Evidence for Vertical Transmission of Babesia odocoilei (Piroplasmida: Babesiidae) in Ixodes scapularis (Acari: Ixodidae).

Limited evidence suggests that the cervid parasite, Babesia odocoilei, is transovarially transmitted from adult female Ixodes scapularis Say to offspring. The prevalence of B. odocoilei in unfed larval I. scapularis and whether vertical transmission is crucial to pathogen maintenance are currently unknown. To investigate these questions, 275 unfed larvae from two Wisconsin counties were tested for B. odocoilei genetic material. Sixteen of 29 pools were positive for the parasite. The maximum likelihood estimation for overall larval infection prevalence was 7.8% (95% confidence interval: 4.7-12). This vertically acquired infection appears to be sustained transstadially in nymphal ticks the following year; however, our relatively small sample and replicate size warrants additional evaluation. Our study revealed further evidence of vertical transmission, a low and consistent infection prevalence in larvae, and the potential importance of vertical transmission in B. odocoilei maintenance.

High Proportion of Unfed Larval Blacklegged Ticks, Ixodes scapularis (Acari: Ixodidae), Collected From Modified Nest Boxes for Mice.

The blacklegged tick, Ixodes scapularis Say, is the primary vector of several tick-borne pathogens, including those causing Lyme disease and babesiosis, in the eastern United States and active collection methods for this species include dragging or wild animal sampling. Nest boxes targeting mice may be an alternative strategy for the surveillance and collection of immature I. scapularis feeding on these hosts and would be much safer for animals compared to small mammal trapping. We constructed double-walled insulated nest boxes (DWINs) with collection tubes mounted below the nesting chamber and deployed eleven in southern Wisconsin from June until September of 2020. The DWINs were occupied by Peromyscus spp. and birds (wren species, Troglodytidae family). We collected 192 ticks from collection tubes, all of which were identified as either I. scapularis (95%) or Dermacentor variabilis Say (Acari: Ixodidae) (5%). Only 12% (21/182) and 20% (2/10) of I. scapularis and D. variabilis were blood-fed, respectively. The high proportion of unfed ticks found in collection tubes may be due to grooming by hosts inside the nest boxes. Alternatively, immature ticks may have climbed trees and entered the DWIN seeking a host. Results suggest that nest boxes could be a tool for finding ticks in areas of low density or at the leading edge of invasion, when small mammal trapping or drag sampling is not feasible.

Coinfection of Ixodes scapularis (Acari: Ixodidae) Nymphs With Babesia spp. (Piroplasmida: Babesiidae) and Borrelia burgdorferi (Spirochaetales: Spirochaetaceae) in Wisconsin.

Borrelia burgdorferi, the spirochete that causes Lyme disease, is endemic and widespread in Wisconsin. Research in the northeastern United States has revealed a positive association between Babesia microti, the main pathogen that causes babesiosis in humans, and Bo. burgdorferi in humans and in ticks. This study was conducted to examine associations between the disease agents in the Upper midwestern United States. Ixodes scapularis Say nymphs (N = 2,858) collected between 2015 and 2017 from nine locations in Wisconsin were tested for Babesia spp. and Borrelia spp. using real-time PCR. Two species of Babesia were detected; Ba. microti and Babesia odocoilei (a parasite of members of the family Cervidae). Prevalence of infection at the nine locations ranged from 0 to 13% for Ba. microti, 11 to 31% for Bo. burgdorferi sensu stricto, and 5.7 to 26% for Ba. odocoilei. Coinfection of nymphs with Bo. burgdorferi and Ba. odocoilei was detected in eight of the nine locations and significant positive associations were observed in two of the eight locations. The prevalence of nymphal coinfection with both and Bo. burgdorferi and Ba. microti ranged from 0.81 to 6.5%. These two pathogens were significantly positively associated in one of the five locations where both pathogens were detected. In the other four locations, the observed prevalence of coinfection was higher than expected in all but one site-year. Clinics and healthcare providers should be aware of the association between Ba. microti and Bo. burgdorferi pathogens when treating patients who report tick bites.

Cloning and molecular characterization of two invertebrate-type lysozymes from Anopheles gambiae.

We sequenced and characterized two novel invertebrate-type lysozymes from the mosquito Anopheles gambiae. Alignment and phylogenetic analysis of these and a number of related insect proteins identified through bioinformatics strategies showed a high degree of conservation of this protein family throughout the Class Insecta. Expression profiles were examined for the two mosquito genes through semiquantitative and real-time PCR analysis. Lys i-1 transcripts were found in adult females in the fat body and Malpighian tubules, whereas Lys i-2 was detected only in fat bodies. Blood-feeding resulted in significantly increased transcript abundance for both genes in the midguts. Neither gene was upregulated following bacterial challenge.

Distinct families of site-specific retrotransposons occupy identical positions in the rRNA genes of Anopheles gambiae.

Two distinct site-specific retrotransposon families, named RT1 and RT2, from the sibling mosquito species Anopheles gambiae and A. arabiensis, respectively, were previously identified. Both were shown to occupy identical nucleotide positions in the 28S rRNA gene and to be flanked by identical 17-bp target site duplications. Full-length representatives of each have been isolated from a single species, A. gambiae, and the nucleotide sequences have been analyzed. Beyond insertion specificity, RT1 and RT2 share several structural and sequence features which show them to be members of the LINE-like, or non-long-terminal-repeat retrotransposon, class of reverse transcriptase-encoding mobile elements. These features include two long overlapping open reading frames (ORFs), poly(A) tails, the absence of long terminal repeats, and heterogeneous 5' truncation of most copies. The first ORF of both elements, particularly ORF1 of RT1, is glutamine rich and contains long tracts of polyglutamine reminiscent of the opa repeat. Near the carboxy ends, three cysteine-histidine motifs occur in ORF1 and one occurs in ORF2. In addition, each ORF2 contains a region of sequence similarity to reverse transcriptases and integrases. Alignments of the protein sequences from RT1 and RT2 reveal 36% identity over the length of ORF1 and 60% identity over the length of ORF2, but the elements cannot be aligned in the 5' and 3' noncoding regions. Unlike that of RT2, the 5' noncoding region of RT1 contains 3.5 copies of a 500-bp subrepeat, followed by a poly(T) tract and two imperfect 55-bp subrepeats, the second spanning the beginning of ORF1. The pattern of distribution of these elements among five siblings species in the A. gambiae complex is nonuniform. RT1 is present in laboratory and wild A. gambiae, A. arabiensis, and A. melas but has not been detected in A. quadriannulatus or A. merus. RT2 has been detected in all available members of the A. gambiae complex except A. merus. Copy number fluctuates, even among the offspring of individual wild female A. gambiae mosquitoes. These findings reflect a complex evolutionary history balancing gain and loss of copies against the coexistence of two elements competing for a conserved target site in the same species for perhaps millions of years.

Mapping a quantitative trait locus involved in melanotic encapsulation of foreign bodies in the malaria vector, Anopheles gambiae.

A Plasmodium-refractory strain of Anopheles gambiae melanotically encapsulates many species of Plasmodium, whereas wild-type mosquitoes are usually susceptible. This encapsulation trait can also be observed by studying the response of refractory and susceptible strains to intrathoracically injected CM-Sephadex beads. We report the results of broad-scale quantitative trait locus (QTL) mapping of the encapsulation trait using the bead model system. Interval mapping using the method of maximum likelihood identified one major QTL, Pen1. The 13.7-cM interval containing Pen1 was defined by marker AGH157 at 8E and AGH46 at 7A on 2R. Pen1 was associated with a maximum LOD score of 9.0 and accounted for 44% of the phenotypic variance in the distribution of phenotypes in the backcross. To test if this QTL is important for encapsulation of Plasmodium berghei, F2 progeny were infected with P. berghei and evaluated for degree of parasite encapsulation. For each of the two markers that define the interval containing Pen1, a significant difference of encapsulation was seen in progeny with at least one refractory allele in contrast with homozygous susceptible progeny. These results suggest that Pen1 is important for melanotic encapsulation of Plasmodium as well as beads.

Sp22D: a multidomain serine protease with a putative role in insect immunity.

Serine proteases play critical roles in a variety of insect immune responses; however, few of the genes that code for these enzymes have been cloned. Here, we describe the molecular characterization of a serine protease gene from the mosquito Anopheles gambiae. Sp22D codes for a 1322 amino acid polypeptide with a complex domain organization. In addition to the carboxy terminal serine protease catalytic domain, Sp22D contains two putative chitin binding domains, a mucin-like domain, two low density lipoprotein receptor class A domains, and two scavenger receptor cysteine rich domains. A typical signal peptide sequence and a lack of potential transmembrane helices suggest that Sp22D is secreted. Sp22D is expressed constitutively in three immune-related cell types: adult hemocytes, fat body cells, and midgut epithelial cells. Wounding induces no changes in transcript abundance, but within 1h after injection of bacteria, Sp22D mRNA increases 1.5-fold. Based on domain organization, tissue distribution, and transcriptional up-regulation in response to immune challenge, we suggest that Sp22D has an immune function. In addition, we predict that Sp22D is secreted into the hemolymph where it may interact with pathogen surfaces and initiate an immune response.

Induction of mosquito hemolymph proteins in response to immune challenge and wounding.

The rapid induction of proteins in the hemolymph of the mosquito, Anopheles gambiae, was examined after wounding or injection of immune elicitors (Escherichia coli, lipopolysaccharide, laminarin, zymosan). One-dimensional gel electrophoresis revealed at least six hemolymph polypeptides >25 kDa that consistently appeared after any breech of the cuticle. All of these polypeptides appeared in the hemolymph within 30 min and reached a maximum concentration after approx. 6 h. No proteins were specifically induced by bacteria or bacterial or fungal cell wall products, however two constitutively expressed proteins were repressed by these injections. Patterns of hemolymph proteins were further analyzed by two-dimensional electrophoresis. Seven spots were enhanced or induced 2 h after injection in four replicate experiments. An additional two spots demonstrated some variability between replicates, but were generally responsive to injection. These rapidly induced polypeptides are candidates for regulating and initiating the mosquito's responses to pathogens and wounding.

Serine proteases as mediators of mosquito immune responses.

Serine proteases regulate several invertebrate defense responses, including hemolymph coagulation, antimicrobial peptide synthesis, and melanization of pathogen surfaces. These processes require the presence of serine proteases in the hemolymph where they can rapidly activate immune pathways in response to pathogen detection. Hemolymph coagulation in the horseshoe crab is controlled by several serine proteases, including two that are pathogen recognition molecules and two in the clip domain family of serine proteases. The antimicrobial peptide synthesis and melanization pathways include clip domain proteases as well as other, uncharacterized serine proteases. We have identified five serine proteases from the hemolymph of the mosquito, Anopheles gambiae. One, Sp22D, is a large protease with potential pathogen binding domains. Sp22D is expressed in three tissues that have immune functions (midgut epithelium, fat body, and hemocytes), and its transcript abundance increases after immune challenge. Sp14A, Sp14D1, and Sp14D2 are clip domain serine proteases that are similar to enzymes with presumed roles in melanization or antimicrobial peptide synthesis. They undergo changes in transcript abundance in response to infection with bacteria or malaria parasites, and they reside in a chromosomal region that has been associated with melanization of parasites. Sp18D, also a clip domain protease, is similar to a Manduca protease with a likely role in immunity, but immune challenge does not affect its mRNA abundance.

Molecular characterization of five serine protease genes cloned from Anopheles gambiae hemolymph.

We identified five new serine protease cDNAs from the hemolymph of the malaria vector, Anopheles gambiae. All five show sequence similarity to genes thought to be involved in vertebrate or invertebrate defense responses. Sp14A, Sp14D2 and Sp22D demonstrate changes in transcript abundance in response to bacteria injections. Sp14A and Sp14D2, as well as the previously characterized Sp14D1, are induced by infection with the malaria parasite, Plasmodium berghei. These three proteases, along with Sp18D, are related to a group of secreted proteases that have amino-terminal clip domains and trypsin-like substrate specificity. BLAST results and phylogenetic analyses group Sp14A, Sp14D1 and Sp14D2 with the Drosophila protease EASTER, and three prophenoloxidase activating enzymes from other insects. EASTER's substrate is SPAETZLE, a ligand involved in embryogenesis but also in activating anti-microbial peptide synthesis. Their similarity to EASTER and immune inducibility suggest that one of these proteases may activate a SPAETZLE-like ligand during anti-parasite responses in mosquitoes. Alternatively, as potential prophenoloxidase activators, Sp14A, Sp14D1 or Sp14D2 may play a role in melanotic encapsulation of Plasmodium.

A genetic study of a melanization response to Sephadex beads in Plasmodium-refractory and -susceptible strains of Anopheles gambiae.

A previously selected Plasmodium-refractory strain of Anopheles gambiae melanotically encapsulates many species of Plasmodium. Genetic studies of this strain have shown that this refractory phenotype is controlled by a limited number of genes, and the existence of two such genes, Pif-B and Pif-C, has been demonstrated. Further work to determine the molecular basis for this mode of refractoriness led to the discovery that the host-parasite interaction is mimicked by the mosquito's response to carboxymethyl (CM)-Sephadex beads injected into the thorax. These small beads are melanized within 24 hr in refractory mosquitoes but are rarely melanized in susceptible ones. Because of the considerable potential in using bead melanization as a model for Plasmodium refractoriness, we performed a genetic analysis of the differential response to beads. Reciprocal crosses of susceptible (4arr) and refractory (L35) mosquitoes and an analysis of F1 phenotypes were done. The F1 progeny had a phenotype similar to that of the parental refractory mosquitoes; therefore, dominant refractory allele(s) must be present in the refractory strain. Males from the reciprocal crosses had identical phenotypes, indicating that X-linked loci did not have a visible effect on the melanizing phenotype. To further study the mode of inheritance of the melanizing trait, a backcross of F1 females to 4arr males was done. The phenotypic distribution of the backcross progeny was bimodal, and the melanization phenotypes were similar to those of the susceptible and refractory parents. These data suggest that a small number of loci are responsible for the differential response to CM-Sephadex beads, and that one chromosomal region contributes strongly to the melanizing trait. Because the 4arr strain carries mutations in the pink eye (X) and red eye (III) genes, possible linkage of the melanizing phenotype to these two genes was tested. No linkage with either marker was detected. The pattern of inheritance of the melanizing phenotype is similar to that of the refractory phenotype of Pif-B; therefore, the genetic basis of the two responses may be the same.

Ixodes scapularis (Acari:Ixodidae): status and changes in prevalence and distribution in Wisconsin between 1981 and 1994 measured by deer surveillance.

A statewide survey of blacklegged ticks, Ixodes scapularis Say, on white-tailed deer was conducted in 1994 to examine the status and changes in the prevalence and geographic distribution of this tick in Wisconsin. I. scapularis adults were collected at 17 of 26 deer registration stations, including stations in eastern (Poy Sippi) and southern Wisconsin (Monroe) without previously reported populations. Nearly all of the stations where 1 or no ticks were collected were in the eastern 1/3 of the state. The prevalence of I. scapularis in 1994 was compared with prevalence estimates taken in similar surveys during 1981 and 1989. A significant increase in tick prevalence occurred at stations along the Wisconsin River Valley, which previously defined the edge of the eastern range of I. scapularis populations and in southern Wisconsin.

Effects of larval nutrition, adult body size, and adult temperature on the ability of Anopheles gambiae (Diptera: Culicidae) to melanize sephadex beads.

A Plasmodium-refractory strain (L35) of the mosquito Anopheles gambiae Giles melanizes late ookinetes on the basal surface of the midgut, resulting in the death of the parasites. This strain also melanizes CM C-25 Sephadex beads, which serve as a model system for investigating the melanization response. The effects of larval nutrition, adult body size, and temperature of the adult environment on the ability of refractory females to melanize CM C-25 beads were studied. Nutritional deprivation during the larval stages significantly decreased the ability of adults to melanize beads. In addition, bead melanization decreased progressively as the environmental temperature of the adults increased from 24 to 30 degrees C. We conclude that environmental stress may affect the immune responses of An. gambiae.

Ixodes scapularis (Acari: Ixodidae): abundance and rate of infection with Borrelia burgdorferi in four state parks in Wisconsin.

Four state parks located in Lyme disease endemic regions of Wisconsin were surveyed for the presence of Ixodes scapularis Say during May and June of 1998 by drag sampling along hiking trails. Nymphal abundance varied between parks, with the average number of nymphs encountered in 1 h ranging from 6.2 +/- 3.8-47.1 +/- 36.3 (mean +/- SD). Questing nymphs were tested for the presence of Borrelia burgdorferi by culture in BSK medium and 7-12% was found to be infected. The average risk of encountering an infected nymph (entomologic risk index) ranged from 0.5 to 5.2 infected nymphs per hour. The highest entomological risk index was recorded from a small island park in northwestern Wisconsin during the last week in May (8.0 infected nymphs per hour). These results indicate a lower risk for human Lyme disease exposure in Wisconsin state parks in comparison with highly endemic areas of the northeastern United States.

Evaluation of the polymerase chain reaction method for identifying members of the Anopheles gambiae (Diptera: Culicidae) complex in southern Africa.

Chromosomally and electrophoretically identified field samples of members of the Anopheles gambiae Giles complex from southern Africa and colony material were used to test the polymerase chain reaction (PCR) method of identification. The samples included An. arabiensis Patton, An. quadriannulatus Theobald, and An. merus Donitz. Only one of the 217 specimens examined was disputed. Twenty specimens (9%) were reamplified because of the presence of multiple bands or lack of amplification after the first assay. Specimens of An. merus from this region displayed both the diagnostic An. merus PCR band as well as the An. quadriannulatus band, possibly because of interspecific hybridization or random variation within the population. This work extends the geographical range over which the PCR technique has been verified to southern Africa.

Borrelia burgdorferi-infected Ixodes scapularis (Acari: Ixodidae) and Peromyscus leucopus in northeastern Wisconsin.

Populations of the blacklegged tick, Ixodes scapularis Say, are established in western and central Wisconsin in the upper midwestern United States, but appear to be expanding geographically there. Here, we report a previously unknown population in northeastern Wisconsin. Questing I. scapularis nymphs and adults were collected by flagging vegetation from a riverine site in Marinette County, Wisconsin, in spring of 1993 and 1994. Dissection and culture of tick guts in modified Barbour-Stoenner-Kelley II medium showed that some of the ticks were infected with Borrelia burgdorferi Johnson, Schmid, Hyde, Steigerwald & Brenner, causative agent of Lyme disease. Fifteen of 30 white-footed mice, Peromyscus leucopus (Rafinesque), live-trapped at the site on 23-24 August 1994 were infested with immature I. scapularis, and ear-punch biopsies yielded B. burgdorferi cultures from 2 of the mice. However, none of 50 white-tailed deer, Odocoileus virginianus (Zimmermann), shot by hunters in Marinette County in November 1994 had I. scapularis on them, probably because no deer were shot at the same site where the tick population is located. These findings document existence of an established population of I. scapularis and a focus of Lyme disease in northeastern Wisconsin.

Comparison of two ribosomal DNA-based methods for differentiating members of the Anopheles gambiae complex (Diptera: Culicidae).

Two DNA-based methods, the restriction fragment length polymorphism (RFLP) and polymerase chain reaction (PCR), were used to identify mosquitoes of the Anopheles gambiae Giles complex collected in Kenya. Field-collected specimens of An. gambiae, An. arabiensis Patton, and An. merus Donity were tested. From a sample of 208 mosquitoes, 181 (87%) were identified by the RFLP method and 205 (99%) were identified by the PCR method. There was complete concordance between the two methods with regard to species identification. PCR assays were simpler, faster, and more reliable than RFLP assays.

Ultrastructure of the encapsulation of Plasmodium cynomolgi (B strain) on the midgut of a refractory strain of Anopheles gambiae.

Using transmission electron microscopy, we investigated the encapsulation of the simian malaria parasite, Plasmodium cynomolgi, in a refractory strain of the mosquito, Anopheles gambiae. After the ookinete penetrates the mosquito midgut epithelium and lodges between the basal membrane and the basal lamina, an electron-dense, melanin-like substance begins to coalesce around the parasite. Completely encapsulated parasites were found as early as 16 hr after the blood meal. Granules of the melanin-like substance often appeared to condense onto the parasite from the fluid in the extracellular spaces of the basal membrane labyrinth. Melanin granules also appeared to condense from the hemolymph onto the basal lamina underlying the parasite. In addition, groups of tubules, vesicles, and membranous whorls often were found in midgut cells that were located next to or were enclosing parasites. These structures were unusually electron-dense, and may have been associated with melanization. Hemocytes rarely were observed near completed capsules and neither hemocytes nor their remnants were components of the capsules. During later stages of encapsulation, parasites appeared abnormal and often were infiltrated with melanin. Although late-stage capsules were usually located basally, completed capsules enclosed by membranes were occasionally observed near the apical border of the midgut. Other capsules associated with cellular debris, were found in the lumen of the midgut from 1 to 6 days after the blood meal.

Ultrastructural localization of phenoloxidase in the midgut of refractory Anopheles gambiae and association of the enzyme with encapsulated Plasmodium cynomolgi.

A melanogenic enzyme, phenoloxidase, was localized ultrastructurally in the midgut epithelia of 2 strains of Anopheles gambiae, a refractory strain that melanotically encapsulates Plasmodium cynomolgi ookinetes on the midgut, and a susceptible strain that does not. Midguts were incubated with either dopa or dopamine, and the resultant electron-dense product of phenoloxidase activity was localized on the basal lamina (BL) and cellular basal membrane labyrinth (BML) in uninfected mosquitoes of both strains. In infected refractory mosquitoes, the reaction products still were observed on the BL and BML but were especially dense in the BML of midgut cells near encapsulated ookinetes and in the capsule itself. In infected susceptible mosquitoes, phenoloxidase localization was reduced or absent in the BL and BML and was not observed near parasites. Phenylthiourea (PTU) inhibited the phenoloxidase reaction, indicating that the reaction product deposited in the absence of PTU resulted from enzyme activity and not autooxidation of the substrates. It is concluded that higher levels of phenoloxidase in the refractory strain following a blood meal may contribute to the ability to encapsulate ookinetes.

The lethal effects of Cyperus iria on Aedes aegypti.

The sedge Cyperus iria, a common weed in rice, contains large amounts of the insect hormone (10R) juvenile hormone III (JH III). Given its widespread distribution in Asia and Africa, we examined the possibility that C. iria could be used as a safe, inexpensive, and readily available mosquito larvicide. Plants of varying ages were harvested and leaves tested for lethal effects on larvae of the yellow fever mosquito, Aedes aegypti. The median lethal doses (LD50s) for frozen leaves from 1- and 2-month-old plants were 267 and 427 mg/100 ml of water, respectively. Leaves from 1-month-old C. iria contained 193 micrograms JH III/g fresh weight, whereas leaves from 2-month-old plants contained 143 micrograms JH III/g fresh weight. Larval sensitivity to the plant differed with age; 4-day-old larvae displayed the greatest mortality followed in decreasing sensitivity by larvae 5, 6, 3, and 2 days old. Six Cyperus species (C. albostriatus, C. alternifolius, C. esculentus, C. iria, C. miliifolius, and C. papyrus) of similar developmental stage were assayed for JH III content. Only C. iria was found to contain significant levels of JH III.