Modélisation statistique des associations et des interactions entre des parasites transmis par des vecteurs, à partir de données issues d'études transversales

Multiparasitism and specifically statistical associations among parasites, have a strong influence on the ecology of parasites. This influence reinforced when parasites interact and thus modify their effect on hosts. However, the identification of associations and interactions between parasites is complex at the population level. Our aim was to model multi-parasite associations and interactions, in particular for parasites of medical, veterinary or agricultural importance. We first present a review of the literature on the different causes and consequences of multiparasitism and the methods and tools available to better understand the phenomena that generate them. In a second step we worked on the detection of multi-parasite associations. We developed a new approach « association screening » to statistically test the presence of multi-parasite associations on a global scale. We used this method to identify associations and to reveal precisely associated parasites in different host populations. Then, we focused on the study of interactions between parasites. We developed a model to identify the interactions between two vector-borne and persistent parasites in a host, using data from cross-sectional studies. One way to increase our capacity to detect parasite interactions in populations is the taking into account common risk factors. Taking into account interactions increases diagnosis, treatments and prevention of infectious diseases.Le multiparasitisme et surtout les associations qui en découlent, ont une grande influence sur l’écologie des parasites concernés. Elle est d’autant plus grande que les parasites peuvent interagir et ainsi modifier leurs effets sur les hôtes. Cependant, l’identification des associations et interactions de parasites est complexe au niveau populationnel. Notre objectif était de modéliser les associations et les interactions multiparasitaires, notamment dans le cadre des parasites d’importance médicale, vétérinaire ou agronomique. Nous avons tout d’abord réalisé une revue bibliographique sur les différentes causes et conséquences du multiparasitisme ainsi que sur les méthodes et outils disponibles pour comprendre les phénomènes qui le génèrent. Dans un second temps, nous nous sommes intéressés tout particulièrement à la détection des associations multiparasitaires. Nous avons développé une nouvelle méthode « de screening des associations » pour tester statistiquement la présence d’associations de parasites à une échelle globale. Nous avons utilisé cette méthode pour identifier les associations et pour révéler précisément les parasites associés au sein de diverses populations d’hôtes. Puis, nous avons étudié les interactions entre les parasites. Nous avons développé un modèle pour identifier les interactions entre deux parasites vectorisés et persistants chez un hôte, à partir de données issues d’études transversales. L’une des voies de progression de la connaissance sur les interactions est la prise en compte des facteurs de risque communs. La prise en compte des interactions contribue à améliorer le diagnostic, les traitements et la prévention des maladies infectieuses

Variation and correlations between sexual, asexual and natural enemy resistance life-history traits in a natural plant pathogen population

BackgroundUnderstanding the mechanisms by which diversity is maintained in pathogen populations is critical for epidemiological predictions. Life-history trade-offs have been proposed as a hypothesis for explaining long-term maintenance of variation in pathogen populations, yet the empirical evidence supporting trade-offs has remained mixed. This is in part due to the challenges of documenting successive pathogen life-history stages in many pathosystems. Moreover, little is understood of the role of natural enemies of pathogens on their life-history evolution.ResultsWe characterize life-history-trait variation and possible trade-offs in fungal pathogen Podosphaera plantaginis infecting the host plant Plantago lanceolata. We measured the timing of both asexual and sexual stages, as well as resistance to a hyperparasite of seven pathogen strains that vary in their prevalence in nature. We find significant variation among the strains in their life-history traits that constitute the infection cycle, but no evidence for trade-offs among pathogen development stages, apart from fast pathogen growth coninciding with fast hyperparasite growth. Also, the seemingly least fit pathogen strain was the most prevalent in the nature.ConclusionsWe conclude that in the nature environmental variation, and interactions with the antagonists of pathogens themselves may maintain variation in pathogen populations.Peer reviewe

Tick-borne pathogens of zoonotic and veterinary importance in Nigerian cattle

Additional file 1: Multiple infections by tick-borne pathogens according to age classes and overall number of animals. (PDF 19 kb)BACKGROUND : Ticks and tick-borne diseases undermine cattle fitness and productivity in the whole of sub-Saharan Africa, including Nigeria. In this West African country, cattle are challenged by numerous tick species, especially during the wet season. Consequently, several TBDs are known to be endemic in Nigerian cattle, including anaplasmosis, babesiosis, cowdriosis and theilerioris (by Theileria mutans and Theileria velifera). To date, all investigations on cattle TBDs in Nigeria have been based on cytological examinations and/or on serological methods. This study aimed to ascertain the occurrence of tick-borne pathogens of veterinary and zoonotic importance in cattle in Nigeria using molecular approaches. METHODS : In October 2008, 704 whole blood samples were collected from indigenous cattle in the Plateau State, Nigeria. Analysis for tick-borne pathogens was conducted by means of PCR-based reverse line blotting (RLB) and sequencing targeting a panel of five genera of microorganisms (i.e. Babesia, Theileria, Anaplasma, Ehrlichia and Rickettsia spp.). RESULTS : In total, 561/704 (82.6 %) animals were found infected, with 465 (69.6 %) of them being infected by two or more microorganisms, with up to 77 possible combinations of pathogens detected. Theileria mutans was the most prevalent microorganism (66.3 %), followed by Theileria velifera (52.4 %), Theileria taurotragi (39.5 %), Anaplasma marginale (39.1 %), Anaplasma sp. (Omatjenne) (34.7 %), Babesia bigemina (7.9 %), Anaplasma centrale (6.3 %), Anaplasma platys (3.9 %), Rickettsia massiliae (3.5 %), Babesia bovis (2.0 %) and Ehrlichia ruminantium (1.1 %). Calves were found significantly less infected than juvenile and adult cattle. CONCLUSIONS : This study provides updated, molecular-based information on cattle TBDs in Nigeria. The molecular approach employed allowed the diagnosis of numerous positive cases including carrier statuses, multiple infections and novel pathogen detections within the indigenous cattle population. Moreover, the RLB method here described enabled the detection of veterinary agents not only pertaining to bovine health, including also those of zoonotic importance. The high prevalence recorded for T. mutans, T. velifera, A. marginale, T. taurotragi and Anaplasma sp. (Omatjenne), suggests they may be endemically established in Nigeria, whereas the lower prevalence recorded for other microorganisms (i.e. A. centrale and B. bovis) highlights a less stable epidemiological scenario, requiring further investigations.The UK’s Biotechnology and Biological Sciences Research Council (BBSRC) under the ‘Combating Infectious Diseases in Livestock for International Development’ (CIDLID) scheme, and the European Union’s Seventh Framework Program (FP7/2007–2013) under grant agreement n° 221948, Integrated Control of Neglected Zoonoses (ICONZ).http://www.parasitesandvectors.comam2016Veterinary Tropical Disease

Statistical modelling of associations and interactions between vector borne parasites, using data from cross-sectional studies

Le multiparasitisme et surtout les associations qui en découlent, ont une grande influence sur l’écologie des parasites concernés. Elle est d’autant plus grande que les parasites peuvent interagir et ainsi modifier leurs effets sur les hôtes. Cependant, l’identification des associations et interactions de parasites est complexe au niveau populationnel. Notre objectif était de modéliser les associations et les interactions multiparasitaires, notamment dans le cadre des parasites d’importance médicale, vétérinaire ou agronomique. Nous avons tout d’abord réalisé une revue bibliographique sur les différentes causes et conséquences du multiparasitisme ainsi que sur les méthodes et outils disponibles pour comprendre les phénomènes qui le génèrent. Dans un second temps, nous nous sommes intéressés tout particulièrement à la détection des associations multiparasitaires. Nous avons développé une nouvelle méthode « de screening des associations » pour tester statistiquement la présence d’associations de parasites à une échelle globale. Nous avons utilisé cette méthode pour identifier les associations et pour révéler précisément les parasites associés au sein de diverses populations d’hôtes. Puis, nous avons étudié les interactions entre les parasites. Nous avons développé un modèle pour identifier les interactions entre deux parasites vectorisés et persistants chez un hôte, à partir de données issues d’études transversales. L’une des voies de progression de la connaissance sur les interactions est la prise en compte des facteurs de risque communs. La prise en compte des interactions contribue à améliorer le diagnostic, les traitements et la prévention des maladies infectieuses.Multiparasitism and specifically statistical associations among parasites, have a strong influence on the ecology of parasites. This influence reinforced when parasites interact and thus modify their effect on hosts. However, the identification of associations and interactions between parasites is complex at the population level. Our aim was to model multi-parasite associations and interactions, in particular for parasites of medical, veterinary or agricultural importance. We first present a review of the literature on the different causes and consequences of multiparasitism and the methods and tools available to better understand the phenomena that generate them. In a second step we worked on the detection of multi-parasite associations. We developed a new approach « association screening » to statistically test the presence of multi-parasite associations on a global scale. We used this method to identify associations and to reveal precisely associated parasites in different host populations. Then, we focused on the study of interactions between parasites. We developed a model to identify the interactions between two vector-borne and persistent parasites in a host, using data from cross-sectional studies. One way to increase our capacity to detect parasite interactions in populations is the taking into account common risk factors. Taking into account interactions increases diagnosis, treatments and prevention of infectious diseases

Data from: Role of temperature and coinfection in mediating pathogen life-history traits

Understanding processes maintaining variation in pathogen life-history traits is a key challenge in disease biology, and of importance for predicting when and where risks of disease emergence are highest. Pathogens are expected to encounter tremendous levels of variation in their environment – both abiotic and biotic – and this variation may promote maintenance of variation in pathogen populations through space and time. Here, we measure life-history traits of an obligate fungal pathogen at both asexual and sexual stages under both single infection and coinfection along a temperature gradient. We find that temperature had a significant effect on all measured life-history traits while coinfection only had a significant effect on the number of sexual resting structures produced. The effect of temperature on life-history traits was both direct as well as mediated through a genotype-by-temperature interaction. We conclude that pathogen life-history traits vary in their sensitivity to abiotic and biotic variation in the environment

Powdery mildew coinfections at different temperatures

Powdery mildew (Podosphaera plantaginis) inoculations on leaves of Plantago lanceolata on petri dishes at different temperatures with and without coinfection. Timing of sporulation of asexual spores and germination of sexual spores. Viability of sexual spores. File contains also the metadata

Data from: Role of temperature and coinfection in mediating pathogen life-history traits

Understanding processes maintaining variation in pathogen life-history traits is a key challenge in disease biology, and of importance for predicting when and where risks of disease emergence are highest. Pathogens are expected to encounter tremendous levels of variation in their environment – both abiotic and biotic – and this variation may promote maintenance of variation in pathogen populations through space and time. Here, we measure life-history traits of an obligate fungal pathogen at both asexual and sexual stages under both single infection and coinfection along a temperature gradient. We find that temperature had a significant effect on all measured life-history traits while coinfection only had a significant effect on the number of sexual resting structures produced. The effect of temperature on life-history traits was both direct as well as mediated through a genotype-by-temperature interaction. We conclude that pathogen life-history traits vary in their sensitivity to abiotic and biotic variation in the environment

Statistical modelling of associations and interactions between vector borne parasites, using data from cross-sectional studies

National audienc

The importance of multiparasitism: examining the consequences of co-infections for human and animal health

Most parasites co-occur with other parasites, although the importance of such multiparasitism has only recently been recognised. Co-infections may result when hosts are independently infected by different parasites at the same time or when interactions among parasite species facilitate co-occurrence. Such interactions can have important repercussions on human or animal health because they can alter host susceptibility, infection duration, transmission risks, and clinical symptoms. These interactions may be synergistic or antagonistic and thus produce diverse effects in infected humans and animals. Interactions among parasites strongly influence parasite dynamics and therefore play a major role in structuring parasite populations (both within and among hosts) as well as host populations. However, several methodological challenges remain when it comes to detecting parasite interactions. The goal of this review is to summarise current knowledge on the causes and consequences of multiparasitism and to discuss the different methods and tools that researchers have developed to study the factors that lead to multiparasitism. It also identifies new research directions to pursue

Models to evaluate associations and interactions between pathogens

International audienc