SARS-CoV-2 infectivity can be modulated through bacterial grooming of the glycocalyx

Martino, Cameron; Kellman, Benjamin P.; Sandoval, Daniel R.; Clausen, Thomas Mandel; Cooper, Robert; Benjdia, Alhosna; Soualmia, Feryel; Clark, Alex E.; Garretson, Aaron F.; Marotz, Clarisse A.; Song, Se Jin; Wandro, Stephen; Zaramela, Livia S.; Salido, Rodolfo A.; Zhu, Qiyun; Armingol, Erick; Vázquez-Baeza, Yoshiki; McDonald, Daniel; Sorrentino, James T.; Taylor, Bryn; Belda-Ferre, Pedro; Das, Promi; Ali, Farhana; Liang, Chenguang; Zhang, Yujie; Schifanella, Luca; Covizzi, Alice; Lai, Alessia; Riva, Agostino; Basting, Christopher; Broedlow, Courtney Ann; Havulinna, Aki S.; Jousilahti, Pekka; Estaki, Mehrbod; Kosciolek, Tomasz; Kuplicki, Rayus; Victor, Teresa A.; Paulus, Martin P.; Savage, Kristen E.; Benbow, Jennifer L.; Spielfogel, Emma S.; Anderson, Cheryl A. M.; Martinez, Maria Elena; Lacey, James V.; Huang, Shi; Haiminen, Niina; Parida, Laxmi; Kim, Ho-Cheol; Gilbert, Jack A.; Sweeney, Daniel A.; Allard, Sarah M.; Swafford, Austin D.; Cheng, Susan; Inouye, Michael; Niiranen, Teemu; Jain, Mohit; Salomaa, Veikko; Zengler, Karsten; Klatt, Nichole R.; Hasty, Jeff; Berteau, Olivier; Carlin, Aaron F.; Esko, Jeffrey D.; Lewis, Nathan E.; Knight, Rob
SARS-CoV-2 infectivity can be modulated through bacterial grooming of the glycocalyx

Martino, Cameron
Kellman, Benjamin P.
Sandoval, Daniel R.
Clausen, Thomas Mandel
Cooper, Robert
Benjdia, Alhosna
Soualmia, Feryel
Clark, Alex E.
Garretson, Aaron F.
Marotz, Clarisse A.
Song, Se Jin
Wandro, Stephen
Zaramela, Livia S.
Salido, Rodolfo A.
Zhu, Qiyun
Armingol, Erick
Vázquez-Baeza, Yoshiki
McDonald, Daniel
Sorrentino, James T.
Taylor, Bryn
Belda-Ferre, Pedro
Das, Promi
Ali, Farhana
Liang, Chenguang
Zhang, Yujie
Schifanella, Luca
Covizzi, Alice
Lai, Alessia
Riva, Agostino
Basting, Christopher
Broedlow, Courtney Ann
Havulinna, Aki S.
Jousilahti, Pekka
Estaki, Mehrbod
Kosciolek, Tomasz
Kuplicki, Rayus
Victor, Teresa A.
Paulus, Martin P.
Savage, Kristen E.
Benbow, Jennifer L.
Spielfogel, Emma S.
Anderson, Cheryl A. M.
Martinez, Maria Elena
Lacey, James V.
Huang, Shi
Haiminen, Niina
Parida, Laxmi
Kim, Ho-Cheol
Gilbert, Jack A.
Sweeney, Daniel A.
Allard, Sarah M.
Swafford, Austin D.
Cheng, Susan
Inouye, Michael
Niiranen, Teemu
Jain, Mohit
Salomaa, Veikko
Zengler, Karsten
Klatt, Nichole R.
Hasty, Jeff
Berteau, Olivier
Carlin, Aaron F.
Esko, Jeffrey D.
Lewis, Nathan E.
Knight, Rob
Katso/Avaa
Lataukset: 

American Society for Microbiology
doi:10.1128/mbio.04015-24
URI
https://doi.org/10.1128/mbio.04015-24
Näytä kaikki kuvailutiedot
Julkaisun pysyvä osoite on:
https://urn.fi/URN:NBN:fi-fe2025082788639
Tiivistelmä
The gastrointestinal (GI) tract is a site of replication of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) and GI symptoms are often reported by patients. SARS-CoV-2 cell entry depends upon heparan sulfate (HS) proteoglycans, which commensal bacteria that bathe the human mucosa are known to modify. To explore human gut HS-modifying bacterial abundances and how their presence may impact SARS-CoV-2 infection, we developed a task-based analysis of proteoglycan degradation on large-scale shotgun metagenomic data. We observed that gut bacteria with high predicted catabolic capacity for HS differ by age and sex, factors associated with coronavirus disease 2019 (COVID-19) severity, and directly by disease severity during/after infection, but do not vary between subjects with COVID-19 comorbidities or by diet. Gut commensal bacterial HS-modifying enzymes reduce spike protein binding and infection of authentic SARS-CoV-2, suggesting that bacterial grooming of the GI mucosa may impact viral susceptibility.
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