Identification of avian malaria (Plasmodium sp.) and canine heartworm (Dirofilaria immitis) in the mosquitoes of Tennessee.

Plasmodium reticulum, the causative agent for avian malaria (a protozoan), and Dirofilaria immitis, the causative agent for canine heartworm (a filarial nematode), are 2 obligate parasites transmitted by mosquitoes. The objective of this project was to identify whether either parasite was present in Tennessee mosquitoes and to illustrate the need for collecting spatial and temporal vector-parasite data. During 2012, mosquitoes were collected from the East Tennessee Research and Education Center (ETREC) in eastern Tennessee and the Ames Plantation Research and Education Center (AMES) in western Tennessee using CO(2) traps and gravid traps. Once mosquitoes were identified to species, their heads and thoraces were pooled in groups of ≤10, and the entire pool underwent DNA extraction and parasite amplification via polymerase chain reaction (PCR) for Plasmodium and Haemoproteus parasite DNA (cytochrome b) and for Dirofilaria species DNA (internal transcribed spacer-2 ribosomal DNA). All positive PCR amplicons were bidirectionally sequenced to confirm positivity and to identify the potential parasite genotype. This approach resulted in 762 mosquito pools, 150 pools from AMES and 612 pools from ETREC. In total, 3,260 mosquitoes were collected, representing 28 mosquito species. The 3 abundant genera were Culex (2,440 specimens, 74.8%), Aedes (720, 22.1%), and Anopheles (85, 2.6%). The remaining specimens included 13 Psorophora, 1 Orthopodomyia signiferia, and 1 Coquillettidia perturbans. Of the 150 pools from AMES, 1 pool (0.7%) was positive for avian malaria and 12 pools (8.0%) were positive for canine heartworm. Of the 612 pools from ETREC, 61 pools (10.0%) were positive for avian malaria and 8 pools (1.3%) were positive for canine heartworm. Positive pools for both Plasmodium and Dirofilaria were primarily Culex pipiens and occurred later in the season. The confirmation of the agents for avian malaria and canine heartworm illustrates the need for concurrent spatial and temporal studies using different trapping methods. The confirmation of avian malaria and canine heartworm in Tennessee illustrates the need for concurrent spatial and temporal studies. Future studies incriminating the potential vector populations will begin to unravel the complex relationships that intimately tie together hosts, vectors, and parasites. Results provide a significant contribution to the knowledge of the diversity of mosquito parasites present in Tennessee, and the presence of positive field populations warrants additional research exploring the environmental factors contributing to transmission.

The knockdown resistance mutation and knockdown time in Anopheles gambiae collected from Mali evaluated through a bottle bioassay and a novel insecticide-treated net bioassay.

Successful malaria management in Mali includes the use of pyrethroids and insecticide-treated nets (ITNs) for mosquito control; however, management is threatened by the spread of insecticide resistance detected via the knockdown resistance (kdr) allele. In a preliminary study, we compared the knockdown times of Anopheles gambiae from Mali using a novel ITN bioassay and the World Health Organization (WHO) bottle bioassay. Additionally, the frequency and relationship between kdr genotypes, molecular forms, and pyrethroid resistance were analyzed. The S molecular form was predominant and accounted for 76% of the assayed population. Both kdr resistant alleles, West Africa resistant (kdr-w) and East Africa resistant (kdr-e), were observed. There was no significant difference in knockdown time based on kdr genotype or molecular form of individual mosquitoes, but mosquitoes in the ITN bioassay homozygous for the kdr-w allele were knocked down significantly faster than those in the WHO bottle bioassay. The ITN bioassay provides an additional indicator of insecticide efficacy because ITNs, frequently used within homes, are the most common form of vector control and malaria prevention, and the ITN bioassays can evaluate seasonal field effects.

Survey of Borreliae in ticks, canines, and white-tailed deer from Arkansas, U.S.A.

BACKGROUND: In the Eastern and Upper Midwestern regions of North America, Ixodes scapularis (L.) is the most abundant tick species encountered by humans and the primary vector of B. burgdorferi, whereas in the southeastern region Amblyomma americanum (Say) is the most abundant tick species encountered by humans but cannot transmit B. burgdorferi. Surveys of Borreliae in ticks have been conducted in the southeastern United States and often these surveys identify B. lonestari as the primary Borrelia species, surveys have not included Arkansas ticks, canines, or white-tailed deer and B. lonestari is not considered pathogenic. The objective of this study was to identify Borrelia species within Arkansas by screening ticks (n=2123), canines (n=173), and white-tailed deer (n=228) to determine the identity and locations of Borreliae endemic to Arkansas using PCR amplification of the flagellin (flaB) gene. METHODS: Field collected ticks from canines and from hunter-killed white-tailed were identified to species and life stage. After which, ticks and their hosts were screened for the presence of Borrelia using PCR to amplify the flaB gene. A subset of the positive samples was confirmed with bidirectional sequencing. RESULTS: In total 53 (21.2%) white-tailed deer, ten (6%) canines, and 583 (27.5%) Ixodid ticks (252 Ixodes scapularis, 161 A. americanum, 88 Rhipicephalus sanguineus, 50 Amblyomma maculatum, 19 Dermacentor variabilis, and 13 unidentified Amblyomma species) produced a Borrelia flaB amplicon. Of the positive ticks, 324 (22.7%) were collected from canines (151 A. americanum, 78 R. sanguineus, 43 I. scapularis, 26 A. maculatum, 18 D. variabilis, and 8 Amblyomma species) and 259 (37.2%) were collected from white-tailed deer (209 I. scapularis, 24 A. maculatum, 10 A. americanum, 10 R. sanguineus, 1 D. variabilis, and 5 Amblyomma species). None of the larvae were PCR positive. A majority of the flaB amplicons were homologous with B. lonestari sequences: 281 of the 296 sequenced ticks, 3 canines, and 27 deer. Only 22 deer, 7 canines, and 15 tick flaB amplicons (12 I. scapularis, 2 A. maculatum, and 1 Amblyomma species) were homologous with B. burgdorferi sequences. CONCLUSIONS: Data from this study identified multiple Borreliae genotypes in Arkansas ticks, canines and deer including B. burgdorferi and B. lonestari; however, B. lonestari was significantly more prevalent in the tick population than B. burgdorferi. Results from this study suggest that the majority of tick-borne diseases in Arkansas are not B. burgdorferi.

Differential Plasmodium falciparum infection of Anopheles gambiae s.s. molecular and chromosomal forms in Mali.

BACKGROUND: Anopheles gambiae sensu stricto (s.s.) is a primary vector of Plasmodium falciparum in sub-Saharan Africa. Although some physiological differences among molecular and chromosomal forms of this species have been demonstrated, the relative susceptibility to malaria parasite infection among them has not been unequivocally shown. The objective of this study was to investigate P. falciparum circumsporozoite protein infection (CSP) positivity among An. gambiae s.s. chromosomal and molecular forms. METHODS: Wild An. gambiae from two sites Kela (n=464) and Sidarebougou (n=266) in Mali were screened for the presence of P. falciparum CSP using an enzyme-linked immunosorbent assay (ELISA). Samples were then identified to molecular form using multiple PCR diagnostics (n=713) and chromosomal form using chromosomal karyotyping (n=419). RESULTS: Of 730 An. gambiae sensu lato (s.l.) mosquitoes, 89 (12.2%) were CSP ELISA positive. The percentage of positive mosquitoes varied by site: 52 (11.2%) in Kela and 37 (13.9%) in Sidarebougou. Eighty-seven of the positive mosquitoes were identified to molecular form and they consisted of nine Anopheles arabiensis (21.4%), 46 S (10.9%), 31 M (12.8%), and one MS hybrid (14.3%). Sixty of the positive mosquitoes were identified to chromosomal form and they consisted of five An. arabiensis (20.0%), 21 Savanna (15.1%), 21 Mopti (30.4%), 11 Bamako (9.2%), and two hybrids (20.0%). DISCUSSION: In this collection, the prevalence of P. falciparum infection in the M form was equivalent to infection in the S form (no molecular form differential infection). There was a significant differential infection by chromosomal form such that, P. falciparum infection was more prevalent in the Mopti chromosomal forms than in the Bamako or Savanna forms; the Mopti form was also the most underrepresented in the collection. Continued research on the differential P. falciparum infection of An. gambiae s.s. chromosomal and molecular forms may suggest that Plasmodium - An. gambiae interactions play a role in malaria transmission.