Colonization of Grande Comore Island by a lineage of Rhipicephalus appendiculatus ticks

<p>Abstract</p> <p>Background</p> <p>Union of the Comoros suffered a severe East Coast Fever epidemic in 2004. <it>Rhipicephalus appendiculatus </it>was probably involved in pathogen transmission as this competent tick species, although previously absent from Comoros, was sampled on 4 animals on one geographical site during the epidemic. We carried out an entomological survey on all three islands of Union of the Comoros to establish cattle tick species distribution with a special emphasis on <it>R. appendiculatus</it>. We investigated <it>R. appendiculatus </it>intraspecific diversity as this species has been previously shown to be split off into two main cytoplasmic lineages with different ecology, physiology and vectorial competence. This survey also included sampling of live cattle imported from Tanzania to investigate the possibility of tick introduction through animal trade.</p> <p>Results</p> <p>Our data show that Comoros cattle are infested with <it>Amblyomma variegatum</it>, <it>Rhipicephalus microplus </it>and <it>R. appendiculatus</it>. This latter species has established throughout Grande Comore but is absent from Anjouan and Moheli. Interestingly, 43 out of the 47 sequenced <it>R. appendiculatus </it>ticks belong to one single highly competent lineage while ticks from the other lineage where only found on imported cattle or on cattle parked at the vicinity of the harbor. At last, 2 ticks identified as <it>R. evertsi</it>, a species so far virtually absent on Comoros, were sampled on imported cattle.</p> <p>Conclusions</p> <p>This survey shows that importation of live cattle is clearly a source of vector introduction in Comoros. The wide distribution of one highly competent <it>R. appendiculatus </it>lineage on Grande Comore, together with the absence of this species on the two neighbouring islands is in accordance with the rapid and disastrous spread of East Coast Fever epidemics on Grande Comore Island only. Whether the other <it>R. appendiculatus </it>lineage as well as <it>R. evertsi </it>species will succeed in establishing permanently on Grande Comore needs to be monitored.</p

Accurate identification of Culicidae at aquatic developmental stages by MALDI-TOF MS profiling

International audienceBACKGROUND: The identification of mosquito vectors is generally based on morphological criteria, but for aquatic stages, morphological characteristics may be missing, leading to incomplete or incorrect identification. The high cost of molecular biology techniques requires the development of an alternative strategy. In the last decade, matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) profiling has proved to be efficient for arthropod identification at the species level.METHODS:To investigate the usefulness of MALDI-TOF MS for the identification of mosquitoes at aquatic stages, optimizations of sample preparation, diet, body parts and storage conditions were tested. Protein extracts of whole specimens from second larval stage to pupae were selected for the creation of a reference spectra database. The database included a total of 95 laboratory-reared specimens of 6 mosquito species, including Anopheles gambiae (S form), Anopheles coluzzi (M form), Culex pipiens pipiens, Culex pipiens molestus, Aedes aegypti and 2 colonies of Aedes albopictus.RESULTS:The present study revealed that whole specimens at aquatic stages produced reproducible and singular spectra according to the mosquito species. Moreover, MS protein profiles appeared weakly affected by the diet provided. Despite the low diversity of some MS profiles, notably for cryptic species, clustering analyses correctly classified all specimens tested at the species level followed by the clustering of early vs. late aquatic developmental stages. Discriminant mass peaks were recorded for the 6 mosquito species analyzed at larval stage 3 and the pupal stage. Querying against the reference spectra database of 149 new specimens at different aquatic stages from the 6 mosquito species revealed that 147 specimens were correctly identified at the species level and that early and late developmental stages were also distinguished.CONCLUSIONS:The present work highlights that MALDI-TOF MS profiling may be useful for the rapid and reliable identification of mosquito species at aquatic stages. With this proteomic tool, it becomes now conceivable to survey mosquito breeding sites prior to the mosquitoes' emergence and to adapt anti-vectorial measures according to the mosquito fauna detected

Matrix-assisted laser desorption ionization--time of flight mass spectrometry: an emerging tool for the rapid identification of mosquito vectors.

BACKGROUND: The identification of mosquito vectors is typically based on morphological characteristics using morphological keys of determination, which requires entomological expertise and training. The use of protein profiling by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF-MS), which is increasingly being used for the routine identification of bacteria, has recently emerged for arthropod identification. METHODS: To investigate the usefulness of MALDI-TOF-MS as a mosquito identification tool, we tested protein extracts made from mosquito legs to create a database of reference spectra. The database included a total of 129 laboratory-reared and field-caught mosquito specimens consisting of 20 species, including 4 Aedes spp., 9 Anopheles spp., 4 Culex spp., Lutzia tigripes, Orthopodomyia reunionensis and Mansonia uniformis. For the validation study, blind tests were performed with 76 specimens consisting of 1 to 4 individuals per species. A cluster analysis was carried out using the MALDI-Biotyper and some spectra from all mosquito species tested. RESULTS: Biomarker mass sets containing 22 and 43 masses have been detected from 100 specimens of the Anopheles, Aedes and Culex species. By carrying out 3 blind tests, we achieved the identification of mosquito vectors at the species level, including the differentiation of An. gambiae complex, which is possible using MALDI-TOF-MS with 1.8 as the cut-off identification score. A cluster analysis performed with all available mosquito species showed that MALDI-Biotyper can distinguish between specimens at the subspecies level, as demonstrated for An gambiae M and S, but this method cannot yet be considered a reliable tool for the phylogenetic study of mosquito species. CONCLUSIONS: We confirmed that even without any specific expertise, MALDI-TOF-MS profiling of mosquito leg protein extracts can be used for the rapid identification of mosquito vectors. Therefore, MALDI-TOF-MS is an alternative, efficient and inexpensive tool that can accurately identify mosquitoes collected in the field during entomological surveys

Identification of arthropods vectors and associated micro-organisms by MALDI-TOF MS

Les arthropodes vecteurs sont hématophages et peuvent assurer la transmission biologique active d'un agent pathogène responsable de maladies humaines ou animales. La lutte anti-vectorielle et la surveillance épidémiologique des vecteurs sont essentielles dans la stratégie de lutte contre les maladies vectorielles. Disposer d'outils d'identification précis, fiable et rapides des vecteurs et des pathogènes associés est indispensable. Ainsi dans ce projet nous avons évalué l'utilisation du MALDI-TOF MS pour identifier les arthropodes vecteurs ainsi que la détection des pathogènes associés. La première partie de notre travail consistait à utiliser MALDI TOF pour identifier les tiques, moustiques et les puces. Nous avons déterminé quelle partie du spécimen permettait d'obtenir une reproductibilité des spectres et une identification correcte par des tests à l'aveugle après création d'une base de données de référence. La deuxième partie consistait à utiliser le MALDI-TOF MS pour détecter des Rcikettsies associés aux tiques dont Rickettsia conorii et R. slovaca, deux pathogènes humains transmis respectivement par Rhipicephalus sanguineus et Dermacentor marginatus. Des variations spectrales étaient obtenues entre les spécimens infectés et non infectés, avec des masses spécifiques liés à l'infection des tiques par les rickettsies. La technique d'identification était validée par des tests à l'aveugle. Les résultats obtenus permettent de conclure que le MALDI TOF pourra être utilisé dans l'avenir pour identifier les tiques prélevées chez des patients, les arthropodes vecteurs lors des enquêtes entomologiques et préciser la prévalence d'infection de ces arthropodes.Arthropods are vectors bloodsucking and can ensure the active biological transmission of a pathogen responsible of human or veterinary diseases. The vector control and vectors epidemiological surveillance are essential in the strategy against the vectors-borne diseases. Accurate, reliable and rapid identification of vectors and associated pathogens are essential. Thus, in this project we evaluated the use of MALDI-TOF MS for the arthropods vectors identification as well as for the detection of associated pathogens. This proteomics technology emerged since few years ago and is currently used in routine for bacteria identification in many microbiology laboratories. In the first part of our work, we used the MALDI TOF to identify the tick, mosquito and flea species. For each arthropod, we determined which part allowed obtaining reproducible spectra by MALDI TOF and correct identification by blind test, after reference database creation. The second part consisted to use the MALDI-TOF MS to detect the associated Rickettsia in ticks including Rickettsia conorii and R. slovaca, two human pathogens transmitted by Rhipicephalus sanguineus and respectively Dermacentors marginatus. The spectral variations were obtained between infected and non infected specimens with specific masses related to the tick infection by Rickettsia. The identification technique of not or infected ticks was validated by blind tests. The obtained results allowed concluding that the MALDI-TOF MS could be used in the future to identify the ticks removed from patient, the arthropods vectors and during entomological survey and determine the prevalence of infection of these arthropods

Emerging tools for identification of arthropod vectors

International audienceThe rapid and reliable identification of arthropod vector species is an essential component of the fight against vector-borne diseases. However, owing to the lack of entomological expertise required for the morphological identification method, development of alternative and complementary tools is needed. This review describes the main methods used for arthropod identification, focusing on the emergence of protein profiling using MALDI-TOF MS technology. Sample preparation, analysis of reproducibility, database creation and blind tests for controlling accuracy of this tool for arthropod identification are described. The advantages and limitations of the MALDI-TOF MS method are illustrated by emphasizing different hematophagous arthropods, including mosquitoes and ticks, the top two main vectors of infectious diseases

New data regarding distribution of cattle ticks in the south-western Indian Ocean islands

International audienceRecent studies have produced new insight into the origin and distribution of some cattle ticks in the south-western Indian Ocean islands. Rhipicephalus appendiculatus, introduced from Tanzania in 2002, is now well established on Grande Comore but has not yet reached the other islands of the archipelago (Moheli, Anjouan and Mayotte). Only one of the two clades identified in Africa has settled so far. Amblyomma variegatum, which was not supposed to be able to persist in the Antananarivo region (1300 m) nor in other Malagasy regions of high altitude without regular introductions of ticks by infested cattle, is now endemic as a general rule up to 1600 m although other regions of lower altitude (1400 m) are still free of the tick. This species remains confined in a small area of the west coast on La Reunion Island. On the contrary, Hyalomma dromedarii could not settle on Madagascar where it was introduced in 2008 and Rhipicephalus evertsi evertsi is not yet present in Grande Comore despite regular introductions by infested cattle from Tanzania. A phylogeographic approach has been carried out at an intra-specific level for A. variegatum. This study has led to the identification of two main lineages, one covering all species distribution and one restricted to East Africa and the Indian Ocean area. These two lineages are in sympatry in Madagascar where a high genetic diversity has been described, whereas a lower genetic diversity is observed on other islands. These results seem to agree with the historical data concerning the introduction of the tick in the Indian Ocean area

Detection of Rickettsia spp in Ticks by MALDI-TOF MS

International audienceBackground Matrix Assisted Laser Desorption/Ionization Time-of-Flight Mass Spectrometry (MALDI-TOF MS) has been shown to be an effective tool for the rapid identification of arthropods, including tick vectors of human diseases. Methodology/Principal Findings The objective of the present study was to evaluate the use of MALDI-TOF MS to identify tick species, and to determine the presence of rickettsia pathogens in the infected Ticks. Rhipicephalus sanguineus and Dermacentor marginatus Ticks infected or not by R. conorii conorii or R. slovaca, respectively, were used as experimental models. The MS profiles generated from protein extracts prepared from tick legs exhibited mass peaks that distinguished the infected and uninfected Ticks, and successfully discriminated the Rickettsia spp. A blind test was performed using Ticks that were laboratory-reared, collected in the field or removed from patients and infected or not by Rickettsia spp. A query against our in-lab arthropod MS reference database revealed that the species and infection status of all Ticks were correctly identified at the species and infection status levels. Conclusions/Significance Taken together, the present work demonstrates the utility of MALDI-TOF MS for a dual identification of tick species and intracellular bacteria. Therefore, MALDI-TOF MS is a relevant tool for the accurate detection of Rickettsia spp in Ticks for both field monitoring and entomological diagnosis. The present work offers new perspectives for the monitoring of other vector borne diseases that present public health concerns