 (also 501Y.V1) variant, first detected in the United Kingdom, could be serendipitously detected by the Thermo Fisher TaqPath COVID-19 PCR assay because a key deletion in these viruses, spike Δ69-70, would cause a "spike gene target failure" (SGTF) result. However, a SGTF result is not definitive for B.1.1.7, and this assay cannot detect other variants of concern (VOC) that lack spike Δ69-70, such as B.1.351 (also 501Y.V2), detected in South Africa, and P.1 (also 501Y.V3), recently detected in Brazil. We identified a deletion in the ORF1a gene (ORF1a Δ3675-3677) in all 3 variants, which has not yet been widely detected in other SARS-CoV-2 lineages. Using ORF1a Δ3675-3677 as the primary target and spike Δ69-70 to differentiate, we designed and validated an open-source PCR assay to detect SARS-CoV-2 VOC. Our assay can be rapidly deployed in laboratories around the world to enhance surveillance for the local emergence and spread of B.1.1.7, B.1.351, and P.1., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

46. Evidence for SARS-CoV-2 Spike Protein in the Urine of COVID-19 Patients.

Author

George S, Pal AC, Gagnon J, Timalsina S, Singh P, Vydyam P, Munshi M, Chiu JE, Renard I, Harden CA, Ott IM, Watkins AE, Vogels CBF, Lu P, Tokuyama M, Venkataraman A, Casanovas-Massana A, Wyllie AL, Rao V, Campbell M, Farhadian SF, Grubaugh ND, Dela Cruz CS, Ko AI, Berna Perez AZ, Akaho EH, Moledina DG, Testani J, John AR, Ledizet M, and Mamoun CB

Subjects

Adult, Child, Humans, Pandemics, SARS-CoV-2 genetics, COVID-19 diagnosis, Spike Glycoprotein, Coronavirus genetics

Abstract

Background: SARS-CoV-2 infection has, as of April 2021, affected >133 million people worldwide, causing >2.5 million deaths. Because the large majority of individuals infected with SARS-CoV-2 are asymptomatic, major concerns have been raised about possible long-term consequences of the infection., Methods: Wedeveloped an antigen capture assay to detect SARS-CoV-2 spike protein in urine samples from patients with COVID-19whose diagnosis was confirmed by positive PCR results from nasopharyngeal swabs (NP-PCR+) forSARS-CoV-2. We used a collection of 233 urine samples from 132 participants from Yale New Haven Hospital and the Children's Hospital of Philadelphia that were obtained during the pandemic (106 NP-PCR+ and 26 NP-PCR-), and a collection of 20 urine samples from 20 individuals collected before the pandemic., Results: Our analysis identified 23 out of 91 (25%) NP-PCR+ adult participants with SARS-CoV-2 spike S1 protein in urine (Ur-S+). Interestingly, although all NP-PCR+ children were Ur-S-, one child who was NP-PCR- was found to be positive for spike protein in their urine. Of the 23 adults who were Ur-S+, only one individual showed detectable viral RNA in urine. Our analysis further showed that 24% and 21% of adults who were NP-PCR+ had high levels of albumin and cystatin C, respectively, in their urine. Among individuals with albuminuria (>0.3 mg/mg of creatinine), statistical correlation could be found between albumin and spike protein in urine., Conclusions: Together, our data showed that one of four individuals infected with SARS-CoV-2 develop renal abnormalities, such as albuminuria. Awareness about the long-term effect of these findings is warranted., Competing Interests: A.I. Ko reportsreceiving research funding from Bristol Myers Squibb, Regeneron, Serimmune, and Tata Medical and Diagnostics; and having consultancy agreements with Tata Medical and Diagnostics. D.G. Moledina reports receiving honoraria from the British Medical Journal, National Kidney Foundation, and Remedy Health Media; serving as an editorial board member for Kidney360; receiving research funding from National Institute of Diabetes and Digestive and Kidney Diseases (grants K23DK117065, R01DK12681, UH3DK114866, and P30DK079310), outside the submitted work; and being a coinventor of the pending patent application “Methods and Systems for Diagnosis of Acute Interstitial Nephritis,” which is subject to an option for a license agreement with RenalytixAI Inc. A.R. John reports receiving research funding from the Burroughs Wellcome Fund and National Institutes of Health (NIH); being a scientific advisor for, or member of, Pluton Biosciences; and having patents and inventions involving antimalarials and malaria and SARS-CoV-2 biomarkers. V. Rao reports patents and inventions with Corvidia Therapeutics, and having consultancy agreements with Translational Catalyst. J. Testani reports receiving research funding from Abbott, Boehringer Ingelheim, Bristol Myers Squibb, 3ive Labs, Merck, NIH, Otsuka, Sanofi, Sequana Medical, The Foundry, and the US Food and Drug Administration; having consultancy agreements with, and receiving honoraria from, AstraZeneca, Bayer, Boehringer Ingelheim, Bristol Myers Squibb, Cardionomic, FIRE1, Lexicon, Magenta Med, Merck, Novartis, Regeneron, Reprieve, Sanofi, Sequana Medical, Windtree Therapeutics, and W.L. Gore; having patents and inventions with Corvidia, Reprieve Inc., and Yale University; and having ownership interest in Reprive Inc. All remaining authors have nothing to disclose., (Copyright © 2021 by the American Society of Nephrology.)

Published

2021

47. PCR assay to enhance global surveillance for SARS-CoV-2 variants of concern.

Author

Vogels CBF, Breban MI, Alpert T, Petrone ME, Watkins AE, Ott IM, de Jesus JG, Claro IM, Ferreira GM, Crispim MAE, Singh L, Tegally H, Anyaneji UJ, Hodcroft EB, Mason CE, Khullar G, Metti J, Dudley JT, MacKay MJ, Nash M, Wang J, Liu C, Hui P, Murphy S, Neal C, Laszlo E, Landry ML, Muyombwe A, Downing R, Razeq J, de Oliveira T, Faria NR, Sabino EC, Neher RA, Fauver JR, and Grubaugh ND

Abstract

With the emergence of SARS-CoV-2 variants that may increase transmissibility and/or cause escape from immune responses 1-3 , there is an urgent need for the targeted surveillance of circulating lineages. It was found that the B.1.1.7 (also 501Y.V1) variant first detected in the UK 4,5 could be serendipitously detected by the ThermoFisher TaqPath COVID-19 PCR assay because a key deletion in these viruses, spike Δ69-70, would cause a "spike gene target failure" (SGTF) result. However, a SGTF result is not definitive for B.1.1.7, and this assay cannot detect other variants of concern that lack spike Δ69-70, such as B.1.351 (also 501Y.V2) detected in South Africa 6 and P.1 (also 501Y.V3) recently detected in Brazil 7 . We identified a deletion in the ORF1a gene (ORF1a Δ3675-3677) in all three variants, which has not yet been widely detected in other SARS-CoV-2 lineages. Using ORF1a Δ3675-3677 as the primary target and spike Δ69-70 to differentiate, we designed and validated an open source PCR assay to detect SARS-CoV-2 variants of concern 8 . Our assay can be rapidly deployed in laboratories around the world to enhance surveillance for the local emergence spread of B.1.1.7, B.1.351, and P.1.

Published

2021

48. Diverse Functional Autoantibodies in Patients with COVID-19.

Author

Wang EY, Mao T, Klein J, Dai Y, Huck JD, Liu F, Zheng NS, Zhou T, Israelow B, Wong P, Lucas C, Silva J, Oh JE, Song E, Perotti ES, Fischer S, Campbell M, Fournier JB, Wyllie AL, Vogels CBF, Ott IM, Kalinich CC, Petrone ME, Watkins AE, Cruz CD, Farhadian SF, Schulz WL, Grubaugh ND, Ko AI, Iwasaki A, and Ring AM

Abstract

COVID-19 manifests with a wide spectrum of clinical phenotypes that are characterized by exaggerated and misdirected host immune responses 1-8 . While pathological innate immune activation is well documented in severe disease 1 , the impact of autoantibodies on disease progression is less defined. Here, we used a high-throughput autoantibody discovery technique called Rapid Extracellular Antigen Profiling (REAP) to screen a cohort of 194 SARS-CoV-2 infected COVID-19 patients and healthcare workers for autoantibodies against 2,770 extracellular and secreted proteins (the "exoproteome"). We found that COVID-19 patients exhibit dramatic increases in autoantibody reactivities compared to uninfected controls, with a high prevalence of autoantibodies against immunomodulatory proteins including cytokines, chemokines, complement components, and cell surface proteins. We established that these autoantibodies perturb immune function and impair virological control by inhibiting immunoreceptor signaling and by altering peripheral immune cell composition, and found that murine surrogates of these autoantibodies exacerbate disease severity in a mouse model of SARS-CoV-2 infection. Analysis of autoantibodies against tissue-associated antigens revealed associations with specific clinical characteristics and disease severity. In summary, these findings implicate a pathological role for exoproteome-directed autoantibodies in COVID-19 with diverse impacts on immune functionality and associations with clinical outcomes., Competing Interests: Competing Interests A.M.R., E.Y.W., and Y.D. are inventors of a patent describing the REAP technology.

Published

2021

49. Saliva viral load is a dynamic unifying correlate of COVID-19 severity and mortality.

Author

Silva J, Lucas C, Sundaram M, Israelow B, Wong P, Klein J, Tokuyama M, Lu P, Venkataraman A, Liu F, Mao T, Oh JE, Park A, Casanovas-Massana A, Vogels CBF, Muenker MC, Zell J, Fournier JB, Campbell M, Chiorazzi M, Fuentes ER, Petrone ME, Kalinich CC, Ott IM, Watkins A, Moore AJ, Nakahata M, Farhadian S, Cruz CD, Ko AI, Schulz WL, Ring A, Ma S, Omer S, Wyllie AL, and Iwasaki A

Abstract

While several clinical and immunological parameters correlate with disease severity and mortality in SARS-CoV-2 infection, work remains in identifying unifying correlates of coronavirus disease 2019 (COVID-19) that can be used to guide clinical practice. Here, we examine saliva and nasopharyngeal (NP) viral load over time and correlate them with patient demographics, and cellular and immune profiling. We found that saliva viral load was significantly higher in those with COVID-19 risk factors; that it correlated with increasing levels of disease severity and showed a superior ability over nasopharyngeal viral load as a predictor of mortality over time (AUC=0.90). A comprehensive analysis of immune factors and cell subsets revealed strong predictors of high and low saliva viral load, which were associated with increased disease severity or better overall outcomes, respectively. Saliva viral load was positively associated with many known COVID-19 inflammatory markers such as IL-6, IL-18, IL-10, and CXCL10, as well as type 1 immune response cytokines. Higher saliva viral loads strongly correlated with the progressive depletion of platelets, lymphocytes, and effector T cell subsets including circulating follicular CD4 T cells (cTfh). Anti-spike (S) and anti-receptor binding domain (RBD) IgG levels were negatively correlated with saliva viral load showing a strong temporal association that could help distinguish severity and mortality in COVID-19. Finally, patients with fatal COVID-19 exhibited higher viral loads, which correlated with the depletion of cTfh cells, and lower production of anti-RBD and anti-S IgG levels. Together these results demonstrated that viral load - as measured by saliva but not nasopharyngeal - is a dynamic unifying correlate of disease presentation, severity, and mortality over time., Competing Interests: Competing interests: AI served as a consultant for Spring Discovery and Adaptive Biotechnologies.

Published

2021

50. Simply saliva: stability of SARS-CoV-2 detection negates the need for expensive collection devices.

Author

Ott IM, Strine MS, Watkins AE, Boot M, Kalinich CC, Harden CA, Vogels CBF, Casanovas-Massana A, Moore AJ, Muenker MC, Nakahata M, Tokuyama M, Nelson A, Fournier J, Bermejo S, Campbell M, Datta R, Dela Cruz CS, Farhadian SF, Ko AI, Iwasaki A, Grubaugh ND, Wilen CB, and Wyllie AL

Abstract

Most currently approved strategies for the collection of saliva for COVID-19 diagnostics require specialized tubes containing buffers promoted for the stabilization of SARS-CoV-2 RNA and virus inactivation. Yet many of these are expensive, in limited supply, and not necessarily validated specifically for viral RNA. While saliva is a promising sample type as it can be reliably self-collected for the sensitive detection of SARS-CoV-2, the expense and availability of these collection tubes are prohibitive to mass testing efforts. Therefore, we investigated the stability of SARS-CoV-2 RNA and infectious virus detection from saliva without supplementation. We tested RNA stability over extended periods of time (2-25 days) and at temperatures representing at-home storage and elevated temperatures which might be experienced when cold chain transport may be unavailable. We found SARS-CoV-2 RNA in saliva from infected individuals is stable at 4°C, room temperature (~19°C), and 30°C for prolonged periods and found limited evidence for viral replication in saliva. This work demonstrates that expensive saliva collection options involving RNA stabilization and virus inactivation buffers are not always needed, permitting the use of cheaper collection options. Affordable testing methods are urgently needed to meet current testing demands and for continued surveillance in reopening strategies.

Published

2020