Linda M. Styer

Mosquitoes inoculate high doses of West Nile virus as they probe and feed on live hosts.

West Nile virus (WNV) is transmitted to vertebrate hosts by mosquitoes as they take a blood meal. The amount of WNV inoculated by mosquitoes as they feed on a live host is not known. Previous estimates of the amount of WNV inoculated by mosquitoes (101.2–104.3 PFU) were based on in vitro assays that do not allow mosquitoes to probe or feed naturally. Here, we developed an in vivo assay to determine the amount of WNV inoculated by mosquitoes as they probe and feed on peripheral tissues of a mouse or chick. Using our assay, we recovered approximately one-third of a known amount of virus inoculated into mouse tissues. Accounting for unrecovered virus, mean and median doses of WNV inoculated by four mosquito species were 104.3 PFU and 105.0 PFU for Culex tarsalis, 105.9 PFU and 106.1 PFU for Cx. pipiens, 104.7 PFU and 104.7 PFU for Aedes japonicus, and 103.6 PFU and 103.4 PFU for Ae. triseriatus. In a direct comparison, in vivo estimates of the viral dose inoculated by Cx. tarsalis were approximately 600 times greater than estimates obtained by an in vitro capillary tube transmission assay. Virus did not disperse rapidly, as >99% of the virus was recovered from the section fed or probed upon by the mosquito. Furthermore, 76% (22/29) of mosquitoes inoculated a small amount of virus (∼102 PFU) directly into the blood while feeding. Direct introduction of virus into the blood may alter viral tropism, lead to earlier development of viremia, and cause low rates of infection in co-feeding mosquitoes. Our data demonstrate that mosquitoes inoculate high doses of WNV extravascularly and low doses intravascularly while probing and feeding on a live host. Accurate estimates of the viral dose inoculated by mosquitoes are critical in order to administer appropriate inoculation doses to animals in vaccine, host competence, and pathogenesis studies.

Modelling adult Aedes aegypti and Aedes albopictus survival at different temperatures in laboratory and field settings

BackgroundThe survival of adult female Aedes mosquitoes is a critical component of their ability to transmit pathogens such as dengue viruses. One of the principal determinants of Aedes survival is temperature, which has been associated with seasonal changes in Aedes populations and limits their geographical distribution. The effects of temperature and other sources of mortality have been studied in the field, often via mark-release-recapture experiments, and under controlled conditions in the laboratory. Survival results differ and reconciling predictions between the two settings has been hindered by variable measurements from different experimental protocols, lack of precision in measuring survival of free-ranging mosquitoes, and uncertainty about the role of age-dependent mortality in the field.MethodsHere we apply generalised additive models to data from 351 published adult Ae. aegypti and Ae. albopictus survival experiments in the laboratory to create survival models for each species across their range of viable temperatures. These models are then adjusted to estimate survival at different temperatures in the field using data from 59 Ae. aegypti and Ae. albopictus field survivorship experiments. The uncertainty at each stage of the modelling process is propagated through to provide confidence intervals around our predictions.ResultsOur results indicate that adult Ae. albopictus has higher survival than Ae. aegypti in the laboratory and field, however, Ae. aegypti can tolerate a wider range of temperatures. A full breakdown of survival by age and temperature is given for both species. The differences between laboratory and field models also give insight into the relative contributions to mortality from temperature, other environmental factors, and senescence and over what ranges these factors can be important.ConclusionsOur results support the importance of producing site-specific mosquito survival estimates. By including fluctuating temperature regimes, our models provide insight into seasonal patterns of Ae. aegypti and Ae. albopictus population dynamics that may be relevant to seasonal changes in dengue virus transmission. Our models can be integrated with Aedes and dengue modelling efforts to guide and evaluate vector control, better map the distribution of disease and produce early warning systems for dengue epidemics.

Mosquito Saliva Causes Enhancement of West Nile Virus Infection in Mice

ABSTRACT West Nile virus (WNV) is transmitted to vertebrate hosts primarily by infected Culex mosquitoes. Transmission of arboviruses by the bite of infected mosquitoes can potentiate infection in hosts compared to viral infection by needle inoculation. Here we examined the effect of mosquito transmission on WNV infection and systematically investigated multiple factors that differ between mosquito infection and needle inoculation of WNV. We found that mice infected with WNV through the bite of a single infected Culex tarsalis mosquito exhibited 5- to 10-fold-higher viremia and tissue titers at 24 and 48 h postinoculation and faster neuroinvasion than mice given a median mosquito-inoculated dose of WNV (105 PFU) by needle. Mosquito-induced enhancement was not due to differences in inoculation location, because additional intravenous inoculation of WNV did not enhance viremia or tissue titers. Inoculation of WNV into a location where uninfected mosquitoes had fed resulted in enhanced viremia and tissue titers in mice similar to those in mice infected by a single infected mosquito bite, suggesting that differences in where virus is deposited in the skin and in the virus particle itself were not responsible for the enhanced early infection in mosquito-infected mice. In addition, inoculation of mice with WNV mixed with salivary gland extract (SGE) led to higher viremia, demonstrating that mosquito saliva is the major cause of mosquito-induced enhancement. Enhanced viremia was not observed when SGE was inoculated at a distal site, suggesting that SGE enhances WNV replication by exerting a local effect. Furthermore, enhancement of WNV infection still occurred in mice with antibodies against mosquito saliva. In conclusion, saliva from C. tarsalis is responsible for enhancement of early WNV infection in vertebrate hosts.

West Nile Virus Infection Decreases Fecundity of Culex tarsalis Females

Abstract West Nile virus (family Flaviviridae, genus Flavivirus, WNV) persistently infects many mosquito tissues, and it has been associated with cytopathological changes in midgut muscles and salivary glands. However, the effects of WNV infection on mosquito fitness (survival and reproduction) are not known. We conducted a life table study of individually housed female Culex tarsalis Coquillett. After an initial bloodmeal from a WNV-infected or uninfected chicken, mosquitoes were provided sucrose and offered weekly opportunities to feed on a hanging blood drop. WNV transmission status was determined by testing the remaining blood drop for virus after mosquito feeding. Dead mosquitoes and eggs were collected daily. Mosquito legs and bodies were tested for WNV, and eggs were counted and allowed to hatch. Two replicates of this experiment were performed, with a total of 62 mosquitoes that fed on a WNV-infected chicken (of which 21 became infected) and 43 mosquitoes that fed on an uninfected chicken. Fecundity of WNV-infected mosquitoes was significantly lower than that of uninfected mosquitoes, especially during the first oviposition. WNV infection was associated with smaller egg rafts, whereas increasing wing length and WNV titer in the legs had a positive effect on egg raft size. Additionally, infected mosquitoes had lower egg hatch rates than did uninfected mosquitoes. There were no significant differences in survival between infected and uninfected mosquitoes. Blood feeding rates were higher in infected mosquitoes than in uninfected mosquitoes. A small amount of virus (average, 378; range, 5–5,000 plaque-forming units) was transmitted to the blood drops fed upon by infected mosquitoes. Although WNV infection negatively impacts mosquito reproduction, facets of mosquito biology that are critical to virus transmission success were either not affected (survival) or changed in such a way as to result in enhanced vectorial capacity (blood feeding).

The costs of infection and resistance as determinants of West Nile virus susceptibility in Culex mosquitoes

BackgroundUnderstanding the phenotypic consequences of interactions between arthropod-borne viruses (arboviruses) and their mosquito hosts has direct implications for predicting the evolution of these relationships and the potential for changes in epidemiological patterns. Although arboviruses are generally not highly pathogenic to mosquitoes, pathology has at times been noted. Here, in order to evaluate the potential costs of West Nile virus (WNV) infection and resistance in a primary WNV vector, and to assess the extent to which virus-vector relationships are species-specific, we performed fitness studies with and without WNV exposure using a highly susceptible Culex pipiens mosquito colony. Specifically, we measured and compared survival, fecundity, and feeding rates in bloodfed mosquitoes that were (i) infected following WNV exposure (susceptible), (ii) uninfected following WNV exposure (resistant), or (iii) unexposed.ResultsIn contrast to our previous findings with a relatively resistant Cx. tarsalis colony, WNV infection did not alter fecundity or blood-feeding behaviour of Cx. pipiens, yet results do indicate that resistance to infection is associated with a fitness cost in terms of mosquito survival.ConclusionsThe identification of species-specific differences provides an evolutionary explanation for variability in vector susceptibility to arboviruses and suggests that understanding the costs of infection and resistance are important factors in determining the potential competence of vector populations for arboviruses.

Viral pathogenesis in mice is similar for West Nile virus derived from mosquito and mammalian cells.

West Nile virus (WNV) is a mosquito-borne pathogen. During replication, WNV acquires different carbohydrates and lipid membranes, depending on its mosquito or vertebrate hosts. Consequently, WNV derived from mosquito and vertebrate cell lines differ in their infectivity for dendritic cells (DCs) and induction of type I interferon (IFN-alpha/beta) in vitro. We evaluated the pathogenesis of WNV derived from mosquito (WNV(C6/36)) and vertebrate (WNV(BHK)) cell lines in mice. The tissue tropism, infectivity, clinical disease, and mortality did not differ for mice inoculated with WNV(C6/36) or WNV(BHK), and there were only minor differences in viral load and serum levels of IFN-alpha/beta. The replication kinetics of WNV(C6/36) and WNV(BHK) were equivalent in primary DCs and skin cells although primary DCs were more susceptible to WNV(C6/36) infection than to WNV(BHK) infection, suggesting that less virus is produced per infected cell for WNV(C6/36). In conclusion, viral source has minimal effect on WNV pathogenesis in vivo.

Validation and clinical use of a sensitive HIV-2 viral load assay that uses a whole virus internal control.

BACKGROUND Human immunodeficiency virus type 2 (HIV-2) is distantly related to the more widespread HIV-1. Although HIV-2 infection is rare in the U.S., cases are concentrated in the Northeast. No FDA-approved HIV-2 viral load assays exist. A clinically validated laboratory-developed assay is currently available in the U.S., however it is not currently approved for use on New York State patients. OBJECTIVE To develop a sensitive viral load assay to quantify HIV-2 RNA in plasma and to validate it for clinical use. METHODS The real-time RT-PCR assay simultaneously amplifies HIV-2 and a whole virus internal control, added during the lysis step. Two extraction volumes can be used. Results are reported in HIV-2 RNA International Units (IU). RESULTS The assay has a limit of detection of 7 IU/mL and a lower limit of quantification of 29 IU/mL. The assay detects multiple strains of HIV-2 group A and B and generates reproducible results. Samples exchanged with a comparator laboratory produced similar viral load results, with 74% of positives differing by <0.5 log10 IU/mL. To date, we have tested 52 clinical specimens from 25 individuals. Twenty-eight (54%) specimens had measurable HIV-2 viral loads (range: 1.63-5.14 log10 IU/mL), 10 (19%) were positive but not quantifiable, and 14 were negative. HIV-2 RNA was detected in at least one specimen from 19 of 25 (76%) individuals tested. CONCLUSIONS We developed a sensitive and accurate HIV-2 viral load assay. Validation data indicate the assay is suitable for clinical use and its availability in New York State will improve clinical monitoring of HIV-2 infected patients.

Parameters of Mosquito-Enhanced West Nile Virus Infection

ABSTRACT The arthropod-borne West Nile virus (WNV) emerged in New York State in 1999 and quickly spread throughout the United States. Transmission is maintained in an enzootic cycle in which infected mosquitoes transmit the virus to susceptible hosts during probing and feeding. Arthropod-derived components within the viral inoculum are increasingly acknowledged to play a role in infection of vertebrate hosts. We previously showed that Culex tarsalis mosquito saliva and salivary gland extract (SGE) enhance the in vivo replication of WNV. Here, we characterized the effective dose, timing, and proximity of saliva and SGE administration necessary for enhancement of WNV viremia using a mouse model. Mosquito saliva and SGE enhanced viremia in a dose-dependent manner, and a single mosquito bite or as little as 0.01 μg of SGE was effective at enhancing viremia, suggesting a potent active salivary factor. Viremia was enhanced when SGE was injected in the same location as virus inoculation from 24 h before virus inoculation through 12 h after virus inoculation. These results were confirmed with mosquito saliva deposited by uninfected mosquitoes. When salivary treatment and virus inoculation were spatially separated, viremia was not enhanced. In summary, the effects of mosquito saliva and SGE were potent, long lasting, and localized, and these studies have implications for virus transmission in nature, where vertebrate hosts are fed upon by both infected and uninfected mosquitoes over time. Furthermore, our model provides a robust system to identify the salivary factor(s) responsible for enhancement of WNV replication. IMPORTANCE Mosquito-borne viruses are a significant class of agents causing emerging infectious diseases. WNV has caused over 18,000 cases of neuroinvasive disease in the United States since its emergence. We have shown that Culex tarsalis mosquito saliva and SGE enhance the replication of WNV. We now demonstrate that saliva and SGE have potent, long-lasting, and localized effects. Our model provides a robust system to identify the salivary factor(s) and characterize the mechanism responsible for enhancement of WNV replication. These studies could lead to the identification of novel prophylactic or treatment options useful in limiting the spread of WNV, other mosquito-borne viruses, and the diseases that they cause.

Two human immunodeficiency virus Type 2 cases in US blood donors including serologic, molecular, and genomic characterization of an epidemiologically unusual case.

Blood donation screening for human immunodeficiency virus Type 2 (HIV‐2) has been in place in the United States since 1992. However, only three HIV‐2 antibody–positive donors have been reported to date, all detected via HIV‐1 cross‐reactivity.

Expansion of HIV screening to non-clinical venues is aided by the use of dried blood spots for Western blot confirmation

BACKGROUND HIV rapid testing programs in New York State (NYS) are required to collect a specimen for confirmation of a preliminary positive result; however, some venues have limited capacity to collect venous blood, and confirmation using oral fluid is restricted by cost and availability. OBJECTIVE To evaluate the feasibility of using dried blood spots (DBS) at non-clinical HIV rapid testing sites for Western blot testing. STUDY DESIGN The New York State Department of Health facilitated registration of 48 non-clinical HIV test sites and provided training on DBS procedures. Following a reactive rapid test, DBS were collected by fingerstick onto filter paper cards, dried and mailed to the NYS public health laboratory for Western blot testing. RESULTS From October 2010 to December 2012, 280 DBS specimens were submitted for confirmation. Four (1.4%) were unsatisfactory for testing and 276 (98.6%) DBS were tested. Of these, 235 (85.1%) were positive, 37 (13.4%) were negative and 4 (1.4%) were indeterminate. During this period, the laboratory also received 1033 venous blood specimens for rapid test confirmation, and 35 (3.4%) were unsatisfactory. Of the 998 tested by Western blot, 784 (78.6%) were positive, 197 (19.7%) were negative and 17 (1.7%) were indeterminate. DISCUSSION Compared to venous blood, the percentage of rapid test referral specimens with a positive Western blot was significantly greater for DBS specimens and the frequency of unsatisfactory specimens did not differ significantly. These results indicate that DBS are a suitable alternative to venous blood for confirmation of HIV rapid tests conducted at non-clinical sites.