6 results on '"Andersen, Genevieve"'
Search Results
2. Multiple Functional Variants of IFIH1, a Gene Involved in Triggering Innate Immune Responses, Protect against Vitiligo
- Author
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Jin, Ying, Andersen, Genevieve H.L., Santorico, Stephanie A., and Spritz, Richard A.
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- 2017
- Full Text
- View/download PDF
3. Temporal phylogeography of Yersinia pestis in Madagascar: Insights into the long-term maintenance of plague.
- Author
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Vogler, Amy J., Andrianaivoarimanana, Voahangy, Telfer, Sandra, Hall, Carina M., Sahl, Jason W., Hepp, Crystal M., Centner, Heather, Andersen, Genevieve, Birdsell, Dawn N., Rahalison, Lila, Nottingham, Roxanne, Keim, Paul, Wagner, David M., and Rajerison, Minoarisoa
- Subjects
YERSINIA pestis ,PLAGUE ,COMMUNICABLE diseases ,GENOMES ,PHYLOGENY - 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. [ABSTRACT FROM AUTHOR]
- Published
- 2017
- Full Text
- View/download PDF
4. Diverse Genotypes of Yersinia pestis Caused Plague in Madagascar in 2007.
- Author
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Riehm, Julia M., Projahn, Michaela, Vogler, Amy J., Rajerison, Minoaerisoa, Andersen, Genevieve, Hall, Carina M., Zimmermann, Thomas, Soanandrasana, Rahelinirina, Andrianaivoarimanana, Voahangy, Straubinger, Reinhard K., Nottingham, Roxanne, Keim, Paul, Wagner, David M., and Scholz, Holger C.
- Subjects
YERSINIA pestis ,SINGLE nucleotide polymorphisms ,TANDEM repeats ,GENOTYPES ,MOLECULAR epidemiology - Abstract
Background: Yersinia pestis is the causative agent of human plague and is endemic in various African, Asian and American countries. In Madagascar, the disease represents a significant public health problem with hundreds of human cases a year. Unfortunately, poor infrastructure makes outbreak investigations challenging. Methodology/Principal Findings: DNA was extracted directly from 93 clinical samples from patients with a clinical diagnosis of plague in Madagascar in 2007. The extracted DNAs were then genotyped using three molecular genotyping methods, including, single nucleotide polymorphism (SNP) typing, multi-locus variable-number tandem repeat analysis (MLVA), and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) analysis. These methods provided increasing resolution, respectively. The results of these analyses revealed that, in 2007, ten molecular groups, two newly described here and eight previously identified, were responsible for causing human plague in geographically distinct areas of Madagascar. Conclusions/Significance: Plague in Madagascar is caused by numerous distinct types of Y. pestis. Genotyping method choice should be based upon the discriminatory power needed, expense, and available data for any desired comparisons. We conclude that genotyping should be a standard tool used in epidemiological investigations of plague outbreaks. Author Summary: Yersinia pestis is a highly pathogenic bacterium and the causative agent of human plague. It has caused three recognized pandemics and is a current human health problem in many countries of Africa, Asia and the Americas, including Madagascar. The pathogen cannot be eradicated from natural plague foci as it persists in various known and cryptic rodent reservoir species. Genotyping is a critical tool in understanding the molecular epidemiology and possible kinetics of plague. In the present study, we succeeded in extracting DNA and genotyping directly from human clinical samples from Madagascar. We applied three different methods, including single nucleotide polymorphism (SNP) typing, multi-locus variable-number tandem repeat (VNTR) analysis (MLVA), and Clustered Regularly Interspaced Short Palindromic Repeats (CRISPR) analysis. Relative to their discriminatory power, all three methods provided important genotype information useful for understanding the molecular epidemiology of the disease, revealing that multiple, distinct genotypes caused human plague in Madagascar within one year, 2007. [ABSTRACT FROM AUTHOR]
- Published
- 2015
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5. Genetics of Vitiligo.
- Author
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Spritz RA and Andersen GH
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- Adaptor Proteins, Signal Transducing genetics, Apoptosis Regulatory Proteins genetics, CTLA-4 Antigen genetics, Forkhead Transcription Factors genetics, Genetic Predisposition to Disease, HLA-A2 Antigen genetics, HLA-DR4 Antigen genetics, Humans, NLR Proteins, Protein Tyrosine Phosphatase, Non-Receptor Type 22 genetics, Receptor, Platelet-Derived Growth Factor alpha genetics, Apoptosis genetics, Autoimmunity genetics, Melanocytes metabolism, Vitiligo genetics
- Abstract
Vitiligo reflects simultaneous contributions of multiple genetic risk factors and environmental triggers. Genomewide association studies have discovered approximately 50 genetic loci contributing to vitiligo risk. At many vitiligo susceptibility loci, the relevant genes and DNA sequence variants are identified. Many encode proteins involved in immune regulation, several play roles in cellular apoptosis, and others regulate functions of melanocytes. Although many of the specific biologic mechanisms need elucidation, it is clear that vitiligo is an autoimmune disease involving a complex relationship between immune system programming and function, aspects of the melanocyte autoimmune target, and dysregulation of the immune response., (Copyright © 2016 Elsevier Inc. All rights reserved.)
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- 2017
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6. A decade of plague in Mahajanga, Madagascar: insights into the global maritime spread of pandemic plague.
- Author
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Vogler AJ, Chan F, Nottingham R, Andersen G, Drees K, Beckstrom-Sternberg SM, Wagner DM, Chanteau S, and Keim P
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- Animals, Cluster Analysis, DNA, Bacterial chemistry, DNA, Bacterial genetics, Genome, Bacterial, Genotype, Humans, Madagascar epidemiology, Minisatellite Repeats, Molecular Epidemiology, Molecular Sequence Data, Molecular Typing, Pandemics, Phylogeny, Polymorphism, Single Nucleotide, Sequence Analysis, DNA, Yersinia pestis isolation & purification, Plague epidemiology, Plague transmission, Yersinia pestis classification, Yersinia pestis genetics
- Abstract
Unlabelled: A cluster of human plague cases occurred in the seaport city of Mahajanga, Madagascar, from 1991 to 1999 following 62 years with no evidence of plague, which offered insights into plague pathogen dynamics in an urban environment. We analyzed a set of 44 Mahajanga isolates from this 9-year outbreak, as well as an additional 218 Malagasy isolates from the highland foci. We sequenced the genomes of four Mahajanga strains, performed whole-genome sequence single-nucleotide polymorphism (SNP) discovery on those strains, screened the discovered SNPs, and performed a high-resolution 43-locus multilocus variable-number tandem-repeat analysis of the isolate panel. Twenty-two new SNPs were identified and defined a new phylogenetic lineage among the Malagasy isolates. Phylogeographic analysis suggests that the Mahajanga lineage likely originated in the Ambositra district in the highlands, spread throughout the northern central highlands, and was then introduced into and became transiently established in Mahajanga. Although multiple transfers between the central highlands and Mahajanga occurred, there was a locally differentiating and dominant subpopulation that was primarily responsible for the 1991-to-1999 Mahajanga outbreaks. Phylotemporal analysis of this Mahajanga subpopulation revealed a cycling pattern of diversity generation and loss that occurred during and after each outbreak. This pattern is consistent with severe interseasonal genetic bottlenecks along with large seasonal population expansions. The ultimate extinction of plague pathogens in Mahajanga suggests that, in this environment, the plague pathogen niche is tenuous at best. However, the temporary large pathogen population expansion provides the means for plague pathogens to disperse and become ecologically established in more suitable nonurban environments., Importance: Maritime spread of plague led to the global dissemination of this disease and affected the course of human history. Multiple historical plague waves resulted in massive human mortalities in three classical plague pandemics: Justinian (6th and 7th centuries), Middle Ages (14th to 17th centuries), and third (mid-1800s to the present). Key to these events was the pathogen's entry into new lands by "plague ships" via seaport cities. Although initial disease outbreaks in ports were common, they were almost never sustained for long and plague pathogens survived only if they could become established in ecologically suitable habitats. Although plague pathogens' ability to invade port cities has been essential for intercontinental spread, these regions have not proven to be a suitable long-term niche. The disease dynamics in port cities such as Mahajanga are thus critical to plague pathogen amplification and dispersal into new suitable ecological niches for the observed global long-term maintenance of plague pathogens.
- Published
- 2013
- Full Text
- View/download PDF
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