Rapid Field Immunoassay for Detecting Antibody to Sin Nombre Virus in Deer Mice

We developed a 1-hour field enzyme immunoassay (EIA) for detecting antibody to Sin Nombre virus in deer mice (Peromyscus maniculatus). The assay specificity and sensitivity were comparable to those of a standard EIA. This test will permit identification of rodents with antibody to this and perhaps other hantaviruses

PUBLIC HEALTH Assessment of Ecologic and Biologic Factors Leading to Hantavirus Pulmonary Syndrome, Colorado, U.S.A

Aim. To understand the ecologic parameters of Sin Nombre virus (SNV; family Bunyaviridae, genus Hantavirus) infections in the deer mouse (Peromyscus maniculatus), environmental variables impacting the rodent populations, and the conditions under which SNV is amplified. This may help us understand the antecedents of human risk for developing hantavirus pulmonary syndrome (HPS) as a consequence of SNV infection. Method. Each 6 weeks, we trapped, measured, tagged, bled, and released rodents at three widely spaced sites in Colorado, USA: Fort Lewis (1994Lewis ( -2001, Molina (1994Molina ( -2001, and Pinyon Canyon Maneuver Site (1995)(1996)(1997)(1998)(1999)(2000)(2001). The ELISA method was used to test rodent blood samples for IgG antibody to SNV antigen. Results. Where rodent species richness was high, the prevalence of infection of deer mice (as determined by the presence of antibody) with SNV was low, and vice versa. There was a higher prevalence of antibody to SNV in male than in female rodents, and seasonal differences were observed in acquisition of SNV between male and female deer mice. Long-lived infected deer mice served as transseasonal, over-winter reservoirs for the virus, providing the mechanism for its survival. Conclusion. Prevalence of rodent infection appears to be associated with fluctuations in deer mouse populations and, indirectly, with timing and amount of precipitation and the resulting biologic events (a "trophic cascade"). Together with information regarding transseasonal maintenance of SNV, seasonal differences in acquisition of SNV between sexes, group foraging, and various other factors may expand our understanding of the risk factors for acquiring HPS. Taken together and applied, we anticipate developing methods for preventing this disease as well as diseases caused by other rodent-borne viruses

Natural history of Sin Nombre virus in western Colorado.

A mark-recapture longitudinal study of immunoglobulin G (IgG) antibody to Sin Nombre virus (SNV) in rodent populations in western Colorado (1994-results summarized to October 1997) indicates the presence of SNV or a closely related hantavirus at two sites. Most rodents (principally deer mice, Peromyscus maniculatus, and pinyon mice, P. truei) did not persist on the trapping webs much beyond 1 month after first capture. Some persisted more than 1 year, which suggests that even a few infected deer mice could serve as transseasonal reservoirs and mechanisms for over-winter virus maintenance. A positive association between wounds and SNV antibody in adult animals at both sites suggests that when infected rodents in certain populations fight with uninfected rodents, virus amplification occurs. At both sites, male rodents comprised a larger percentage of seropositive mice than recaptured mice, which suggests that male mice contribute more to the SNV epizootic cycle than female mice. In deer mice, IgG antibody prevalence fluctuations were positively associated with population fluctuations. The rates of seroconversion, which in deer mice at both sites occurred mostly during late summer and midwinter, were higher than the seroprevalence, which suggests that the longer deer mice live, the greater the probability they will become infected with SNV

Population Dynamics Of A Diverse Rodent Assemblage In Mixed Grass-Shrub Habitat, Southeastern Colorado, 1995–2000

We followed seasonal and year-to-year population dynamics for a diverse rodent assemblage in a short-grass prairie ecosystem in southeastern Colorado (USA) for 6 yr. We captured 2,798 individual rodents (range, one to 812 individuals per species) belonging to 19 species. The two most common species, deer mice (Peromyscus maniculatus) and western harvest mice (Reithrodontomys megalotis), generally had population peaks in winter and nadirs in summer; several other murid species demonstrated autumn peaks and spring nadirs; heteromyids were infrequently captured in winter, and populations generally peaked in summer or autumn. Interannual trends indicated an interactive effect between temperature and precipitation. Conditions associated with low rodent populations or population declines were high precipitation during cold periods (autumn and winter) and low precipitation during warm periods (spring and summer). Severity of adverse effects varied by species. Heteromyids, for example, were apparently not negatively affected by the hot, dry spring and summer of 2000. Cross-correlations for the temporal series of relative population abundances between species pairs (which are affected by both seasonal and interannual population dynamics) revealed positive associations among most murids and among most heteromyids, but there were negative associations between murids and heteromyids. These results have important implications for those attempting to model population dynamics of rodent populations for purposes of predicting disease risk