Full Length Research Paper
ABSTRACT
Mansonellosis is a vector-borne infection caused by different species of filarial nematodes of the genus Mansonella, including ozzardi, perstans, and streptocerca. The infection is mainly transmitted by bloodsucking midges of the genus Culicoides. All Mansonella species are known to induce little to no symptoms in humans. Due to the asymptomatic nature of the infection, epidemiological and immunological data are almost inexistent. Here, we collected blood samples from 88 volunteers in 3 major departments of South Benin and analyzed using parasitological and molecular approaches, the presence of Mansonella infections in the region. Polymerase chain reaction (PCR) and entomological identification strategy were then used on 252 potential vectors collected in the same area to identify those hosting the parasite. While microscopic observations indicate a prevalence of 27.3% of Mansonella perstans infections, PCR analyses revealed a much higher burden (40.9%). Molecular analyses further showed that 2.27% of the tested individuals were positive for Mansonella streptocerca. Moreover, data from molecular identification of the parasites and morphological examination of the vectors revealed that out of 11 Culicoides species identified in the study region, milnei, imicola, and inornatipennis were positive for M. perstans. Our findings suggest PCR as a tool of choice to analyze the prevalence of Mansonellosis and demonstrate that M. perstans is the predominant Mansonella spp. in South Benin. Finally, the present study supports the hypothesis that a high transmission of M. perstans is maintained in the region of South Benin by three main Culicoides spp., including milnei, imicola, and inornatipennis.
Key words: Mansonella, M. perstans, vectors, Culicoides.
INTRODUCTION
Humans are the definitive hosts for several filarial nematode parasites, including mansonelliasis. Mansonella perstans, Mansonella streptocerca, and Mansonella ozzardi are the three agents that cause mansonelliasis (Simonsen et al., 2011). M. perstans is a human filarial nematode transmitted by vectors spread over sub-Saharan Africa (Raccurt, 2018), Central and South America, and the Caribbean.
It is transmitted by microscopic blood-sucking flies known as midges (Chung et al., 2020). M. ozzardi appears to be primarily linked with humans, but patas monkeys (Erythrocebuspatas) have been infected with them for experimental purposes (Ferreira et al., 2021). The black fly Simulium amazonicum and the midge Leptoconops bequaerti may operate as concurrent vectors in various parts of South America and Haiti, respectively (Conte et al., 2003). M. streptocerca is primarily a human parasite, but it has been known to infect wild chimps in rare instances. Biting midges of the genus Culicoides, like other Mansonella species vectors, are the principal vectors (Gaillard et al., 2020). Vector-borne diseases are spread by insects such as mosquitoes, ticks, and fleas. Infectious illnesses can be transmitted from one host (carrier) to another via various vectors (da Silva et al., 2017). There are now 14 vector-borne diseases in the United States of national public health concern (Bélard and Gehringer, 2021). These diseases cause many human illnesses and deaths yearly and should be reported to the Centers for Disease Control (CDC) and Prevention’s National Notifiable Diseases Surveillance System. The CDC received 51,258 reports of vector-borne illness cases from state and local health officials in 2013 (Tang et al., 2010).
The irregularity, dispersion, and commonness of vector-borne diseases are heavily influenced by environmental factors, exceptionally high and low-temperature limits, and precipitation patterns (Vijayvargiya et al., 2019). Climate change can alter natural factors such as vector population size and thickness, vector endurance rates, the overall wealth of disease-carrying creatures (zoonotic) supply hosts, and microorganism proliferation rates, resulting in altered climate patterns and an increase in extreme events that can influence infection flare-ups by altering organic factors such as vector population size and thickness, vector endurance rates, and microbe multiplication rates (Confalonieri and Dutra, 2014, Raccurt, 2018). The risk of infection spreading to individuals may increase due to these changes (Jamison et al., 2015). South Africa is known for its wide range of weather conditions. The country’s climate varies from tropical to subtropical high summer precipitation regions in the north to semi-arid conditions in the northwest (Gehringer et al., 2014). As we get closer to the focal point, the stature decreases, as do the temperatures during the winter months. Many parts of the country have weather conditions that allow massive numbers of adult Culicoides midges to stay active all year, with daytime temperatures occasionally falling below 0°C (Laidoudi et al., 2020). During the mild winter, small populations of infection-infected adult midges may thus live long enough between episodes. The vector spans should be shorter than the most severe season of viremia in the vertebrate population to ensure continued transmission of viral illnesses (Keiser et al., 2008). Culicoides biting midges are the most common hematophagous insects and can be found worldwide (Agbolade et al., 2006). They transmit a broad spectrum of human, domestic, and wild animal infections (Debrah et al., 2017). The seasonal abundance of Culicoides midges, the vector of Bluetongue and African horse sickness viruses (BTV/AHSV), the incidence of viruses in midges and black flies of the Simulium species family for M. ozzardi (Wanji et al., 2019)were determined in three geographic locations in South Africa (Shelley and Coscarón, 2001). In the current research, we will identify, discuss and highlight the different vectors of Mansonella species in Benin.
METHODOLOGY
Specimen collections and storage
The study areas, known to be highly endemic for Mycobacterium ulcerans infection from the earlier screening of school children, include three big communes: Abomey, Couffo, and Mono. The communities in these areas are located in reasonably flat bushland and extensive border swamps. The Davougon village is situated approximately 150 km from Cotonou. The neighboring villages border the river Couffo and its associated swamps on their east side. Domestic water is collected mainly from communal boreholes with hand pumps, but some people also collect water from the swamp and an unprotected spring between the villages. The populations mainly practice subsistence farming (bananas, cassava, sweet potatoes, maize, beans, and other vegetables) and keep animals (cows, goats, sheep, pigs, ducks, chickens, and pigeons) on a small scale. Some cassava is also grown as a cash crop, and a few males are engaged in charcoal burning. Most houses in these areas have brick walls and iron sheets. Few houses have mud walls and are roofed with dried grass or iron sheets (Figure 1). Blood specimens (0.5-1 ml) from patients with known M. perstans and characteristic Culicoides gnawing midges were collected and stored in EDTA tubes. Standard microscopy and PCR-based techniques were used to reach the first conclusions. M. perstans was identified using Knott’s focus, which was identified using thin blood films. The extra living creatures were identified using laboratory-grown, clinically approved PCR tests, which were confirmed by Sanger sequencing of a segment of glpQ after PCR enhancement. Except for the Mp test, in which samples were frozen at -80°C for an extended period, all samples were stored at 4°C prior to further analysis, and nucleic corrosive was isolated within four days of collection to avoid the degradation of the genetic material from the sample.
Sample preparation
The DNA test was carried out in a laminar stream hood. The MolYsis Complete 5-unit (Molzym, Bremen, Germany) kit was used for DNA extraction and host DNA evacuation. Because of the small sample volume, the manufacturer recommended using the “small-size test convention,” except that elution was done using 70 μL of deionized water. The REPLI-g Single Cell Kit (Qiagen, Hilden, Germany) was used to enhance the entire genome in a separate room from the test readiness. Agencourt AMPure XP dots (Beckman Coulter, Brea, CA) were used to purge enhanced DNA with a globule volume of 1.5X the sample volume. By adding sub-atomic grade water (DNase/RNase free), cleaned DNA was attenuated to a concentration of 2 ng/L. A final test volume of 50 μL was used for sequencing.
Collection and analysis of vectors
From December 2020 to July 2021, samples of Culicoides biting midges were collected bimonthly between 6:00 and 9:00 a.m. following the previously described human bait method (Agbolade et al., 2005). Culicoides samples were immediately taken to the laboratory, where they were identified, dissected, and examined for filarial larvae using a dissecting binocular Olympus® CX23 microscope.
Sequencing
Adult midges captured using light traps were stored at 20°C in 70% ethanol. Total DNA extraction, mitochondrial cytochrome c oxidase I (cox 1) PCR amplification, and sequencing analysis were carried out as previously described (Matsuda et al., 2009). The sequencing data were deposited in GenBank, and the sequences of Culicoides species, as determined here and in previous work of Matsuda et al. (2009), were aligned with BioEdit v7.0 for comparison.
Molecular biological methods
Isolation of plasmid DNA
According to the manufacturer’s instructions, Plasmid DNA was filtered using the QIAprep® MiniprepKit (Qiagen), using a 30 µl elution volume. A QIAcube automated workstation separated genomic and plasmid DNA from various samples (Qiagen).
DNA extraction
A single adult midge was squished using a plastic pestle in a 1.5-ml microcentrifuge tube. According to the manufacturer’s instructions, the DNeasy Tissue and Blood Kit extracted complete DNA from the hatchlings (Qiagen, Hiden, Germany).
Polymerase chain reaction (PCR)
PCR is a comprehensively utilized standard strategy to create high measures of any ideal DNA grouping in vitro (Mullis et al., 1986). The standard reaction blend and PCR cycling boundaries are displayed in Table 1.
PCR and sequencing analysis
PCR items were cleansed using a NucleoSpin® Gel and PCR Clean-up Kit (MACHEREY-NAGEL, Düren, Germany) and ligated into the pCR4-TOPO vector utilizing the TOPO®TA pack (Thermo Fisher Scientific, Karlsruhe, Germany). Plasmids were changed into competent Escherichia coli cells (Table 2), and states containing recombinant plasmids (12 white settlements) were picked and developed for the time being utilizing standard conditions. Recombinant plasmid DNA was removed for the time being from E. coli societies utilizing a QIAprep Plasmid Miniprep Kit (Qiagen, Hilden, Germany). The measures of additions were dictated by province PCR of the plasmid DNA employing pTOP-seqprimers (Thermo Fisher Scientific). Plasmids with fragments of the right size were exposed to sequencing. Sanger sequencing was performed by Seqlab GmbH (Göttingen, Germany). The arrangements acquired from each gene clone were adjusted, and agreement successions characterized forward and inverted strands (n=24). BioEdit (Hall, 1999)and Blast (Altschul et al., 1990)were utilized for the arrangements investigation.
Primers
For cloning into articulation vectors and sequencing, preliminary steps were used. The right portion shows the toughening temperatures used in PCRs and the limiting compounds. The primers used in the reaction are shown in Table 2.
Molecular identification of vectors
The DNeasy Blood and Tissue Kit (Qiagen) was utilized to seclude DNA from the blood of gnawing midges. The full-blood dinner investigation was done per the distributed mosquito convention and the specialized details given by Lassen et al. (1972). The samples were first screened with an animal-type explicit groundwork. The presence of a PCR item from some random sample in gel electrophoresis was viewed as a positive outcome for that sample. Eurofins MWG|Operon sequenced the filtered PCR items on a business premise (Ebersberg, Germany). The produced FASTA documents were then used to distinguish species utilizing the GenBank DNA succession data set’s nucleotide-nucleotide essential arrangement searches apparatus (BLAST)¹. Few samples identified as positive by the species-explicit groundwork pair were then enhanced with the widespread preliminary pair, and the subsequent successions were approved in GenBank. If any sample did not give good results due to technical errors such as sequencing issues or deficient DNA extraction, the samples were repeatedly reanalyzed before being discarded or tagged irrelevant.
RESULTS
This study included 88 patients with suspected Mp attending the hospital. There were 66 (75%) females and 22 (25%) males in the present study (Figure 2). Microscopically by counting chamber technique, M. perstans was observed in 24 patients amongst 88 samples obtained from patients representing the prevalence of M. perstans (Table 3). Among 88 samples, 36 were positive on PCR based on M. perstans Internal Transcribed Spacer1 (MpITS1) (Table 5). 15 (22.73%) females were observed positive for M. perstans, while 9 (40.90%) males were observed with M. perstans microscopically (Table 4). Based on PCR, 25 (37.87%) females and 11 (50%) males were observed to be positive for M. perstans (Figure 2 and Table 4). Six locations were sampled during the Culicoides investigation. Out of 252 Ceratopogonidae collected, 67 were Culicoides. Eleven Culicoides spp. were identified, including Culicoides bolitinos, Culicoides grahami, Culicoides milnei, Culicoides fulvithorax, Culicoides neavei, Culicoides inornatipennis, Culicoides imicola, Culicoides schultzei, Culicoides accraensis, Culicoides kibatiensis, and Culicoides enderleini which were depicted for the first time in West Africa, showing new local faunal species. Morphologically, the different species identified were C. graham (n=8), C. milnei (n=17), C. neavei (n=5), C. imicola (n=6), C. fulvithorax (n=2), C. schultzei (n=3), C. accraensis (n=6), C. inornatipennis (n=8), C. bolitinos (n=3), C. kibatiensis (n=4), and C. enderleini (n=5). Using PCR, we observed that M. perstans was present in C. milnei, C. imicola, and C. inornatipennis. After the conventional PCR, the bands on gel electrophoresis are as shown in Figure 5. This comparison was statistically insignificant as the p-value was higher (p=0.08) than 0.05.
M. streptocerca was reported for the first time in Benin, and out of 88 blood samples, M. streptocerca was observed in 2 (2.27%) samples (Table 3). M. streptocerca was found only in the samples positive on microscope but negative for M. perstans on PCR. C. milnei was the most abundant Culicoides species observed in Benin (Figure 4). BLAST analysis was done for obtained sequences, matched with the M. perstans and M. streptocerca. All the sequences were submitted in the GenBank. The accession number for the sequence of M. perstans, M. streptocerca, and C. milnei are MW644567, MW675685, and MW665129, respectively.
Microscopy, PCR, and sequencing
Microfilariae tallies controlled by microscopy ran between 50 and 1800 microfilaria/ml. All samples underwent additional examination to uncover the presence or nonappearance of Wolbachia. The groupings of the obtained ITS amplicons of the 7 M. perstans (Figure 3) mono infections from Gabon are indistinguishable from the groupings of M. perstans beginning from Cameroon (EU272183) and Equatorial Guinea (EU272182). The collected grouping has been kept in the GenBank data set under KJ631373.
Distinguishing proof of the species as M. perstans was made on morphologic measures from thick spreads of fringe blood. The shortfall of accompanying Wuchereria bancrofti was affirmed by midnight blood filtration and negative tests (ICT™ and TropBio™) for flowing filarial antigen. Mp_ITS1 covered 79 bp, Culicoides spp. ITS1 with 41 bp, C. milnei ITS1 with 106 bp, the detection limit was observed at C 10-17 g/µl, SybrGreen dye, and hybridization probe.
DISCUSSION
These three species are known to cause human mansonellosis. However, other Mansonella species, for example, the chimpanzee parasite Mansonella rodhaini, can occasionally infect humans, and some other species can use humans as their definitive hosts (Orihel and Eberhard, 1998, Richard-Lenoble et al., 1988), which produce patent infections with circulating microfilariae. Also, M. ozzardi was originally the only known parasite to cause infections in humans, and the terms “mansonellosis” or “mansonelliasis,” until the mid-1980s, were used to refer only to the infections caused by M. ozzardi (Connor and Neafie, 1976; Linley et al., 1983; Marinkelle and German, 1970; Nelson, 1965; Shelley et al., 1980). These terms were revised after Orihel and Eberhard included M. perstans and M. streptocerca in the genus Mansonella (Eberhard and Orihel, 1984; Orihel and Eberhard, 1982).
As the three species have different geographical distributions, these species also have many different vectors; specifically, M. ozzardi has many variating vectors that transmit these filarial infections to primates, primarily humans. Many M. ozzardi vectors are from the black fly family, Simuliidae, for example, Simulium exiguum, Simulium amazonicum, Simulium argentiscutum, Simulium oyapockense, Simulium sanguineum, Simulium guyanensis, Simulium sanchezi, and Simulium minusculum. Other vectors of M. ozzardi are from flies or biting midges known as Ceratopogonidae. Examples of these vectors found in the literature include Culicoides insinuatus, Culicoides guttatus, Culicoides paraensis, Culicoides debilipalpis, Culicoides lahillei, Culicoides furens, Culicoides barbosai, Culicoides paraensis, Culicoides phlebotomus, and Leptoconops bequaerti (Crosskey, 1990; Lane and Crosskey, 2012; Linley et al., 1983; Shelley and Coscarón, 2001). Natural habitats and breeding sites of vectors also affect the distribution and consequent infection rates of the parasite. For example, M. ozzardi is transmitted by a range of Simulium and Culicoides spp. However, it appears that the parasite is most commonly transmitted by Simulium vectors of the Amazonicum species group and thus is distributed along the riverine breeding sites of these Simulium vectors (Shelley and Coscarón, 2001; Shelley et al., 2010). C. phlebotomus is the only known vector in Trinidad, which uses sandy beaches as its breeding site, and thus the parasite has a coastal distribution (Linley et al., 1983; Nathan, 1981). Such a PCR-based amplification of these filarial parasite using “species-specific target sequences” allows increased diagnostic sensitivity in comparison to traditional diagnostic methods, which include microscopy, and also allow reliable differentiation of samples taken from individuals living in co-endemic areas (Alhassan et al., 2015; Phillips et al., 2014; Ricciardi and Ndao, 2015; Shelley et al., 2001). A popular nested PCR uses a universal filariae primer to amplify a variable portion of filarial parasite ribosomal ITS1 DNA and allows for the subsequent identification of species based on the amplified fragment size (Tang et al., 2010). Nowadays, this rDNA ITS1 method has become a single-step diagnostic method by adapting it for real-time PCR (Moya et al., 2016; Thiele et al., 2016). PCR-restriction-fragment-length polymorphism (RFLP) is used to differentiate a broad range of filarial species using universal primers with a combination of the earlier techniques (Jiménez et al., 2011; Nuchprayoon et al., 2005).
This investigational research work is the first in Benin to decide upon the predominance of mansonellosis and its vectors’ dispersion. Our few outcomes infer that mansonellosis is profoundly predominant in Benin. Using PCR, our investigation shows that Mp is present in three species of the Culicoides genus, namely C. milnei, C. imicola, and C. inornatipennis. In this way, our examination presumes that these three Culicoides are liable for the transmission of mansonellosis in Benin. Our outcomes suggest that in Benin M. perstans, nematodes are exceptionally appropriated, and patients of M. ulcerans illness are adventitiously contaminated, so our investigation also proposes that this parasite should be considered in the Buruli ulcer patient’s administration.
Previous studies have reported that the vectors of M. perstans are biting midges (Culicoides) in most of the other endemic countries (Ta-Tang et al., 2018). For vector incrimination, the vector should be attracted to and must bite humans. It should be able also to carry the parasite. In determining the importance of a particular vector species in disease transmission, it is crucial to describe the disease transmission dynamics like mansonellosis. Culicoides midges are involved in the transmission of infective M. perstans larvae. This research work was thus conducted to determine the prevalence of various Mansonella spp. in Benin and the related vectors usually involved in the parasite transmission. Our research work is indeed aligned with the existing evidence in research that Mansonella spp., specifically M. perstans are present in various Culicoides spp., as after assessing the presence of M. perstans in Culicoides spp. samples obtained from patients in Benin using PCR, we inferred that M. perstans in Benin is carried and transmitted by Culicoides vectors of which three species have been highlighted.
Our microscopic observation of the 88 samples found that 15 (22.73%) females were positive for M. perstans, while 9 (40.90%) males were also positive for M. perstans. Based on PCR, 25 (37.87%) females and 11 (16.63%) males were observed positive for M. perstans. Higher prevalence was observed in males as compared to females. This might be due to more exposure of males to infection than females. These findings follow the previous studies in which male prevalence was reported more than females (Debrah et al., 2017). The vector abundance could clarify the high microfilaria distribution. Though, in Benin, the microfilaria vector has not been identified. We presume it might be due to missing microfilaria or misinterpretation during observation. The limited entomologic investigations conducted in mansonellosis-endemic areas show that the prevalence of Mansonella-infected wild-caught Culicoides is either meagre (0.8%) or nonexistent. These results contradict the high incidence of Mansonella microfilaremia in humans. Several studies have incriminated the vector species for M. perstans in endemic areas.
Additionally, this problem is complicated because, for tropical Culicoides spp. taxonomy, no work has been done in detail (Simonsen et al., 2011). Most intensive studies have been carried out in Cameroon and Nigeria. Recent studies in Cameroon have described C. milnei as the vector that transmits M. perstans (Debrah et al., 2017). Numerous previous studies have been carried out in various countries to determine the vector for M. perstans in endemic areas like Nigeria and Congo, but none has been carried out in Benin. Biting midges have had a dominant presence in rural areas because rural areas provide suitable conditions for vector-breeding, such as wet mud and leaf litter (Agbolade et al., 2006; Ta-Tang et al., 2018). Various landmarks such as bushes or the margin of the pond or the head of an animal, the abundance of cassava tubercules and banana plants, underbrush, and decayed matter of plants have been reported to support Culicoides’ breeding (Bakhoum et al., 2016). Previous studies have reported higher sensitivity of molecular methods than microscopy in detecting parasitemia and bacteremia (Parola et al., 2011; Andrews et al., 2005). In addition, real-time PCR assays for a few Culicoides spp. have been developed, as has a DNA microarray for identifying Culicoides species. The bites of Culicoides midges transfer M. perstans nematodes, but it is unclear if M. perstans-infected midges may also carry M. ulcerans. For example, skin penetration is necessary to establish the presence of M. ulcerans, as explained in the guinea pig experiment (Marsollier et al., 2007). However, such a test was not performed in our work, so we cannot establish a strong argument related to M. perstans and M. ulcerans co-infection. Persistent filarial diseases can cause immunological adjustment and influence the host’s reaction to intracellular microbes. Therefore, drives must be embraced to find minimal expense, touchy ways to deal with assistance, distinguish and group tainted people, survey treatment adequacy, and explain immunological connections between various filarial contaminations and different infections.
CONCLUSION
M. perstans has a high genetic diversity in different areas. The molecular identification method that we are developing is helping in epidemiology to provide a more unambiguous indication of the geographical distribution of the area of risk points where there is a high chance of having contact with the vector. Due to persistent filarial diseases, the host’s reaction to intracellular microbes and immunological reactions can be compromised. Efforts should be made to explore low-cost-efficient methods to address the issue, identify the infected persons, explore the available remedies, and investigate immunological connectedness between various filarial contaminations and different infections. The current study demonstrates that mansonellosis is profoundly predominant in Benin. PCR examination confirms the presence of M. perstans in C. milnei, C. imicola, and C. inornatipennis, suggesting that the three Culicoides are liable for the transmission of mansonellosis in Benin. The nucleotide sequence-based molecular identification technique developed here successfully identified midges and will be valuable for a better knowledge of Culicoides biting midge environments.
CONFLICT OF INTERESTS
The authors have not declared any conflict of interests.
REFERENCES
Alhassan A, Li Z, Poole CB, Carlow CKS (2015). Expanding the MDx toolbox for filarial diagnosis and surveillance. Trends in Parasitology 31(8):391-400. |
|
Agbolade O, Akinboye D, Ogunkolo O (2005). Loa loa and Mansonella perstans: neglected human infections that need control in Nigeria. African Journal of Biotechnology 4(13). |
|
Agbolade O-M, Akinboye DO, Olateju TM, Ayanbiyi OA, Kuloyo OO, Fenuga OO (2006). Biting of anthropophilic Culicoides fulvithorax (Diptera: Ceratopogonidae), a vector of Mansonella perstans in Nigeria. The Korean Journal of Parasitology 44(1):67. |
|
Altschul SF, Gish W, Miller W, Myers EW, Lipman DJ (1990). Basic local alignment search tool. Journal of Molecular Biology 215(3):403-410. |
|
Andrews L, Andersen RF, Webster D, Dunachie S, Walther RM, Bejon P, Hunt-Cooke A, Bergson G, Sanderson F, Hill AV (2005). Quantitative real-time polymerase chain reaction for malaria diagnosis and its use in malaria vaccine clinical trials. The American journal of Tropical Medicine 73(1):191-198. |
|
Bakhoum MT, Fall AG, Fall M, Bassene CK, Baldet T, Seck MT, Bouyer J, Garros C, Gimonneau G (2016). Insight on the larval habitat of Afrotropical Culicoides Latreille (Diptera: Ceratopogonidae) in the Niayes area of Senegal, West Africa. Parasites and Vectors 9(1):462-462. |
|
Bélard S, Gehringer C (2021). High Prevalence of Mansonella Species and Parasitic Coinfections in Gabon Calls for an End to the Neglect of Mansonella Research. Oxford University Press US. |
|
Chung M, Aluvathingal J, Bromley RE, Nadendla S, Fombad FF, Kien CA, Gandjui NV, Njouendou AJ, Ritter M, Sadzewicz L (2020). Complete mitochondrial genome sequence of Mansonella perstans. Microbiology Resource Announcements 9:e00490-20. |
|
Confalonieri UE, Dutra FRS (2014). Climate Change and Vector-Borne Diseases in Latin America. Environmental Deterioration and Human Health. Springer. |
|
Conte A, Giovannini A, Savini L, Goffredo M, Calistri P, Meiswinkel R (2003). The effect of climate on the presence of Culicoides imicola in Italy. Journal of Veterinary Medicine Series B 50:139-147. |
|
Crosskey RW (1990). The natural history of blackflies. John Wiley & Sons Ltd |
|
Da Silva LBT, Crainey JL, Da Silva TRR, Suwa UF, Vicente ACP, De Medeiros JF, Pessoa FAC, Luz SLB (2017). Molecular verification of New World Mansonella perstans parasitemias. Emerging infectious Diseases 23:545. |
|
Debrah LB, Nausch N, Opoku VS, Owusu W, Mubarik Y, Berko DA, Wanji S, Layland LE, Hoerauf A, Jacobsen M, Debrah AY, Phillips RO (2017). Epidemiology of Mansonella perstans in the middle belt of Ghana. Parasites and Vectors 10(1):1-8. |
|
Ferreira MU, Crainey JL, Luz SL (2021). Mansonella ozzardi. Trends in Parasitology 37(1):90-91. |
|
Gaillard CM, Pion SD, Hamou H, Sirima C, Bizet C, Lemarcis T, Rodrigues J, Esteban A, Peeters M, Ngole EM (2020). Detection of DNA of filariae closely related to Mansonella perstans in faecal samples from wild non-human primates from Cameroon and Gabon. Parasites and Vectors 13(1):1-13. |
|
Gehringer C, Kreidenweiss A, Flamen A, Antony JS, Grobusch MP, Bélard S (2014). Molecular evidence of Wolbachia endosymbiosis in Mansonella perstans in Gabon, Central Africa. The Journal of Infectious Diseases 210(10):1633-1638. |
|
Hall TA (1999). BioEdit: a user-friendly biological sequence alignment editor and analysis program for Windows 95/98/NT. In Nucleic acids Symposium Series 41(41):95-98. |
|
Jiménez M, González LM, Carranza C, Bailo B, Pérez-Ayala A, Muro A, Pérez-Arellano JL, Gárate T (2011). Detection and discrimination of Loa loa, Mansonella perstans and Wuchereria bancrofti by PCR-RFLP and nested-PCR of ribosomal DNA ITS1 region. Experimental Parasitology 127(1):282-286. |
|
Keiser PB, Coulibaly Y, Kubofcik J, Diallo AA, Klion AD, Traoré SF, Nutman TB (2008). Molecular identification of Wolbachia from the filarial nematode Mansonella perstans. Molecular and Biochemical Parasitology 160(2):123-128. |
|
Lane RP, Crosskey RW (2012). Medical insects and arachnids. Springer Science and Business Media. |
|
Laidoudi Y, Davoust B, Varloud M, Niang EHA, Fenollar F, Mediannikov O (2020). Development of a multiplex qPCR-based approach for the diagnosis of Dirofilaria immitis, D. repens and Acanthocheilonema reconditum. Parasites and Vectors 13(1):319. |
|
Lassen K, Liu Sy, Lizarzaburu C, Ríos R (1972). Preliminary report on the effect of selective application of propoxur on indoor surfaces in El Salvador. American Journal of Tropical Medicine and Hygiene 5:813-815. |
|
Linley JR, Hoch AL, Pinheiro FP (1983). Biting Midges (Diptera: Ceratopogonidae) and Human Health1. Journal of Medical Entomology 20(4):347-364. |
|
Marsollier L, Aubry J, Milon G, Brodin P (2007). Punaises aquatiques et transmission de Mycobacterium ulcerans. Médecine/Sciences 23(6-7):572-575. |
|
Matsuda K, Tsuji H, Asahara T, Matsumoto K, Takada T, Nomoto K (2009). Establishment of an analytical system for the human fecal microbiota, based on reverse transcription-quantitative PCR targeting of multicopy rRNA molecules. Applied and Environmental Microbiology 75(7):1961-1969. |
|
Mullis K, Faloona F, Scharf S, Saiki R, Horn G, Erlich H (1986). Specific enzymatic amplification of DNA in vitro: the polymerase chain reaction. Cold Spring Harbor symposia on quantitative biology, 1986. Cold Spring Harbor Laboratory Press pp. 263-273. |
|
Nathan MB (1981). Transmission of the human filarial parasite Mansonella Ozzardi by Culicoides phlebotomus (Williston) (Diptera: Ceratopogonidae) in coastal north Trinidad. Bulletin of Entomological Research 71(1):97-106. |
|
Nuchprayoon S, Junpee A, Poovorawan Y, Scott AL (2005). detection and differentiation of filarial parasites by universal primers and polymerase chain reaction-restriction fragment length polymorphism analysis. The American journal of tropical medicine and hygiene, 73(5):895-900. |
|
Parola P, Diatta G, Socolovschi C, Mediannikov O, Tall A, Bassene H, Trape JF, Raoult D (2011). Tick-borne relapsing fever borreliosis, rural Senegal. Emerging infectious diseases 17:883. |
|
Phillips RO, Frimpong M, Sarfo FS, Kretschmer B, Beissner M, Debrah A, Ampem-Amoako Y, Abass KM, Thompson W, Duah MS, Abotsi J, Adjei O, Fleischer B, Bretzel G, Wansbrough-Jones M, Jacobsen M (2014). Infection with Mansonella perstans Nematodes in Buruli Ulcer Patients, Ghana. Emerging Infectious Diseases 20(6):1000-1003. |
|
Raccurt C (2018). Mansonella ozzardi and its vectors in the New World: an update with emphasis on the current situation in Haiti. Journal of Helminthology 92(6):655-661. |
|
Ricciardi A, Ndao M (2015). Diagnosis of Parasitic Infections: What's Going On? SLAS Discovery 20(1):6-21. |
|
Shelley RM (1980). Revision of the milliped genus Pleuroloma (Polydesmida: Xystodesmidae). Canadian Journal of Zoology 58(2):129-168. |
|
Shelley AJ, Tang T-HT, López-Vélez R, Lanza M, Rubio JM, Luz SLB (2010). Nested PCR to detect and distinguish the sympatric filarial species Onchocerca volvulus, Mansonella ozzardi and Mansonella perstans in the Amazon Region. Memórias Do Instituto Oswaldo Cruz 105(6):823-828. |
|
Shelley A, Coscarón S (2001). Simuliid blackflies (Diptera: Simuliidae) and ceratopogonid midges (Diptera: Ceratopogonidae) as vectors of Mansonella ozzardi (Nematoda: Onchocercidae) in northern Argentina. Memórias do Instituto Oswaldo Cruz 96:451-458. |
|
Simonsen PE, Onapa AW, Asio SM (2011). Mansonella perstans filariasis in Africa. Acta Tropica 120:S109-S120. |
|
Tang T-HT, López-Vélez R, Lanza M, Shelley AJ, Rubio JM, Luz SLB (2010). Nested PCR to detect and distinguish the sympatric filarial species Onchocerca volvulus, Mansonella ozzardi and Mansonella perstans in the Amazon Region. Memórias Do Instituto Oswaldo Cruz, 105(6):823-828. |
|
Ta-Tang T-H, Crainey JL, Post RJ, Luz SL, Rubio JM (2018). Mansonellosis: current perspectives. Research and Reports in Tropical Medicine 9:9-24. |
|
Vijayvargiya P, Jeraldo PR, Thoendel MJ, Greenwood-Quaintance KE, Esquer GZ, Sohail MR, Chia N, Pritt BS, Patel R (2019). Application of metagenomic shotgun sequencing to detect vector-borne pathogens in clinical blood samples. |
|
Wanji S, Tayong DB, Ebai R, Opoku V, Kien CA, Ndongmo WPC, Njouendou AJ, Ghani RN, Ritter M, Debrah YA (2019). Update on the biology and ecology of Culicoides species in the South-West region of Cameroon with implications on the transmission of Mansonella perstans. Parasites and Vectors 12(1):1-12. |
Copyright © 2024 Author(s) retain the copyright of this article.
This article is published under the terms of the Creative Commons Attribution License 4.0