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1.
Genomic surveillance reveals dynamic shifts in the connectivity of COVID-19 epidemics (preprint)
Nathaniel L Matteson; Gabriel W Hassler; Ezra Kurzban; Madison A Schwab; Sarah A Perkins; Karthik Gangavarapu; Joshua I Levy; Edyth Parker; David Pride; Abbas Hakim; Peter De Hoff; Willi Cheung; Anelizze Castro-Martinez; Andrea Rivera; Anthony Veder; Ariana Rivera; Cassandra Wauer; Jacqueline Holmes; Jedediah Wilson; Shayla N Ngo; Ashley Plascencia; Elijah S Lawrence; Elizabeth W Smoot; Emily R Eisner; Rebecca Tsai; Marisol Chacon; Nathan A Baer; Phoebe Seaver; Rodolfo A Salido; Stefan Aigner; Toan T Ngo; Tom Barber; Tyler Ostrander; Rebecca Fielding-Miller; Elizabeth H Simmons; Oscar E Zazueta; Idanya Serafin-Higuera; Manuel Sanchez-Alavez; Jose L Moreno-Camacho; Abraham Garcia-Gil; Ashleigh R Murphy Schafer; Eric McDonald; Jeremy Corrigan; John D Malone; Sarah Stous; Seema Shah; Niema Moshiri; Alana Weiss; Catelyn Anderson; Christine M Aceves; Emily G Spencer; Emory C Hufbauer; Justin J Lee; Karthik S Ramesh; Kelly N Nguyen; Kieran Saucedo; Refugio Robles-Sikisaka; Kathleen M Fisch; Steven L Gonias; Amanda Birmingham; Daniel McDonald; Smruthi Karthikeyan; Natasha K Martin; Robert T Schooley; Agustin J Negrete; Horacio J Reyna; Jose R Chavez; Maria L Garcia; Jose M Cornejo-Bravo; David Becker; Magnus Isaksson; Nicole L Washington; William Lee; Richard S Garfein; Marco A Luna-Ruiz Esparza; Jonathan Alcantar-Fernandez; Benjamin Henson; Kristen Jepsen; Beatriz Olivares-Flores; Gisela Barrera-Badillo; Irma Lopez-Martinez; Jose E Ramirez-Gonzalez; Rita Flores-Leon; Stephen F Kingsmore; Alison Sanders; Allorah Pradenas; Benjamin White; Gary Matthews; Matt Hale; Ronald W McLawhon; Sharon L Reed; Terri Winbush; Ian H McHardy; Russel A Fielding; Laura Nicholson; Michael M Quigley; Aaron Harding; Art Mendoza; Omid Bakhtar; Sara H Browne; Jocelyn Olivas Flores; Diana G Rincon Rodriguez; Martin Gonzalez Ibarra; Luis C Robles Ibarra; Betsy J Arellano Vera; Jonathan Gonzalez Garcia; Alicia Harvey-Vera; Rob Knight; Louise C Laurent; Gene W Yeo; Joel O Wertheim; Xiang Ji; Michael Worobey; Marc A Suchard; Kristian G Andersen; Abraham Campos-Romero; Shirlee Wohl; Mark Zeller.
medrxiv; 2023.
Preprint in English | medRxiv | ID: ppzbmed-10.1101.2023.03.14.23287217

ABSTRACT

The maturation of genomic surveillance in the past decade has enabled tracking of the emergence and spread of epidemics at an unprecedented level. During the COVID-19 pandemic, for example, genomic data revealed that local epidemics varied considerably in the frequency of SARS-CoV-2 lineage importation and persistence, likely due to a combination of COVID-19 restrictions and changing connectivity. Here, we show that local COVID-19 epidemics are driven by regional transmission, including across international boundaries, but can become increasingly connected to distant locations following the relaxation of public health interventions. By integrating genomic, mobility, and epidemiological data, we find abundant transmission occurring between both adjacent and distant locations, supported by dynamic mobility patterns. We find that changing connectivity significantly influences local COVID-19 incidence. Our findings demonstrate a complex meaning of 'local' when investigating connected epidemics and emphasize the importance of collaborative interventions for pandemic prevention and mitigation.


Subject(s)
COVID-19
2.
Wastewater sequencing uncovers early, cryptic SARS-CoV-2 variant transmission (preprint)
Smruthi Karthikeyan; Joshua I Levy; Peter De Hoff; Greg Humphrey; Amanda Birmingham; Kristen Jepsen; Sawyer Farmer; Helena M. Tubb; Tommy Valles; Caitlin E Tribelhorn; Rebecca Tsai; Stefan Aigner; Shashank Sathe; Niema Moshiri; Benjamin Henson; Abbas Hakim; Nathan A Baer; Tom Barber; Pedro Belda-Ferre; Marisol Chacon; Willi Cheung; Evelyn S Crescini; Emily R Eisner; Alma L Lastrella; Elijah S Lawrence; Clarisse A Marotz; Toan T Ngo; Tyler Ostrander; Ashley Plascencia; Rodolfo A Salido; Phoebe Seaver; Elizabeth W Smoot; Daniel McDonald; Robert M Neuhard; Angela L Scioscia; Alysson M. Satterlund; Elizabeth H Simmons; Christine M Aceves; Catelyn Anderson; Karthik Gangavarapu; Emory Hufbauer; Ezra Kurzban; Justin Lee; Nathaniel L Matteson; Edyth Parker; Sarah A Perkins; Karthik S Ramesh; Refugio Robles-Sikisaka; Madison A Schwab; Emily Spencer; Shirlee Wohl; Laura Nicholson; Ian H Mchardy; David P Dimmock; Charlotte A Hobbs; Omid Bakhtar; Aaron Harding; Art Mendoza; Alexandre Bolze; David Becker; Elizabeth T Cirulli; Magnus Isaksson; Kelly M Schiabor Barrett; Nicole L Washington; John D Malone; Ashleigh Murphy Schafer; Nikos Gurfield; Sarah Stous; Rebecca Fielding-Miller; Tommi Gaines; Richard Garfein; Cheryl A. M. Anderson; Natasha K. Martin; Robert T Schooley; Brett Austin; Stephen F Kingsmore; William Lee; Seema Shah; Eric McDonald; Mark Zeller; Kathleen M Fisch; Louise C Laurent; Gene W Yeo; Kristian G Andersen; Rob Knight.
medrxiv; 2021.
Preprint in English | medRxiv | ID: ppzbmed-10.1101.2021.12.21.21268143

ABSTRACT

As SARS-CoV-2 becomes an endemic pathogen, detecting emerging variants early is critical for public health interventions. Inferring lineage prevalence by clinical testing is infeasible at scale, especially in areas with limited resources, participation, or testing/sequencing capacity, which can also introduce biases. SARS-CoV-2 RNA concentration in wastewater successfully tracks regional infection dynamics and provides less biased abundance estimates than clinical testing. Tracking virus genomic sequences in wastewater would improve community prevalence estimates and detect emerging variants. However, two factors limit wastewater-based genomic surveillance: low-quality sequence data and inability to estimate relative lineage abundance in mixed samples. Here, we resolve these critical issues to perform a high-resolution, 295-day wastewater and clinical sequencing effort, in the controlled environment of a large university campus and the broader context of the surrounding county. We develop and deploy improved virus concentration protocols and deconvolution software that fully resolve multiple virus strains from wastewater. We detect emerging variants of concern up to 14 days earlier in wastewater samples, and identify multiple instances of virus spread not captured by clinical genomic surveillance. Our study provides a scalable solution for wastewater genomic surveillance that allows early detection of SARS-CoV-2 variants and identification of cryptic transmission.

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