Your search keyword '"Rahalison L"' showing total 6 results

1. A Non-Stationary Relationship between Global Climate Phenomena and Human Plague Incidence in Madagascar

Author

Minoarison Rajerison, Andrew P. Morse, Sandra Telfer, Katharina Kreppel, Cyril Caminade, Lila Rahalison, Matthew Baylis, Kreppel, Katharina, Caminade, Cyril, Telfer, Sandra, Rajerison, M, Rahalison, L, Morse, Andy, and Baylis, Matthew

Subjects

Bacterial Diseases, Yersinia Pestis, Epidemiology, Global climate, Climate, RC955-962, Plant Science, Global Health, Plague (disease), Microbiology, Infectious Disease Epidemiology, Arctic medicine. Tropical medicine, Madagascar, Medicine and Health Sciences, Humans, Public and Occupational Health, Precipitation, Temporal scales, Microbial Pathogens, El Nino-Southern Oscillation, Plague, biology, Incidence, Ecology and Environmental Sciences, Public Health, Environmental and Occupational Health, Biology and Life Sciences, Plant Pathology, Tropical Diseases, biology.organism_classification, Yersinia, Bacterial Pathogens, Infectious Diseases, El Niño Southern Oscillation, Geography, Yersinia pestis, Medical Microbiology, Climatology, Earth Sciences, Seasons, Indian Ocean Dipole, Local disease, Public aspects of medicine, RA1-1270, Research Article, Neglected Tropical Diseases

Abstract

Background Plague, a zoonosis caused by Yersinia pestis, is found in Asia and the Americas, but predominantly in Africa, with the island of Madagascar reporting almost one third of human cases worldwide. Plague's occurrence is affected by local climate factors which in turn are influenced by large-scale climate phenomena such as the El Niño Southern Oscillation (ENSO). The effects of ENSO on regional climate are often enhanced or reduced by a second large-scale climate phenomenon, the Indian Ocean Dipole (IOD). It is known that ENSO and the IOD interact as drivers of disease. Yet the impacts of these phenomena in driving plague dynamics via their effect on regional climate, and specifically contributing to the foci of transmission on Madagascar, are unknown. Here we present the first analysis of the effects of ENSO and IOD on plague in Madagascar. Methodology/principal findings We use a forty-eight year monthly time-series of reported human plague cases from 1960 to 2008. Using wavelet analysis, we show that over the last fifty years there have been complex non-stationary associations between ENSO/IOD and the dynamics of plague in Madagascar. We demonstrate that ENSO and IOD influence temperature in Madagascar and that temperature and plague cycles are associated. The effects on plague appear to be mediated more by temperature, but precipitation also undoubtedly influences plague in Madagascar. Our results confirm a relationship between plague anomalies and an increase in the intensity of ENSO events and precipitation. Conclusions/significance This work widens the understanding of how climate factors acting over different temporal scales can combine to drive local disease dynamics. Given the association of increasing ENSO strength and plague anomalies in Madagascar it may in future be possible to forecast plague outbreaks in Madagascar. The study gives insight into the complex and changing relationship between climate factors and plague in Madagascar., Author Summary Plague is a vector-borne bacterial infection with rodents and their fleas as its principal hosts. Transmission to humans occurs via the bite of an infected flea. In the highlands of Madagascar, plague is endemic and more than one hundred human cases are reported every year. Global climate is known to affect many infectious diseases and has been shown to affect plague incidence in other areas of the world. The ENSO and the IOD are global climate drivers affecting rainfall and temperature in Madagascar. Our study investigates the effect of global climate drivers on human plague incidence on the island. We found a link between ENSO, IOD, temperature and precipitation and plague incidence throughout the 48-year time-series although it was not constant over time. The correlation between ENSO and plague turned from weakly positive to strongly negative and then to positive, and the association with the IOD became stronger with time. We demonstrate that during periods of high ENSO intensity, plague incidence is likely to increase via ENSO's impact on temperature and precipitation. This shows that climate indices can be a tool to help predict human plague incidence.

Published

2014

2. Temporal phylogeography of Yersinia pestis in Madagascar: Insights into the long-term maintenance of plague.

Author

Vogler AJ, Andrianaivoarimanana V, Telfer S, Hall CM, Sahl JW, Hepp CM, Centner H, Andersen G, Birdsell DN, Rahalison L, Nottingham R, Keim P, Wagner DM, and Rajerison M

Subjects

Endemic Diseases, Genome, Bacterial, Genotype, Humans, Madagascar epidemiology, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Spatio-Temporal Analysis, Yersinia pestis genetics, Phylogeography, Plague epidemiology, Plague microbiology, Yersinia pestis classification, Yersinia pestis isolation & purification

Abstract

Background: Yersinia pestis appears to be maintained in multiple, geographically separate, and phylogenetically distinct subpopulations within the highlands of Madagascar. However, the dynamics of these locally differentiated subpopulations through time are mostly unknown. To address that gap and further inform our understanding of plague epidemiology, we investigated the phylogeography of Y. pestis in Madagascar over an 18 year period., Methodology/principal Findings: We generated whole genome sequences for 31 strains and discovered new SNPs that we used in conjunction with previously identified SNPs and variable-number tandem repeats (VNTRs) to genotype 773 Malagasy Y. pestis samples from 1995 to 2012. We mapped the locations where samples were obtained on a fine geographic scale to examine phylogeographic patterns through time. We identified 18 geographically separate and phylogenetically distinct subpopulations that display spatial and temporal stability, persisting in the same locations over a period of almost two decades. We found that geographic areas with higher levels of topographical relief are associated with greater levels of phylogenetic diversity and that sampling frequency can vary considerably among subpopulations and from year to year. We also found evidence of various Y. pestis dispersal events, including over long distances, but no evidence that any dispersal events resulted in successful establishment of a transferred genotype in a new location during the examined time period., Conclusions/significance: Our analysis suggests that persistent endemic cycles of Y. pestis transmission within local areas are responsible for the long term maintenance of plague in Madagascar, rather than repeated episodes of wide scale epidemic spread. Landscape likely plays a role in maintaining Y. pestis subpopulations in Madagascar, with increased topographical relief associated with increased levels of localized differentiation. Local ecological factors likely affect the dynamics of individual subpopulations and the associated likelihood of observing human plague cases in a given year in a particular location.

Published

2017

3. A non-stationary relationship between global climate phenomena and human plague incidence in Madagascar.

Author

Kreppel KS, Caminade C, Telfer S, Rajerison M, Rahalison L, Morse A, and Baylis M

Subjects

Climate, El Nino-Southern Oscillation, Humans, Incidence, Madagascar epidemiology, Seasons, Plague epidemiology

Abstract

Background: Plague, a zoonosis caused by Yersinia pestis, is found in Asia and the Americas, but predominantly in Africa, with the island of Madagascar reporting almost one third of human cases worldwide. Plague's occurrence is affected by local climate factors which in turn are influenced by large-scale climate phenomena such as the El Niño Southern Oscillation (ENSO). The effects of ENSO on regional climate are often enhanced or reduced by a second large-scale climate phenomenon, the Indian Ocean Dipole (IOD). It is known that ENSO and the IOD interact as drivers of disease. Yet the impacts of these phenomena in driving plague dynamics via their effect on regional climate, and specifically contributing to the foci of transmission on Madagascar, are unknown. Here we present the first analysis of the effects of ENSO and IOD on plague in Madagascar., Methodology/principal Findings: We use a forty-eight year monthly time-series of reported human plague cases from 1960 to 2008. Using wavelet analysis, we show that over the last fifty years there have been complex non-stationary associations between ENSO/IOD and the dynamics of plague in Madagascar. We demonstrate that ENSO and IOD influence temperature in Madagascar and that temperature and plague cycles are associated. The effects on plague appear to be mediated more by temperature, but precipitation also undoubtedly influences plague in Madagascar. Our results confirm a relationship between plague anomalies and an increase in the intensity of ENSO events and precipitation., Conclusions/significance: This work widens the understanding of how climate factors acting over different temporal scales can combine to drive local disease dynamics. Given the association of increasing ENSO strength and plague anomalies in Madagascar it may in future be possible to forecast plague outbreaks in Madagascar. The study gives insight into the complex and changing relationship between climate factors and plague in Madagascar.

Published

2014

4. Plague circulation and population genetics of the reservoir Rattus rattus: the influence of topographic relief on the distribution of the disease within the Madagascan focus.

Author

Brouat C, Rahelinirina S, Loiseau A, Rahalison L, Rajerison M, Laffly D, Handschumacher P, and Duplantier JM

Subjects

Animals, Genetics, Population, Madagascar epidemiology, Plague epidemiology, Plague microbiology, Population Density, Rats, Rodent Diseases microbiology, Seroepidemiologic Studies, Yersinia pestis genetics, Genetic Variation, Plague veterinary, Rodent Diseases epidemiology, Topography, Medical, Yersinia pestis classification, Yersinia pestis isolation & purification

Abstract

Background: Landscape may affect the distribution of infectious diseases by influencing the population density and dispersal of hosts and vectors. Plague (Yersinia pestis infection) is a highly virulent, re-emerging disease, the ecology of which has been scarcely studied in Africa. Human seroprevalence data for the major plague focus of Madagascar suggest that plague spreads heterogeneously across the landscape as a function of the relief. Plague is primarily a disease of rodents. We therefore investigated the relationship between disease distribution and the population genetic structure of the black rat, Rattus rattus, the main reservoir of plague in Madagascar., Methodology/principal Findings: We conducted a comparative study of plague seroprevalence and genetic structure (15 microsatellite markers) in rat populations from four geographic areas differing in topology, each covering about 150-200 km(2) within the Madagascan plague focus. The seroprevalence levels in the rat populations mimicked those previously reported for humans. As expected, rat populations clearly displayed a more marked genetic structure with increasing relief. However, the relationship between seroprevalence data and genetic structure differs between areas, suggesting that plague distribution is not related everywhere to the effective dispersal of rats., Conclusions/significance: Genetic diversity estimates suggested that plague epizootics had only a weak impact on rat population sizes. In the highlands of Madagascar, plague dissemination cannot be accounted for solely by the effective dispersal of the reservoir. Human social activities may also be involved in spreading the disease in rat and human populations.

Published

2013

5. Phylogeography and molecular epidemiology of Yersinia pestis in Madagascar.

Author

Vogler AJ, Chan F, Wagner DM, Roumagnac P, Lee J, Nera R, Eppinger M, Ravel J, Rahalison L, Rasoamanana BW, Beckstrom-Sternberg SM, Achtman M, Chanteau S, and Keim P

Subjects

Analysis of Variance, Cluster Analysis, DNA, Bacterial chemistry, Humans, Madagascar epidemiology, Minisatellite Repeats genetics, Molecular Epidemiology methods, Molecular Typing, Phylogeography, Polymerase Chain Reaction, Polymorphism, Single Nucleotide genetics, Plague epidemiology, Plague microbiology, Yersinia pestis genetics

Abstract

Background: Plague was introduced to Madagascar in 1898 and continues to be a significant human health problem. It exists mainly in the central highlands, but in the 1990s was reintroduced to the port city of Mahajanga, where it caused extensive human outbreaks. Despite its prevalence, the phylogeography and molecular epidemiology of Y. pestis in Madagascar has been difficult to study due to the great genetic similarity among isolates. We examine island-wide geographic-genetic patterns based upon whole-genome discovery of SNPs, SNP genotyping and hypervariable variable-number tandem repeat (VNTR) loci to gain insight into the maintenance and spread of Y. pestis in Madagascar., Methodology/principal Findings: We analyzed a set of 262 Malagasy isolates using a set of 56 SNPs and a 43-locus multi-locus VNTR analysis (MLVA) system. We then analyzed the geographic distribution of the subclades and identified patterns related to the maintenance and spread of plague in Madagascar. We find relatively high levels of VNTR diversity in addition to several SNP differences. We identify two major groups, Groups I and II, which are subsequently divided into 11 and 4 subclades, respectively. Y. pestis appears to be maintained in several geographically separate subpopulations. There is also evidence for multiple long distance transfers of Y. pestis, likely human mediated. Such transfers have resulted in the reintroduction and establishment of plague in the port city of Mahajanga, where there is evidence for multiple transfers both from and to the central highlands., Conclusions/significance: The maintenance and spread of Y. pestis in Madagascar is a dynamic and highly active process that relies on the natural cycle between the primary host, the black rat, and its flea vectors as well as human activity.

Published

2011

6. Development and evaluation of two simple, rapid immunochromatographic tests for the detection of Yersinia pestis antibodies in humans and reservoirs.

Author

Rajerison M, Dartevelle S, Ralafiarisoa LA, Bitam I, Dinh TN, Andrianaivoarimanana V, Nato F, and Rahalison L

Subjects

Animals, Bacterial Proteins immunology, Humans, Immunoglobulin G blood, Immunoglobulin M blood, Rodentia, Sensitivity and Specificity, Antibodies, Bacterial blood, Immunoassay methods, Plague diagnosis, Plague veterinary, Yersinia pestis immunology

Abstract

Background: Tools for plague diagnosis and surveillance are not always available and affordable in most of the countries affected by the disease. Yersinia pestis isolation for confirmation is time-consuming and difficult to perform under field conditions. Serologic tests like ELISA require specific equipments not always available in developing countries. In addition to the existing rapid test for antigen detection, a rapid serodiagnostic assay may be useful for plague control., Methods/principal Findings: We developed two rapid immunochromatography-based tests for the detection of antibodies directed against F1 antigen of Y. pestis. The first test, SIgT, which detects total Ig (IgT) anti-F1 in several species (S) (human and reservoirs), was developed in order to have for the field use an alternative method to ELISA. The performance of the SIgT test was evaluated with samples from humans and animals for which ELISA was used to determine the presumptive diagnosis of plague. SIgT test detected anti-F1 Ig antibodies in humans with a sensitivity of 84.6% (95% CI: 0.76-0.94) and a specificity of 98% (95% CI: 0.96-1). In evaluation of samples from rodents and other small mammals, the SlgT test had a sensitivity of 87.8% (95% CI: 0.80-0.94) and a specificity of 90.3% (95% CI: 0.86-0.93). Improved performance was obtained with samples from dogs, a sentinel animal, with a sensitivity of 93% (95% CI: 0.82-1) and a specificity of 98% (95% CI: 0.95-1.01). The second test, HIgM, which detects human (H) IgM anti-F1, was developed in order to have another method for plague diagnosis. Its sensitivity was 83% (95% CI: 0.75-0.90) and its specificity about 100%., Conclusion/significance: The SIgT test is of importance for surveillance because it can detect Ig antibodies in a range of reservoir species. The HIgM test could facilitate the diagnosis of plague during outbreaks, particularly when only a single serum sample is available.

Published

2009