Abstract

Rickettsia felis belongs to spotted fever group Rickettsia and is an emerging human pathogen most commonly transmitted by a range of fleas and ticks. While recent evidence has suggested mosquitoes are infected with R. felis, there is little information about the role of mosquitoes in the organism’s transmission. In this study, around 100 mosquitoes were collected monthly between 2013 and 2014 from the same residential dwelling at Yangzhou, China. The collected mosquitoes were identified for their species and gender, followed by gltA-based PCR and hydroxymethylbilane synthase-based PCR to determine the prevalence of Rickettsia and blood meal. Three mosquito species (Culex pipiens: 76%, 996/1,304; C. tritaeniorhynchus: 17%, 216/1,304; Aedes albopictus: 7%, 92/1,304) were identified. For 1,088 female mosquitoes, 31% of them were positive for blood meal and 7% carried R. felis DNA. In a strong contrast, none of the 216 male mosquitoes were positive for blood meal but two males were positive for Rickettsia. Interestingly, 63% of R. felis-positive mosquitoes (50/79) were negative for blood meal, being significantly higher than 37% of mosquitoes and being positive for both R. felis and blood meal . Furthermore, we compared the prevalence of Rickettsia and blood meal in the mosquitoes collected in the months with temperature below and above 23°C, the minimum temperature required for mosquito egg hatching. Mosquitoes captured in the months below 23°C showed significant higher positivity of R. felis(71/936, 7.6% vs. 8/368, 2.2%; ) and blood meal (294/936, 31.4% vs. 36/368, 9.8%; ) than in the months above 23°C. Collectively, the seasonal and gender differences of R. felis and blood meal in mosquitoes add to the existing evidence, supporting a potential vector role of mosquitoes in the transmission of R. felis. Studies with a R. felis infection model covering the full life cycle of mosquitoes is necessary to unambiguously prove the transstadial and transovarial transmission of R. felis in mosquitoes.

1. Introduction

Rickettsia felis is an obligate intracellular Gram-negative bacterium belonging to the family Rickettsiaceae [1] and the agent of flea-borne spotted fever in people [2]. Except the primary vector of fleas, R. felis was detected in mosquitoes by a growing number of recent reports, paralleling the increasing implication of R. felis as a human pathogen [39]. Additionally, it was suggested that Rickettsia may be maintained in mosquitoes through both transstadial and transovarial transmission [4, 7, 8]. R. felis can grow in some mosquito cell lines, such as Aedes albopictus and Anopheles gambiae [10], indicating the possibility of the transmission and evolution of Rickettsia in the mosquito.

Mosquitoes are cosmopolitan in every land region with huge numbers except for Antarctica and a few islands [11]. Feeding on blood is a behavioral trait of female mosquitoes that allows them to obtain the nutrients necessary for reproduction [12]. Male mosquitoes mainly feed on nectar and plant juices, but not blood meal. However, the number and abundance of mosquito species and the blood-sucking activities are variable due to the vectors of climatic circumstances, animals, and human activities. Investigation on the seasonal differences of R. felis and blood meal in female and male mosquitoes will lead to a better understanding of this organism’s transmission.

Here, molecular approaches were used to determine the positivity of Rickettsia and blood meal of the mosquitoes captured from the same residential dwelling between September 2013 and August 2014. The findings of this study were described as below.

2. Materials and Methods

2.1. Sample Collection

Between September 2013 and August 2014, mosquitoes () were captured monthly with hand nets in the same residential dwelling of Yangzhou, Jiangsu, China (Table 1, Figure 1). The collection of mosquitoes was not performed in January and February of 2014 when the university was closed for the holiday. After washing in PBS to exclude the possibility of environmental contamination with R. felis, the species and gender of the collected mosquitoes were identified using standard morphological criteria [15] and PCR before putting into 400 μl (individual)/600 μl (pool) of RNA/DNA Stabilization Reagent (Roche Molecular Biochemicals, Indianapolis) and then stored at −80°C freezer until DNA extraction as described below. The average monthly temperatures in the Yangzhou were obtained from the local weather station.

2.2. DNA Extraction

After thawing and triturating with the shaker (Precellys 24 sysis and homogenization, France) at 5800 × rpm, 15 s × 2 (times), and 20 s (interrupt) at room temperature, mosquitoes were used for DNA extraction with QIAamp DNA Mini Kit (QIAGEN, Valencia, USA) according to the manufacturer’s descriptions.Then, the extracted DNAs were kept in −80°C freezer until performance of PCR assay detection.

2.3. PCR Assays

HMBS gene (hydroxymethylbilane synthase gene) is a single-copy gene of the heme synthesis pathway in mammalians but not plants and prokaryotes (Table 1). The HMBS-basedFRET-qPCR targeting for a 286 bp amplicon was used for blood meal detection in mosquitoes as described before [4, 13]. The HMBS-basedFRET-qPCR was proved to be highly sensitive and specific and was confirmed to detect 13 mammalian species of blood meals in mosquitoes [13].

The gltA-based FRET-qPCR targeting for a 170 bp amplicon of Rickettsia spp. and nested-PCR targeting for 446 bp and 353 bp amplicon gltA gene were used in this study to detect Rickettsia infections as described before [4, 5]. The gltA gene encodes one type of citrate synthase which plays a key role in energy production and providing biosynthetic precursors. The gltA-based PCRs were established with high sensitivity and specificity and applied in variety of samples including mosquitoes [4, 5].

The species of mosquitoes were also verified by the PCR assay with amplicon of 710 bp cytochrome c oxidase subunit 1 gene (CO1 gene) as described before [14, 16]. CO1 gene is one of three mitochondrial DNA-encoded subunits of cytochrome c oxidase which is a key enzyme in aerobic metabolism. It is proposed as the DNA barcoding system for animal life [17] and had been used as the DNA barcodes for the common mosquito species in China [16].

2.4. Statistical Analysis

The chi-squared test (Statistica, StatSoft, Tulsa, USA) was used to compare the prevalence of Rickettsia and blood meal between different groups of mosquitoes. was considered significantly different.

3. Results and Discussion

According to the morphological criteria and PCR followed by DNA sequencing, three mosquito species were identified in this study, including Culex pipiens (76%, 996/1,304), C. tritaeniorhynchus (17%, 216/1,304), and Aedes albopictus (7%, 92/1,304), in both female (83%, 1088/1,304) and male (17%, 216/1,304) (Table 1, Figure 1).

R. felis was detected in all the months with mosquito samples except in April and August of 2014 (6%, 79/1,304). We found that about one-third of the female mosquitoes (31%, 336/1,088) had taken a blood meal while 7% (77/1,088) carried R. felis DNA. In strong contrast, none of the 216 male mosquitoes were positive for a blood meal but two were R. felis positive. The absence of a blood meal in the males was anticipated as males do not feed on animals but obtain their nutrition from plants. Detection of R. felis DNA in male mosquitoes, however, suggests vertical (transovarial) transmission of R. felis in mosquitoes such that the organism could be maintained in the population without mosquitoes having to feed on rickettsemic hosts.

In this study, 79 R. felis-positive mosquitoes were identified. For these Rickettsia-positive samples, 63% of them (50/79) were free of a blood meal, being significantly higher than 37% being also positive for blood meal (29/79) () (Table 2, Figure 1). This further stipulates the possibility of vertical transmission of this organism in mosquitoes.

Yangzhou, located in the east of China with the coordinates of 32°24′N, 119°25′E, has a subtropical monsoon climate with humid changeable wind, longer winter (4 months) and summer (3 months), and shorter springs and autumns (2 months each). The annual average temperature is 15°C with the highest in July (40°C) and lowest in January (−15°C). The average atmosphere temperature for each of the four months (May, June, July, and August) of 2014 was above 23°C, the minimum temperature required for mosquito egg hatching [18, 19]. Species richness and number abundance of the mosquito were generally higher during the summer and fall [20]; for instance, C. pipiens appear around May, and the density slowly increased until a seasonal maximum in July-August [21] or sometimes later in September [22], which is confirmed by our findings in this study. The temperature is critical to key life-fitness parameter of the stages of many insect species [23], including mosquitoes. The development thermal threshold (23°C) (Figure 1(c), dash line) is the temperature below which immature stages would stop developing [18, 19]. The data in this study indicated that the positivity of R. felis (2%, 8/368 vs. 8%, 71/936, ) and blood meal (10%, 36/368 vs. 31%, 294/936, ) in these four months above 23°C was significantly lower than those months below 23°C (Figure 1). Mosquitoes captured in the months without the possibility of mosquito egg hatching had significantly higher prevalence of R. felis than those in the months with constant egg hatching. This difference may add to the evidence suggesting the transstadial and transovarial transmission of R. felis in mosquitoes. In order to unambiguously prove the transstadial and transovarial transmission of this organism in mosquitoes, further studies with a R. felis infection model covering each life stage of mosquitoes is necessary.

4. Conclusions

In conclusion, the seasonal and gender differences of R. felis and blood meal in mosquitoes suggest the possible transstadial and transovarial transmission of R. felis in mosquitoes. Studies with the R. felis infection model within the full life cycle of mosquito are necessary to unambiguously prove the potential vector role of mosquitoes in transmission of this organism.

Data Availability

The data used to support the findings of this study are included within the article.

Conflicts of Interest

The authors declare that they have no conflicts of interest.

Acknowledgments

This project was supported by grant from the National Natural Science Foundation of China (no. 31472225) and the Priority Academic Program Development of Jiangsu Higher Education Institutions, Yangzhou, Jiangsu Province, China.