Emerging Infectious Diseases
[Volume 5 No.1 / January - February 1999]

Suggested Citation

Commentary

A Midcourse Assessment of Hantavirus Pulmonary Syndrome

Robert E. Shope
University of Texas Medical Branch, Galveston, Texas, USA

------------------------------------------------------------------------

Our understanding of infectious diseases follows a natural course—the
initial discovery of the cause, the exploration of the natural history and
biology of the etiologic agent, and finally the cure or solution. The
discovery of Sin Nombre virus (SNV), one of the viruses causing hantavirus
pulmonary syndrome (HPS), is unparalleled in terms of the rapid progress of
the scientific investigation leading to its description. A cluster of cases
of fatal adult respiratory syndrome was recognized in the Four Corners
region of the United States in May 1993, and within a few days serologic
evidence confirmed hantavirus infection (1). The outbreak occurred in the
wake of the Institute of Medicine's report Emerging Infections: Microbial
Threats to Health in the United States, in which acute respiratory disease
was first on the list of clinical syndromes requiring high-priority
surveillance (2).

The scientific community has now entered the midcourse phase of HPS
research, including the exploration of the natural history of the American
hantaviruses. Seven articles in this issue describe studies of rodent
reservoirs of Sin Nombre and related viruses. They illustrate the
multidisciplinary nature of such studies, which require ecologic methods,
in addition to the newer molecular biology techniques that have helped
hantavirologists detect and characterize the viruses.

These and other studies have elucidated much about the natural host
relationships of hantaviruses. Multiple hantavirus genotypes exist in
virtually all parts of North and South America; each hantavirus genotype
has a single rodent species as its principal reservoir. Evidence exists
that the virus and rodent have evolved together. Each hantavirus variant is
focal in distribution. Prevalence of antibody is high in some regions, and
low or absent in others, even when the same species of rodent is found in
both places. Rodents are not infected at birth; they acquire the virus from
other rodents. Once infected, the animals develop antibody, but many, or
maybe all, infected rodents remain infected. Because of rapid turnover of
the rodent population (as older antibody-carrying animals die and nonimmune
animals are born), antibody prevalence can vary greatly, from 0% to 50%,
with prevalence often lower than 20%.

The studies also have raised new questions. Why and by what route are
animals infected? The articles in this issue suggest that contamination of
wounds when animals fight may be an important route of infection, while
allowing for the possibility of secondary mechanisms, such as venereal
transmission or close association during communal nesting. Although
textbooks state that people become infected by inhaling aerosols created by
the rodents, we need better information. If the animals create infectious
aerosols, why are only a small proportion of susceptible animals infected,
even in enclosed colonies of the rodents (3)? Why is human infection so
rare, even among forest workers and mammalogists (4)? Are some animals
supersecretors of virus? Are individual virus-carrying rodents infectious
for life or only periodically? If periodically, what makes them shed and
stop shedding virus?

Classic pathogenesis studies are required to answer these questions. Two
technologic advances—reverse transcription-polymerase chain reaction
(RT-PCR) and enzyme-linked immunosorbent assay (ELISA)—have revolutionized
science but at the same time lured us away from other time-tested methods.
Before the RT-PCR technique was developed, virologists measured infectious
virus by isolating it in cell cultures or laboratory animals. Although we
need information about the infectivity of rodent blood, urine, throat
secretions, feces, and organs, few investigators attempt to isolate
infectious hantaviruses. The reasons are obvious. Virus isolation is
tedious, technically difficult, and (without biosafety level three or four
facilities) dangerous. Because detecting nucleic acid by RT-PCR is safe and
easily accomplished, most investigators are satisfied with that method.
Safe isolation of hantaviruses in the Americas will require additional
investment in physical biocontainment facilities for university and
government laboratories.

Many compelling reasons exist for isolating hantaviruses. How else will
serotype specificity, animal models, pathogenic potential, replication,
transmission, and other phenotypic properties be studied? I cannot
emphasize too strongly the importance of propagating and preserving this
biologic material. To isolate hantaviruses from rodent tissues will require
new approaches. The technical difficulty now in isolating hantaviruses is
analogous to that encountered 30 years ago with dengue viruses. The
solution for dengue was to use a natural host, the mosquito (5). Colonized,
virus-free rodent reservoir hosts of hantaviruses could possibly provide
the increased sensitivity to infection needed to facilitate routine
isolation of hantaviruses. This approach has been successful on a limited
scale in Europe (6).

Only two serologic methods—ELISA and, to a lesser extent,
immunofluorescence assay—are used on a large scale in the Americas for
testing rodent sera for hantavirus antibody. CDC developed a recombinant
antigen product of the small RNA segment of SNV (7), which was produced in
large quantity and distributed gratis to state health departments and to
collaborators in both North and South America for use in ELISA. The antigen
is broadly cross-reactive and entirely safe. Before the advent of ELISA,
classic virologists surveyed for antibody with one test and then confirmed
a portion of the antibody-positive and -negative serum specimens with a
different test, often the neutralization test. Such confirmatory tests are
desirable in the studies of rodents for hantavirus antibody but are rarely
done. The neutralization test, used to a limited extent (8), is not
practical for study of large numbers of rodent serum specimens or for work
with biosafety level four agents. An alternate to this test is the
hemagglutination-inhibition test. Asian and European hantaviruses
agglutinate goose cells (9,10); it should be feasible, therefore, to
develop the hemagglutination-inhibition test for American hantaviruses.

What will it take to cure or prevent HPS? The only proposed antihantavirus
drug is ribavirin, which although still under trial, has not been
efficacious in treating HPS (11). Supportive emergency care can save lives,
but diagnosis must be made early, clinical expertise is concentrated in
only a few medical centers, and HPS cases are often dispersed. Approaches
to hantavirus human vaccines have been developed (12), but such vaccines
are probably not commercially feasible in the Americas, which have a low
incidence of disease caused by focal genotypes. Rodent control does not
seem practical because of the immense geographic range of hantaviruses.
Ongoing rodent studies may eventually determine whether a wildlife vaccine
analogous to that used successfully for rabies will be practical (13).

For the immediate future, we must depend on education to prevent human
exposure. To design an effective education program, we must know much more
about the rodent reservoir and the mode of virus transmission, both among
rodents and to people. The publication of these ecologic studies in a
medical journal represents important changes in the medical and ecologic
sciences. These studies have required collaboration of ecologists,
epidemiologists, and virologists. Their successful continuation, as well as
the conception, design, and conduct of future studies, requires the spirit
of innovation best achieved in a multidisciplinary atmosphere, as well as a
long-term commitment to collect data for several years.

References

  1. Nichol ST, Spiropoulou CF, Morzunov S, Rollin PE, Ksiazek TG, Feldmann
     H, et al. Genetic identification of a hantavirus associated with an
     outbreak of acute respiratory illness. Science 1993;262:914-7.
  2. Lederberg J, Shope RE, Oaks SC. Emerging infections: microbial threats
     to health in the United States. Washington: National Academy Press;
     1992. p. 136.
  3. Otteson EW, Riolo J, Rowe JE, Nichol ST, Ksiazek TG, Rollin PE, et al.
     Occurrence of hantavirus within the rodent population of northeastern
     California and Nevada. Am J Trop Med Hyg 1996;54:127-33.
  4. Vitek CR, Ksiazek TG, Peters CJ, Breiman RF. Evidence against
     infection with hantaviruses among forest and park workers in the
     southwestern United States. Clin Infect Dis 1996;23:283-5.
  5. Rosen L, Gubler D. The use of mosquitoes to detect and propagate
     dengue viruses. Am J Trop Med Hyg 1974;23:1153-60.
  6. Vapalahti O, Lundkvist A, Kukkonen SK, Cheng Y, Gilljam M, Kanerva M,
     et al. Isolation and characterization of Tula virus, a distinct
     serotype in the genus Hantavirus, family Bunyaviridae. J Gen Virol
     1996;77:3063-7.
  7. Feldmann H, Sanchez A, Morzunov S, Spiropoulou C, Rollin PE, Ksiazek
     TG, et al. Utilization of autopsy tissue RNA for the synthesis of the
     nucleocapsid antigen of a newly recognized virus associated with
     hantavirus pulmonary syndrome. Virus Res 1993;30:351-67.
  8. Chu Y-K, Jennings G, Schmaljohn A, Elgh F, Hjelle B, Lee HW, et al.
     Cross neutralization of hantaviruses with immune sera from
     experimentally infected animals and from hemorrhagic fever with renal
     syndrome and hantavirus pulmonary syndrome patients. J Infect Dis
     1995;172:1581-4.
  9. Tsai TF, Tang YW, Hu SL, Ye KL, Chen GL, Xu ZY.
     Hemagglutination-inhibiting antibody in hemorrhagic fever with renal
     syndrome. J Infect Dis 1984;150:895-8.
 10. Brummer-Korvenkontio M, Manni T, Ukkonen S, Vaheri A. Detection of
     hemagglutination-inhibiting antibodies in patients with nephropathia
     epidemica and Korean hemorrhagic fever by using Puumala virus cell
     culture antigen. J Infect Dis 1986;997-8.
 11. Mertz GJ, Hjelle BL, Bryan RT. Hantavirus infection. Adv Intern Med
     1997;42:369-421.
 12. Chu YK, Jennings GB, Schmaljohn CS. A vaccinia virus-vectored Hantaan
     virus vaccine protects hamsters from challenge with Hantaan and Seoul
     viruses but not Puumala virus. J Virol 1995;69:6417-23.
 13. Wandeler AI. Oral immunization of wildlife. In: Baer GM, editor. The
     Natural History of Rabies. Boca Raton (FL): CRC Press; 1991. p.
     485-503.

Emerging Infectious Diseases
National Center for Infectious Diseases
Centers for Disease Control and Prevention
Atlanta, GA

URL: ftp://ftp.cdc.gov/pub/EID/vol5no1/ascii/shope.txt

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