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Volume 31, Number 2—February 2025
Research Letter
Sin Nombre Virus as Unlikely Reverse Zoonotic Threat
Suggested citation for this article
Abstract
We inoculated clinical materials into deer mice to attempt isolation of Sin Nombre virus. We did not observe productive infection in the natural rodent reservoir. Genomic comparisons between rodent reservoirs and human disease may provide insight into hantavirus evolution and genetic determinants, but reverse zoonosis of Sin Nombre virus appears unlikely.
Sin Nombre virus (SNV) is the primary cause of human hantavirus cardiopulmonary syndrome (HCPS) in North America. In nature, Peromyscus maniculatus deer mice are the reservoir host for SNV, although other rodents may also serve as competent reservoir hosts (1). Human HCPS is characterized by a sudden onset of respiratory distress that rapidly progresses and requires urgent medical attention.
As for many hantaviruses, SNV isolation has proven challenging. The extended prodromal phase, often >14 days, precludes collection of optimal samples with peak viral titers and minimal host immune responses for virus isolation. In previous studies, Andes virus (ANDV) was isolated from serum samples fortuitously collected immediately before HCPS disease onset, as well as from oral, nasal, or urine specimens (2,3). Those detections were likely achievable because of ADV’s ability to transmit from human to human, an attribute not known in SNV, and higher viral burdens in mucosal specimens of patients infected with ANDV (4).
Samples submitted for diagnostic confirmation of HCPS are collected after symptom onset and commonly include only serum or whole blood. In Canada, hantavirus diagnostic testing is done through a combination of serologic and molecular testing at the National Microbiology Laboratory of the Public Health Agency of Canada (5). By 2024, >150 cases of HCPS in Canada had been confirmed. Despite efforts to propagate SNV from acute samples, isolation attempts on standard Vero cell culture have been unsuccessful. We previously showed that Vero cell propagation alters the virulence of SNV in nonhuman primates (NHPs) and infectivity in deer mice (6,7). We sought to assess whether direct inoculation of deer mice with clinical material would enable isolation of virus without prior Vero propagation.
We inoculated laboratory-reared deer mice (Peromyscus maniculatus rufinus, both sexes, >4 weeks of age, 3–6 per group) via intraperitoneal injection with acute serum from laboratory-confirmed symptomatic HCPS (n = 10) case-patients, SNV-infected NHPs with HCPS (n = 5), or cell culture supernatant containing Vero-propagated SNV (n = 2) (Table; Appendix). Acute specimens from HCPS case-patients were positive for SNV by reverse transcription PCR (RT-PCR), were IgM positive, and had low or no detectable IgG against hantaviruses in serum. NHP samples infected with the deer mice–only passaged SNV (6) were collected immediately before or shortly after apparent signs of disease. Those samples were ositive by reverse transcription PCR (RT-PCR) and IgM-positive by serology but also had detectable IgG. When possible, serum from HCPS case-patients was inoculated into deer mice without a freeze-thaw cycle. Serum from NHPs and the SNV cell culture supernatant were previously cryopreserved.
At 14 days after infection, when SNV in experimentally inoculated deer mice is readily detectable in multiple organs (7,8), we euthanized the mice and collected samples (blood, serum, lung, liver, spleen, kidney) for analyses. Deer mice inoculated with serum from HCPS case-patients or experimentally infected NHPs tested negative for SNV RNA. All but 1 animal had detectable IgG against the nucleocapsid protein and showed exposure to SNV (Table). That 1 animal was inoculated with human serum that had low levels of SNV detected in lung and liver specimens, although strand-specific RT-PCR could not detect antigenome RNA, suggesting inoculum-derived infection. All 7 deer mice injected with Vero-propagated SNV had multiple SNV-positive tissues, which is contradictory to our previous findings (7). Strand-specific quantitative RT-PCR confirmed the presence of replicating SNV; however, the presence of replicating SNV was 2–4 logs less than comparable tissues from mice inoculated with deer mice–only passaged SNV (Appendix Table).
Figure
Figure. Experimental infection of North American deer mice (Peromyscus maniculatus) with Sin Nombre virus (SNV) to determine whether direct inoculation with clinical material would enable isolation of virus without...
The original aim of this study was to create a reliable method to isolate hantaviruses from clinical materials from confirmed HCPS cases by using natural reservoirs. However, after attempting that approach with samples from 10 unique HCPS case-patients and material from 5 NHPs experimentally infected with an SNV strain originally isolated from the deer mice colony founders, developing that method does not seem possible, at least not as outlined here (Figure). Although we did not determine SNV-neutralizing titers, the lack of IgG response indicates that all clinical samples were likely not completely neutralized before inoculation of deer mice. Nevertheless, this work addresses an overlooked aspect of hantaviruses: the potential ability to spillback and create reverse zoonotic events. Our work suggests that spillback is unlikely, at least for SNV, which implies that humans are truly dead-end hosts of SNV. Thus, virus evolution is primarily, if not exclusively, occurring in the natural rodent reservoirs.
In conclusion, genetically, hantaviruses have proven difficult to adapt in disease modeling efforts, and only rodent-derived isolates or inocula have recapitulated human disease in hamsters and NHPs (6,9,10). The molecular determinants of virulence are largely unknown, and without a reverse genetics system will be difficult to elucidate. Thus, to clarify hantavirus evolution and genetic factors associated with human disease, SNV genomic surveillance is needed, especially to elucidate hantavirus evolution and genetic factors associated with human disease.
Dr. Prévost is a postdoctoral research scientist within the Special Pathogens program at the Public Health Agency of Canada. His primary research interests include emerging viral pathogens and the evaluation of medical countermeasures to treat and prevent them.
Acknowledgments
We thank Kevin Tierney and Kimberly Azaransky for animal husbandry and procedures and Chris Taylor for overseeing the breeding colony.
This work was reviewed and approved by the animal care and use committee of the Canadian Science Centre for Human and Animal Health and conducted by trained staff in a Canadian Council for Animal Care certified facility. All work with infectious SNV was conducted in a Biosafety Level 4 facility.
This work was funded by the Public Health Agency of Canada.
References
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e0153421 . DOIPubMedGoogle Scholar - Ferrés M, Martínez-Valdebenito C, Henriquez C, Marco C, Angulo J, Barrera A, et al. Viral shedding and viraemia of Andes virus during acute hantavirus infection: a prospective study. Lancet Infect Dis. 2024;24:775–82. DOIPubMedGoogle Scholar
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- Warner BM, Stein DR, Griffin BD, Tierney K, Leung A, Sloan A, et al. Development and characterization of a Sin Nombre virus transmission model in Peromyscus maniculatus. Viruses. 2019;11:183. DOIPubMedGoogle Scholar
- Botten J, Mirowsky K, Kusewitt D, Bharadwaj M, Yee J, Ricci R, et al. Experimental infection model for Sin Nombre hantavirus in the deer mouse (Peromyscus maniculatus). Proc Natl Acad Sci U S A. 2000;97:10578–83. DOIPubMedGoogle Scholar
- Safronetz D, Prescott J, Haddock E, Scott DP, Feldmann H, Ebihara H. Hamster-adapted Sin Nombre virus causes disseminated infection and efficiently replicates in pulmonary endothelial cells without signs of disease. J Virol. 2013;87:4778–82. DOIPubMedGoogle Scholar
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Figures
Suggested citation for this article: Prévost J, Tailor N, Leung A, Warner B, Safronetz D. Sin Nombre virus as unlikely reverse zoonotic threat. Emerg Infect Dis. 2025 Feb [date cited]. https://doi.org/10.3201/eid3102.241532
Original Publication Date: January 16, 2025
1Current affiliation: Vaccine and Infectious Disease Organization, Saskatoon, Saskatchewan, Canada.
Table of Contents – Volume 31, Number 2—February 2025
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Please use the form below to submit correspondence to the authors or contact them at the following address:
David Safronetz, National Microbiology Laboratory, Public Health Agency of Canada, 1015 Arlington St, Winnipeg, MB R3E 3R2, Canada
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