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2. Unveiling candidate genes for metabolic resistance to malathion in Aedes albopictus through RNA sequencing-based transcriptome profiling.

Author

Huang, Xinyue, Kaufman, Phillip E., Athrey, Giridhar N., Fredregill, Chris, and Slotman, Michel A.

Subjects
AEDES albopictus, MALATHION, DENGUE hemorrhagic fever, WEST Nile fever, GENE families, METABOLIC detoxification, AEDES aegypti, MOSQUITO vectors
Abstract

Aedes albopictus, also known as the Asian tiger mosquito, is indigenous to the tropical forests of Southeast Asia. Ae. albopictus is expanding across the globe at alarming rates, raising concern over the transmission of mosquito-borne diseases, such as dengue, West Nile fever, yellow fever, and chikungunya fever. Since Ae. albopictus was reported in Houston (Harris County, Texas) in 1985, this species has rapidly expanded to at least 32 states across the United States. Public health efforts aimed at controlling Ae. albopictus, including surveillance and adulticide spraying operations, occur regularly in Harris County. Despite rotation of insecticides to mitigate the development of resistance, multiple mosquito species including Culex quinquefasciatus and Aedes aegypti in Harris County show organophosphate and pyrethroid resistance. Aedes albopictus shows relatively low resistance levels as compared to Ae. aegypti, but kdr-mutation and the expression of detoxification genes have been reported in Ae. albopictus populations elsewhere. To identify potential candidate detoxification genes contributing to metabolic resistance, we used RNA sequencing of field-collected malathion-resistant and malathion-susceptible, and laboratory-maintained susceptible colonies of Ae. albopictus by comparing the relative expression of transcripts from three major detoxification superfamilies involved in malathion resistance due to metabolic detoxification. Between these groups, we identified 12 candidate malathion resistance genes and among these, most genes correlated with metabolic detoxification of malathion, including four P450 and one alpha esterase. Our results reveal the metabolic detoxification and potential cuticular-based resistance mechanisms associated with malathion resistance in Ae. albopictus in Harris County, Texas. Author summary: The Asian tiger mosquito, Aedes albopictus, is an invasive species rapidly expanding worldwide. It is the main vector for several arboviruses, including dengue virus, Zika virus, and chikungunya virus. These viral diseases pose a substantial threat to global public health. Ae. albopictus has developed resistance to insecticides such as malathion, making its control more challenging. To uncover the genetic basis of this resistance, we conducted a study using RNA sequencing-based transcriptome profiling. In this study, we obtained gene expression patterns in malathion-resistant and susceptible mosquitoes. The transcriptomic information allowed us to identify potential key genes in detoxification gene families associated with metabolic resistance to malathion. Our discovery provides insights into the molecular mechanisms behind malathion resistance in Ae. albopictus. Our research not only contributes to the understanding of mosquito biology and control but also highlights the future direction for continued efforts in developing innovative strategies to mitigate rapid development of insecticide resistance in Ae. albopictus. [ABSTRACT FROM AUTHOR]

Published
2024
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5. Genomic investigation refutes record of most diverged avian hybrid

Author

Alfieri, James M., Johnson, Taryn, Linderholm, Anna, Blackmon, Heath, Athrey, Giridhar N., Alfieri, James M., Johnson, Taryn, Linderholm, Anna, Blackmon, Heath, and Athrey, Giridhar N.

Abstract

The most diverged avian hybrid that has been documented (Numida meleagris × Penelope superciliaris) was reported in 1957. This identification has yet to be confirmed, and like most contemporary studies of hybridization, the identification was based on phenotype, which can be misleading. In this study, we sequenced the specimen in question and performed analyses to validate the specimen's parentage. We extracted DNA from the specimen in a dedicated ancient DNA facility and performed whole-genome short-read sequencing. We used BLAST to find Galliformes sequences similar to the hybrid specimen reads. We found that the proportion of BLAST hits mapped overwhelmingly to two species, N. meleagris and Gallus gallus. Additionally, we constructed phylogenies using avian orthologs and parsed the species placed as sister to the hybrid. Again, the hybrid specimen was placed as a sister to N. meleagris and G. gallus. Despite not being a hybrid between N. meleagris and P. superciliaris, the hybrid still represents the most diverged avian hybrid confirmed with genetic data. In addition to correcting the “record” of the most diverged avian hybrid, these findings support recent assertions that morphological and behavioral-based identifications of avian hybrids can be error-prone. Consequently, this study serves as a cautionary tale to researchers of hybridization.

Published
2023
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6. Fourth Report on Chicken Genes and Chromosomes 2022

Author

Smith, Jacqueline, Alfieri, James M., Anthony, Nick, Arensburger, Peter, Athrey, Giridhar N., Balacco, Jennifer, Balic, Adam, Bardou, Philippe, Barela, Paul, Bigot, Yves, Blackmon, Heath, Borodin, Pavel M., Carroll, Rachel, Casono, Meya C., Charles, Mathieu, Cheng, Hans, Chiodi, Maddie, Cigan, Lacey, Coghill, Lyndon M., Crooijmans, Richard, Das, Neelabja, Davey, Sean, Davidian, Asya, Degalez, Fabien, Dekkers, Jack M., Derks, Martijn, Diack, Abigail B., Djikeng, Appolinaire, Drechsler, Yvonne, Dyomin, Alexander, Fedrigo, Olivier, Fiddaman, Steven R., Formenti, Giulio, Frantz, Laurent A.F., Fulton, Janet E., Gaginskaya, Elena, Galkina, Svetlana, Gallardo, Rodrigo A., Geibel, Johannes, Gheyas, Almas A., Godinez, Cyrill John P., Goodell, Ashton, Graves, Jennifer A.M., Griffin, Darren K., Haase, Bettina, Han, Jian Lin, Hanotte, Olivier, Henderson, Lindsay J., Hou, Zhuo Cheng, Howe, Kerstin, Huynh, Lan, Ilatsia, Evans, Jarvis, Erich D., Johnson, Sarah M., Kaufman, Jim, Kelly, Terra, Kemp, Steve, Kern, Colin, Keroack, Jacob H., Klopp, Christophe, Lagarrigue, Sandrine, Lamont, Susan J., Lange, Margaret, Lanke, Anika, Larkin, Denis M., Larson, Greger, Layos, John King N., Lebrasseur, Ophélie, Malinovskaya, Lyubov P., Martin, Rebecca J., Cerezo, Maria Luisa Martin, Mason, Andrew S., McCarthy, Fiona M., McGrew, Michael J., Mountcastle, Jacquelyn, Muhonja, Christine Kamidi, Muir, William, Muret, Kévin, Murphy, Terence D., Ng'ang'a, Ismael, Nishibori, Masahide, O'Connor, Rebecca E., Ogugo, Moses, Okimoto, Ron, Ouko, Ochieng, Patel, Hardip R., Perini, Francesco, Pigozzi, María Ines, Potter, Krista C., Price, Peter D., Reimer, Christian, Rice, Edward S., Rocos, Nicolas, Rogers, Thea F., Saelao, Perot, Schauer, Jens, Schnabel, Robert D., Schneider, Valerie A., Simianer, Henner, Smith, Adrian, Stevens, Mark P., Stiers, Kyle, Tiambo, Christian Keambou, Tixier-Boichard, Michele, Torgasheva, Anna A., Tracey, Alan, Tregaskes, Clive A., Vervelde, Lonneke, Wang, Ying, Warren, Wesley C., Waters, Paul D., Webb, David, Weigend, Steffen, Wolc, Anna, Wright, Alison E., Wright, Dominic, Wu, Zhou, Yamagata, Masahito, Yang, Chentao, Yin, Zhong Tao, Young, Michelle C., Zhang, Guojie, Zhao, Bingru, Zhou, Huaijun, Smith, Jacqueline, Alfieri, James M., Anthony, Nick, Arensburger, Peter, Athrey, Giridhar N., Balacco, Jennifer, Balic, Adam, Bardou, Philippe, Barela, Paul, Bigot, Yves, Blackmon, Heath, Borodin, Pavel M., Carroll, Rachel, Casono, Meya C., Charles, Mathieu, Cheng, Hans, Chiodi, Maddie, Cigan, Lacey, Coghill, Lyndon M., Crooijmans, Richard, Das, Neelabja, Davey, Sean, Davidian, Asya, Degalez, Fabien, Dekkers, Jack M., Derks, Martijn, Diack, Abigail B., Djikeng, Appolinaire, Drechsler, Yvonne, Dyomin, Alexander, Fedrigo, Olivier, Fiddaman, Steven R., Formenti, Giulio, Frantz, Laurent A.F., Fulton, Janet E., Gaginskaya, Elena, Galkina, Svetlana, Gallardo, Rodrigo A., Geibel, Johannes, Gheyas, Almas A., Godinez, Cyrill John P., Goodell, Ashton, Graves, Jennifer A.M., Griffin, Darren K., Haase, Bettina, Han, Jian Lin, Hanotte, Olivier, Henderson, Lindsay J., Hou, Zhuo Cheng, Howe, Kerstin, Huynh, Lan, Ilatsia, Evans, Jarvis, Erich D., Johnson, Sarah M., Kaufman, Jim, Kelly, Terra, Kemp, Steve, Kern, Colin, Keroack, Jacob H., Klopp, Christophe, Lagarrigue, Sandrine, Lamont, Susan J., Lange, Margaret, Lanke, Anika, Larkin, Denis M., Larson, Greger, Layos, John King N., Lebrasseur, Ophélie, Malinovskaya, Lyubov P., Martin, Rebecca J., Cerezo, Maria Luisa Martin, Mason, Andrew S., McCarthy, Fiona M., McGrew, Michael J., Mountcastle, Jacquelyn, Muhonja, Christine Kamidi, Muir, William, Muret, Kévin, Murphy, Terence D., Ng'ang'a, Ismael, Nishibori, Masahide, O'Connor, Rebecca E., Ogugo, Moses, Okimoto, Ron, Ouko, Ochieng, Patel, Hardip R., Perini, Francesco, Pigozzi, María Ines, Potter, Krista C., Price, Peter D., Reimer, Christian, Rice, Edward S., Rocos, Nicolas, Rogers, Thea F., Saelao, Perot, Schauer, Jens, Schnabel, Robert D., Schneider, Valerie A., Simianer, Henner, Smith, Adrian, Stevens, Mark P., Stiers, Kyle, Tiambo, Christian Keambou, Tixier-Boichard, Michele, Torgasheva, Anna A., Tracey, Alan, Tregaskes, Clive A., Vervelde, Lonneke, Wang, Ying, Warren, Wesley C., Waters, Paul D., Webb, David, Weigend, Steffen, Wolc, Anna, Wright, Alison E., Wright, Dominic, Wu, Zhou, Yamagata, Masahito, Yang, Chentao, Yin, Zhong Tao, Young, Michelle C., Zhang, Guojie, Zhao, Bingru, and Zhou, Huaijun

Abstract

Chicken Genomic Diversity consortium: large-scale genomics to unravel the origins and adaptations of chickens

Published
2023

7. Domestication is associated with increased interspecific hybrid compatibility in landfowl (order: Galliformes).

Author

Alfieri, James M, Hingoranee, Reina, Athrey, Giridhar N, and Blackmon, Heath

Subjects
REPRODUCTIVE isolation, GALLIFORMES, EXTREME value theory, PHYLOGENY, AVICULTURE, MORPHOLOGY
Abstract

Some species are able to hybridize despite being exceptionally diverged. The causes of this variation in accumulation of reproductive isolation remain poorly understood, and domestication as an impetus or hindrance to reproductive isolation remains to be characterized. In this study, we investigated the role of divergence time, domestication, and mismatches in morphology, habitat, and clutch size among hybridizing species on reproductive isolation in the bird order Galliformes. We compiled and analyzed hybridization occurrences from literature and recorded measures of postzygotic reproductive isolation. We used a text-mining approach leveraging a historical aviculture magazine to quantify the degree of domestication across species. We obtained divergence time, morphology, habitat, and clutch size data from open sources. We found 123 species pairs (involving 77 species) with known offspring fertility (sterile, only males fertile, or both sexes fertile). We found that divergence time and clutch size were significant predictors of reproductive isolation (McFadden's Pseudo -R 2 = 0.59), but not habitat or morphological mismatch. Perhaps most interesting, we found a significant relationship between domestication and reproductive compatibility after correcting for phylogeny, removing extreme values, and addressing potential biases (F 1,74 = 5.43, R 2 = 0.06, P -value = 0.02). We speculate that the genetic architecture and disruption in selective reproductive regimes associated with domestication may impact reproductive isolation, causing domesticated species to be more reproductively labile. [ABSTRACT FROM AUTHOR]

Published
2024
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8. Effective population size of Culex quinquefasciatus under insecticide-based vector management and following Hurricane Harvey in Harris County, Texas.

Author

Xinyue Huang, Athrey, Giridhar N., Kaufman, Phillip E., Fredregill, Chris, and Slotman, Michel A.

Subjects
INSECTICIDE resistance, HURRICANE Harvey, 2017, CULEX quinquefasciatus, WEST Nile fever, MOSQUITO control, LANDFALL
Abstract

Introduction: Culex quinquefasciatus is a mosquito species of significant public health importance due to its ability to transmit multiple pathogens that can cause mosquito-borne diseases, such as West Nile fever and St. Louis encephalitis. In Harris County, Texas, Cx. quinquefasciatus is a common vector species and is subjected to insecticide-based management by the Harris County Public Health Department. However, insecticide resistance in mosquitoes has increased rapidly worldwide and raises concerns about maintaining the effectiveness of vector control approaches. This concern is highly relevant in Texas, with its humid subtropical climate along the Gulf Coast that provides suitable habitat for Cx. quinquefasciatus and other mosquito species that are known disease vectors. Therefore, there is an urgent and ongoing need to monitor the effectiveness of current vector control programs. Methods: In this study, we evaluated the impact of vector control approaches by estimating the effective population size of Cx. quinquefasciatus in Harris County. We applied Approximate Bayesian Computation to microsatellite data to estimate effective population size. We collected Cx. quinquefasciatus samples from two mosquito control operation areas; 415 and 802, during routine vector monitoring in 2016 and 2017. No county mosquito control operations were applied at area 415 in 2016 and 2017, whereas extensive adulticide spraying operations were in effect at area 802 during the summer of 2016. We collected data for eighteen microsatellite markers for 713 and 723 mosquitoes at eight timepoints from 2016 to 2017 in areas 415 and 802, respectively. We also investigated the impact of Hurricane Harvey’s landfall in the Houston area in August of 2017 on Cx. quinquefasciatus population fluctuation. Results: We found that the bottleneck scenario was the most probable historical scenario describing the impact of the winter season at area 415 and area 802, with the highest posterior probability of 0.9167 and 0.4966, respectively. We also detected an expansion event following Hurricane Harvey at area 802, showing a 3.03-fold increase in 2017. Discussion: Although we did not detect significant effects of vector control interventions, we found considerable influences of the winter season and a major hurricane on the effective population size of Cx. quinquefasciatus. The fluctuations in effective population size in both areas showed a significant seasonal pattern. Additionally, the significant population expansion following Hurricane Harvey in 2017 supports the necessity for post-hurricane vectorcontrol interventions. [ABSTRACT FROM AUTHOR]

Published
2023
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9. Chicken Genomic Diversity consortium: large-scale genomics to unravel the origins and adaptations of chickens

Author

Fiddaman, Steven R, Klopp, Christophe, Charles, Mathieu, Bardou, Philippe, Lebrasseur, Ophélie, Derks, Martijn F. L., Schauer, Jens, Reimer, Christian, Geibel, Johannes, Gheyas, Almas, Smith, Adrian L., Schnabel, Robert, Cerezo, Maria Luisa Martin, Nishibori, Masahide, Godinez, Cyrill John P., Layos, John King N., Alfieri, James M., Blackmon, Heath, Athrey, Giridhar N., Larson, Greger, Ng’ang’a, Ismael, Muir, William, Lange, Margaret, Wright, Dominic, Cheng, Hans H, Simianer, Henner, Weigend, Steffen, Warren, Wesley, Crooijmans, Richard P. M. A., Hanotte, Olivier, Smith, Jacqueline, Tixier-Boichard, Michele, and Frantz, Laurent Af

Abstract

On October 25-26, 2019, a satellite meeting devoted to the preparation of a Chicken Genome Diversity Consortium was organised after the 11th European Symposium of Poultry Genetics in Prague. Researchers involved in chicken genomics from Europe, Africa and China, discussed the objectives of such a consortium with some presenting their data. However, the technical aspects of how to share and jointly analyse the data were not finalized, nor was the funding model for the cost of data storage and computation. In 2021, an opportunity arose with the call for projects of the SuperMUC computing cluster of the Leibniz-Rechenzentrum in Germany. A new consortium of scientists re-launched the discussion to establish a project with the aim to explore how the high-throughput genomics age can be harnessed to answer evolutionary questions surrounding the chicken. The FARMGENOMIC project (23826) was accepted for funding in autumn 2021, gathering around 20 members from 10 institutions in Europe, North America, and Africa. This newly formed Chicken Genomic Diversity consortium brings together members from a variety of disciplines, including genomics, palaeogenetics, animal breeding, immunology, organismal biology, evolutionary biology, and archaeology. Central to the consortium are the concepts of inclusivity and openness – all data are to be made available to all members of the consortium, and later distributed to the wider community, and collaborations between groups are fostered and actively encouraged. It is hoped this state-of-the-art resource, curated in-house by bioinformaticians, will enable the community to answer previously intractable questions in chicken evolution.

Published
2023
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10. Fourth Report on Chicken Genes and Chromosomes 2022

Author

Smith, Jacqueline, primary, Alfieri, James M., additional, Anthony, Nick, additional, Arensburger, Peter, additional, Athrey, Giridhar N., additional, Balacco, Jennifer, additional, Balic, Adam, additional, Bardou, Philippe, additional, Barela, Paul, additional, Bigot, Yves, additional, Blackmon, Heath, additional, Borodin, Pavel M., additional, Carroll, Rachel, additional, Casono, Meya C., additional, Charles, Mathieu, additional, Cheng, Hans, additional, Chiodi, Maddie, additional, Cigan, Lacey, additional, Coghill, Lyndon M., additional, Crooijmans, Richard, additional, Das, Neelabja, additional, Davey, Sean, additional, Davidian, Asya, additional, Degalez, Fabien, additional, Dekkers, Jack M., additional, Derks, Martijn, additional, Diack, Abigail B., additional, Djikeng, Appolinaire, additional, Drechsler, Yvonne, additional, Dyomin, Alexander, additional, Fedrigo, Olivier, additional, Fiddaman, Steven R., additional, Formenti, Giulio, additional, Frantz, Laurent A.F., additional, Fulton, Janet E., additional, Gaginskaya, Elena, additional, Galkina, Svetlana, additional, Gallardo, Rodrigo A., additional, Geibel, Johannes, additional, Gheyas, Almas, additional, Godinez, Cyrill John P., additional, Goodell, Ashton, additional, Graves, Jennifer A. M., additional, Griffin, Daren K., additional, Haase, Bettina, additional, Han, Jian-Lin, additional, Hanotte, Olivier, additional, Henderson, Lindsay J., additional, Hou, Zhuo-Cheng, additional, Howe, Kerstin, additional, Huynh, Lan, additional, Ilatsia, Evans, additional, Jarvis, Erich, additional, Johnson, Sarah M., additional, Kaufman, Jim, additional, Kelly, Terra, additional, Kemp, Steve, additional, Kern, Colin, additional, Keroack, Jacob H., additional, Klopp, Christophe, additional, Lagarrigue, Sandrine, additional, Lamont, Susan J., additional, Lange, Margaret, additional, Lanke, Anika, additional, Larkin, Denis M., additional, Larson, Greger, additional, Layos, John King N., additional, Lebrasseur, Ophélie, additional, Malinovskaya, Lyubov P., additional, Martin, Rebecca J., additional, Martin Cerezo, Maria Luisa, additional, Mason, Andrew S., additional, McCarthy, Fiona M., additional, McGrew, Michael J., additional, Mountcastle, Jacquelyn, additional, Muhonja, Christine Kamidi, additional, Muir, William, additional, Muret, Kévin, additional, Murphy, Terence, additional, Ng’ang’a, Ismael, additional, Nishibori, Masahide, additional, O’Connor, Rebecca E., additional, Ogugo, Moses, additional, Okimoto, Ron, additional, Ouko, Ochieng, additional, Patel, Hardip R., additional, Perini, Francesco, additional, Pigozzi, María Ines, additional, Potter, Krista C., additional, Price, Peter D., additional, Reimer, Christian, additional, Rice, Edward S., additional, Rocos, Nicolas, additional, Rogers, Thea F., additional, Saelao, Perot, additional, Schauer, Jens, additional, Schnabel, Robert, additional, Schneider, Valerie, additional, Simianer, Henner, additional, Smith, Adrian, additional, Stevens, Mark P., additional, Stiers, Kyle, additional, Tiambo, Christian Keambou, additional, Tixier-Boichard, Michele, additional, Torgasheva, Anna A., additional, Tracey, Alan, additional, Tregaskes, Clive A., additional, Vervelde, Lonneke, additional, Wang, Ying, additional, Warren, Wesley C., additional, Waters, Paul D., additional, Webb, David, additional, Weigend, Steffen, additional, Wolc, Anna, additional, Wright, Alison E., additional, Wright, Dominic, additional, Wu, Zhou, additional, Yamagata, Masahito, additional, Yang, Chentao, additional, Yin, Zhong-Tao, additional, Young, Michelle C., additional, Zhang, Guojie, additional, Zhao, Bingru, additional, and Zhou, Huaijun, additional

Published
2023
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13. Fourth Report on Chicken Genes and Chromosomes 2022.

Author

Smith, Jacqueline, Alfieri, James M., Anthony, Nick, Arensburger, Peter, Athrey, Giridhar N., Balacco, Jennifer, Balic, Adam, Bardou, Philippe, Barela, Paul, Bigot, Yves, Blackmon, Heath, Borodin, Pavel M., Carroll, Rachel, Casono, Meya C., Charles, Mathieu, Cheng, Hans, Chiodi, Maddie, Cigan, Lacey, Coghill, Lyndon M., and Crooijmans, Richard

Subjects
KARYOTYPES, CHROMOSOMES, CHICKENS, BIOLOGICAL evolution, CHICKEN breeds, GENETIC determinism, LOCUS (Genetics), MASS extinctions
Abstract

Bird whole-genome alignments. a Alignment of chicken to zebra finch [Rhie et al., 2021], Anna's hummingbird [Rhie et al., 2021], superb fairywren [Penalba et al., 2020], and the ancestral emu genome [Liu J et al., 2021]. b Alignment of the chicken genome to species that have undergone significant chromosome rearrangement: saker falcon, California condor [Robinson et al., 2021], and golden eagle [Mead et al., 2021]. The Bird 10,000 Genomes (B10K) Project [Zhang et al., 2015] has generated insightful results and the future bird T2T genome and pan-genome will undoubtedly reveal more genes. The chicken genome aligns very well with the emu genome, which is considered to represent the ancestral bird genome [Liu J et al., 2021]. Chicken as a Model for Bird Genome Alignments (Prepared by P.D. Waters, J.A.M. Graves, and H.R. Patel) Chicken has long been a model for bird genomes [International Chicken Genome Sequencing Consortium, 2004], but it is only in recent years that a chromosome-level assembly has been available that includes the gene-dense microchromosomes. The GC content of most of these "missing" genes is more than 60%, and few genes even have over 80% (the median GC content of the chicken genome is 42.22% and the median GC content of the duck genome is 41.99%) [Hron et al., 2015; Bornelov et al., 2017; Botero-Castro et al., 2017; Yin et al., 2019b]. [Extracted from the article]

Published
2022
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