Sonja Lečić, Thomas M. Wolfe, Animesh Ghosh, Serdar Satar, Camilla Souza Beraldo, Emily Smith, Jason J. Dombroskie, Emily Jernigan, Glen Ray Hood, Hannes Schuler, Christian Stauffer
{"title":"空间变化的沃尔巴克氏体频率揭示了最近从欧洲引入北美的一种农业害虫的入侵起源","authors":"Sonja Lečić, Thomas M. Wolfe, Animesh Ghosh, Serdar Satar, Camilla Souza Beraldo, Emily Smith, Jason J. Dombroskie, Emily Jernigan, Glen Ray Hood, Hannes Schuler, Christian Stauffer","doi":"10.1111/eva.70016","DOIUrl":null,"url":null,"abstract":"<p>The introduction of non-native species across the world represents a major global challenge. Retracing invasion origin is an important first step in understanding the invasion process, often requiring detailed sampling within the native range. Insect species frequently host <i>Wolbachia</i>, a widespread endosymbiotic bacterium that manipulates host reproduction to increase infected female fitness. Here, we draw on the spatial variation in infection frequencies of an actively spreading <i>Wolbachia</i> strain <i>w</i>Cer2 to investigate the invasion origin of the European cherry fruit fly, <i>Rhagoletis cerasi.</i> This pest of cherries was introduced from Europe to North America within the last decade. First, we screen the introduced fly population for the presence of <i>Wolbachia</i>. The introduced populations lack the <i>w</i>Cer2 strain and the strongly associated mitochondrial haplotype, suggesting strain absence due to founder effects with invading individuals originating from <i>w</i>Cer2-uninfected native population(s). To narrow down geographic regions of invasion origin, we perform spatial interpolation of the <i>w</i>Cer2 infection frequency across the native range and predict the infection frequency in unsampled regions. For this, we use an extensive dataset of <i>R. cerasi</i> infection covering 238 populations across Europe over 25 years, complemented with 14 additional populations analyzed for this study. We find that <i>R. cerasi</i> was unlikely introduced from <i>w</i>Cer2-infected populations in Central and Western Europe. We propose <i>w</i>Cer2-uninfected populations from Eastern Europe and the Mediterranean region as the most likely candidates for the invasion origin. This work utilizes <i>Wolbachia</i> as an indirect instrument to provide insights into the invasion source of <i>R. cerasi</i> in North America, revealing yet another application for this multifaceted heritable endosymbiont. Given the prevalence of biological invasions, rapidly uncovering invasion origins gives fundamental insights into how invasive species adapt to new environments.</p>","PeriodicalId":168,"journal":{"name":"Evolutionary Applications","volume":"17 9","pages":""},"PeriodicalIF":3.5000,"publicationDate":"2024-09-20","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1111/eva.70016","citationCount":"0","resultStr":"{\"title\":\"Spatially Varying Wolbachia Frequencies Reveal the Invasion Origin of an Agricultural Pest Recently Introduced From Europe to North America\",\"authors\":\"Sonja Lečić, Thomas M. Wolfe, Animesh Ghosh, Serdar Satar, Camilla Souza Beraldo, Emily Smith, Jason J. Dombroskie, Emily Jernigan, Glen Ray Hood, Hannes Schuler, Christian Stauffer\",\"doi\":\"10.1111/eva.70016\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>The introduction of non-native species across the world represents a major global challenge. Retracing invasion origin is an important first step in understanding the invasion process, often requiring detailed sampling within the native range. Insect species frequently host <i>Wolbachia</i>, a widespread endosymbiotic bacterium that manipulates host reproduction to increase infected female fitness. Here, we draw on the spatial variation in infection frequencies of an actively spreading <i>Wolbachia</i> strain <i>w</i>Cer2 to investigate the invasion origin of the European cherry fruit fly, <i>Rhagoletis cerasi.</i> This pest of cherries was introduced from Europe to North America within the last decade. First, we screen the introduced fly population for the presence of <i>Wolbachia</i>. The introduced populations lack the <i>w</i>Cer2 strain and the strongly associated mitochondrial haplotype, suggesting strain absence due to founder effects with invading individuals originating from <i>w</i>Cer2-uninfected native population(s). To narrow down geographic regions of invasion origin, we perform spatial interpolation of the <i>w</i>Cer2 infection frequency across the native range and predict the infection frequency in unsampled regions. For this, we use an extensive dataset of <i>R. cerasi</i> infection covering 238 populations across Europe over 25 years, complemented with 14 additional populations analyzed for this study. We find that <i>R. cerasi</i> was unlikely introduced from <i>w</i>Cer2-infected populations in Central and Western Europe. We propose <i>w</i>Cer2-uninfected populations from Eastern Europe and the Mediterranean region as the most likely candidates for the invasion origin. This work utilizes <i>Wolbachia</i> as an indirect instrument to provide insights into the invasion source of <i>R. cerasi</i> in North America, revealing yet another application for this multifaceted heritable endosymbiont. 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Spatially Varying Wolbachia Frequencies Reveal the Invasion Origin of an Agricultural Pest Recently Introduced From Europe to North America
The introduction of non-native species across the world represents a major global challenge. Retracing invasion origin is an important first step in understanding the invasion process, often requiring detailed sampling within the native range. Insect species frequently host Wolbachia, a widespread endosymbiotic bacterium that manipulates host reproduction to increase infected female fitness. Here, we draw on the spatial variation in infection frequencies of an actively spreading Wolbachia strain wCer2 to investigate the invasion origin of the European cherry fruit fly, Rhagoletis cerasi. This pest of cherries was introduced from Europe to North America within the last decade. First, we screen the introduced fly population for the presence of Wolbachia. The introduced populations lack the wCer2 strain and the strongly associated mitochondrial haplotype, suggesting strain absence due to founder effects with invading individuals originating from wCer2-uninfected native population(s). To narrow down geographic regions of invasion origin, we perform spatial interpolation of the wCer2 infection frequency across the native range and predict the infection frequency in unsampled regions. For this, we use an extensive dataset of R. cerasi infection covering 238 populations across Europe over 25 years, complemented with 14 additional populations analyzed for this study. We find that R. cerasi was unlikely introduced from wCer2-infected populations in Central and Western Europe. We propose wCer2-uninfected populations from Eastern Europe and the Mediterranean region as the most likely candidates for the invasion origin. This work utilizes Wolbachia as an indirect instrument to provide insights into the invasion source of R. cerasi in North America, revealing yet another application for this multifaceted heritable endosymbiont. Given the prevalence of biological invasions, rapidly uncovering invasion origins gives fundamental insights into how invasive species adapt to new environments.
期刊介绍:
Evolutionary Applications is a fully peer reviewed open access journal. It publishes papers that utilize concepts from evolutionary biology to address biological questions of health, social and economic relevance. Papers are expected to employ evolutionary concepts or methods to make contributions to areas such as (but not limited to): medicine, agriculture, forestry, exploitation and management (fisheries and wildlife), aquaculture, conservation biology, environmental sciences (including climate change and invasion biology), microbiology, and toxicology. All taxonomic groups are covered from microbes, fungi, plants and animals. In order to better serve the community, we also now strongly encourage submissions of papers making use of modern molecular and genetic methods (population and functional genomics, transcriptomics, proteomics, epigenetics, quantitative genetics, association and linkage mapping) to address important questions in any of these disciplines and in an applied evolutionary framework. Theoretical, empirical, synthesis or perspective papers are welcome.