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Volume 29, Number 4—April 2023
Research Letter

Powassan Virus Infection Detected by Metagenomic Next-Generation Sequencing, Ohio, USA

Author affiliations: Children’s Hospital Medical Center of Akron, Akron, Ohio, USA (M. Farrington, M. Ginsberg, S.F Pangonis); Columbiana County Health District, Lisbon, Ohio, USA (J. Elenz); University of California, San Francisco, California, USA (C.Y. Chiu, S. Miller)

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Abstract

We describe a 4-year-old male patient in Ohio, USA, who had encephalitis caused by Powassan virus lineage 2. Virus was detected by using metagenomic next-generation sequencing and confirmed with IgM and plaque reduction neutralization assays. Clinicians should recognize changing epidemiology of tickborne viruses to enhance encephalitis diagnosis and management.

Powassan virus (POWV) is a tickborne flavivirus that causes encephalitis with severe neurologic sequelae (1). In the United States, POWV infections occur primarily in the Northeast and Great Lakes regions (2). We report a case of human POWV infection in Ohio.

A 4-year-old boy was brought to the emergency department because of fever, vomiting, and convulsive status epilepticus. He had no neurologic history or developmental delays. Mosquito and tick exposure history was substantial, although no engorged ticks were recently removed. The patient had not traveled outside of Ohio.

Results of a computed tomography scan of the head were unremarkable. We initiated intravenous vancomycin, ceftriaxone, and acyclovir. Magnetic resonance imaging showed left temporal pulvinar and thalamic T2-weighted fluid attenuated inversion recovery hyperintensity and restricted diffusion; an electroencephalogram showed lateralized periodic discharges. Cerebrospinal fluid (CSF) was collected by lumbar puncture, revealing a leukocyte count of 44 cells/μL (reference range <10 cells/μL) of which 85% were lymphocytes; glucose and protein levels were normal. The patient’s BIOFIRE FILMARRAY Meningitis/Encephalitis PCR panel (bioMérieux, https://www.biomerieux-diagnostics.com) was negative (Table). He was admitted to the pediatric intensive care unit, and seizures were controlled with anticonvulsants. Tests for infectious and noninfectious causes of meningitis and encephalitis were negative (Table). Antimicrobial drugs were discontinued after negative bacterial cultures were observed. Acyclovir was discontinued after PCR of CSF for herpes simplex virus was negative.

On hospitalization day 5, severe neurologic decline developed, and brain magnetic resonance imaging was repeated. New areas of T2 hyperintensity and restricted diffusion and thalamic microhemorrhages in a rhombencephalitis pattern were identified. Lumbar puncture was repeated, revealing considerable lymphocytic pleocytosis and elevated protein (156 mg/dL). Leading diagnoses were autoimmune encephalitis and acute necrotizing encephalopathy of childhood (ANEC). The patient exhibited severe encephalopathy, nystagmus, right hemiparesis, and diffuse hypertonia. He was treated with high dose methylprednisolone, plasmapheresis, and intravenous immunoglobulins.

Figure

Identification and phylogenetic analysis of Powassan virus found in cerebrospinal fluid of 4-year-old boy detected by metagenomic next-generation sequencing, Ohio, USA. A) Phylogenetic analysis of the 140-bp region in the Powassan virus genome corresponding to the single sequence read detected by metagenomic next-generation sequencing. Single read from the patient in this study was aligned with sequences from 23 representative Powassan virus genomes from lineage 1 (blue shaded box) and lineage 2 (deer tick virus lineage, pink shaded box) and 1 yellow fever virus sequence as an outgroup by using MAFFT v7.388 (Appendix reference 11 ). Phylogenetic tree was constructed by using the maximum-likelihood method and PhyML 3.0 software (Appendix reference 12); support values for the main branches are shown. Powassan virus from our patient (red asterisk) belongs to lineage 2. GenBank accession numbers are shown for each sequence. Scale bar indicates nucleotide substitutions per site. B) Powassan virus genome showing major capsid and nonstructural genes. Single sequence read from the patient mapped to the NS3 gene (arrow and red box). C) List of top 10 GenBank reference sequences matching the patient’s 140-nt read after using MegaBLAST (https://blast.ncbi.nlm.nih.gov) alignment as default setting, each showing 98.6% sequence identity. If Powassan virus sequences were excluded from the reference database, no other matches in GenBank were found. Cds, coding sequence; env, envelope protein; NS, nonstructural; pre, M protein precursor peptide.

Figure. Identification and phylogenetic analysis of Powassan virus found in cerebrospinal fluid of 4-year-old boy detected by metagenomic next-generation sequencing, Ohio, USA. A) Phylogenetic analysis of the 140-bp region in the...

Genetic testing for familial ANEC type 1 was negative. We sent CSF obtained on hospital day 5 to the University of California San Francisco for metagenomic next-generation sequencing (mNGS), which detected a single 140-nt POWV sequence (Appendix). We performed phylogenetic analysis of the sequence and assigned the patient’s virus to lineage 2 (Figure, panel A); the sequence mapped to the nonstructural NS3 gene (Figure, panel B). We performed BLAST (3) sequence alignments in GenBank, which yielded matches to POWV genomes (Figure, panel C). CSF samples obtained before the patient received intravenous Igs were sent for confirmatory testing to the CDC Arbovirus Diagnostic Laboratory, Division of Vector-Borne Diseases, National Center for Emerging and Zoonotic Infectious Diseases (https://www.cdc.gov/ncezid/dvbd/specimensub), which showed IgM against POWV (capture ELISA), negative POWV-specific PCR, and a positive plaque reduction neutralization test at 1:8 dilution (reference range <1:2), confirming the final diagnosis was ANEC caused by POWV. The patient continued having severe neurologic sequalae requiring a tracheostomy, gastrostomy tube, and inpatient rehabilitation. At follow-up 1 year after admission, he had been decannulated, was able to orally ingest liquids and solids, and ambulated independently, but he had substantial language and cognitive deficits.

Diagnostic yield for patients with encephalitis from any cause is 37% (4); mNGS enables detection of nearly all pathogens in a single assay and can improve diagnostic yield for patients with CNS infections (5). We identified 1 nucleotide sequence aligning to POWV, which is below the preestablished reporting threshold for a positive result of >3 reads spanning >3 regions of the viral genome (5). Thus, our finding was potentially a false positive, especially because POWV is not endemic to Ohio. However, POWV has never been a contaminant in clinical mNGS analyses of >4,000 CSF samples at the University of California San Francisco laboratory, and our result was confirmed as a true positive by a plaque reduction neutralization test. Of note, a case of POWV encephalitis identified by mNGS from 10 genomic sequencing reads has been reported (6). Furthermore, POWV-specific PCR of our patient’s CSF was negative, consistent with a low viral titer near the limit of detection by molecular assays. Patients with POWV encephalitis are often PCR negative because viremia precedes CNS disease development (7).

The number of POWV cases reported has increased over the past few decades (2), likely because of tick range expansion. Ixodes scapularis is the only tick species in northeastern Ohio that can transmit POWV (8). Tick range expansion might be caused by increasing temperatures from climate change (9), migration of animal hosts, and changes in land use or host populations (10). Ticks carrying POWV lineage 2 were not identified on the family’s property. However, healthcare and public health workers should be aware of changing epidemiology and potential emerging tickborne infections in nonendemic regions.

In conclusion, we identified a POWV infection in Ohio by using mNGS. Tests for autoimmune etiologies, familial ANEC (type 1), and other viral agents were negative, excluding alternative diagnoses. Our case highlights the ability of mNGS to identify rare or unexpected pathogens that cause encephalitis. Providers should recognize changing epidemiology of tickborne viruses, such as POWV, to enhance encephalitis diagnosis and management. When cases are identified, local public health departments should complete comprehensive entomological and epidemiologic studies to determine virus prevalence.

Dr. Farrington recently completed her pediatrics residency at the Children’s Hospital Medical Center of Akron in 2022. She is currently working as a pediatric hospitalist at the St. Louis Children’s Hospital–Washington University.

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References

  1. Kemenesi  G, Bányai  K. Tick-borne flaviviruses, with a focus on Powassan virus. Clin Microbiol Rev. 2018;32:e0010617. DOIPubMedGoogle Scholar
  2. Centers for Disease Control and Prevention. Powassan virus [cited 2022 May 3]. https://www.cdc.gov/powassan/statistics.html
  3. Altschul  SF, Gish  W, Miller  W, Myers  EW, Lipman  DJ. Basic local alignment search tool. J Mol Biol. 1990;215:40310. DOIPubMedGoogle Scholar
  4. Glaser  CA, Honarmand  S, Anderson  LJ, Schnurr  DP, Forghani  B, Cossen  CK, et al. Beyond viruses: clinical profiles and etiologies associated with encephalitis. Clin Infect Dis. 2006;43:156577. DOIPubMedGoogle Scholar
  5. Miller  S, Naccache  SN, Samayoa  E, Messacar  K, Arevalo  S, Federman  S, et al. Laboratory validation of a clinical metagenomic sequencing assay for pathogen detection in cerebrospinal fluid. Genome Res. 2019;29:83142. DOIPubMedGoogle Scholar
  6. Piantadosi  A, Kanjilal  S, Ganesh  V, Khanna  A, Hyle  EP, Rosand  J, et al. Rapid detection of Powassan virus in a patient with encephalitis by metagenomic sequencing. Clin Infect Dis. 2018;66:78992. DOIPubMedGoogle Scholar
  7. Hermance  ME, Thangamani  S. Powassan virus: an emerging arbovirus of public health concern in North America. Vector Borne Zoonotic Dis. 2017;17:45362. DOIPubMedGoogle Scholar
  8. Eisen  RJ, Eisen  L, Beard  CB. County-scale distribution of Ixodes scapularis and Ixodes pacificus (Acari: Ixodidae) in the continental United States. J Med Entomol. 2016;53:34986. DOIPubMedGoogle Scholar
  9. Bouchard  C, Dibernardo  A, Koffi  J, Wood  H, Leighton  PA, Lindsay  LR. N Increased risk of tick-borne diseases with climate and environmental changes. Can Commun Dis Rep. 2019;45:839. DOIPubMedGoogle Scholar
  10. Diuk-Wasser  MA, VanAcker  MC, Fernandez  MP. Impact of land use changes and habitat fragmentation on the eco-epidemiology of tick-borne diseases. J Med Entomol. 2021;58:154664. DOIPubMedGoogle Scholar

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Cite This Article

DOI: 10.3201/eid2904.221005

Original Publication Date: March 16, 2023

1Current affiliation: St. Louis Children’s Hospital, St. Louis, Missouri, USA.

Table of Contents – Volume 29, Number 4—April 2023

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Scott F Pangonis, Children’s Medical Center of Akron, 1 Perkins Sq, Akron, OH 44321, USA

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Page created: January 28, 2023
Page updated: March 21, 2023
Page reviewed: March 21, 2023
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