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32 results on '"Vigneron, Aurelien"'

1. Comparative genomic analysis of six Glossina genomes, vectors of African trypanosomes

Author

Attardo, Geoffrey M, Abd-Alla, Adly MM, Acosta-Serrano, Alvaro, Allen, James E, Bateta, Rosemary, Benoit, Joshua B, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel B, Farrow, David W, Friedrich, Markus, Hua-Van, Aurélie, Jennings, Emily C, Larkin, Denis M, Lawson, Daniel, Lehane, Michael J, Lenis, Vasileios P, Lowy-Gallego, Ernesto, Macharia, Rosaline W, Malacrida, Anna R, Marco, Heather G, Masiga, Daniel, Maslen, Gareth L, Matetovici, Irina, Meisel, Richard P, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang J, Minx, Patrick, Mireji, Paul O, Ometto, Lino, Parker, Andrew G, Rio, Rita, Rose, Clair, Rosendale, Andrew J, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin T, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Van Den Abbeele, Jan, Vigneron, Aurelien, Wang, Jingwen, Warren, Wesley C, Waterhouse, Robert M, Weirauch, Matthew T, Weiss, Brian L, Wilson, Richard K, Zhao, Xin, and Aksoy, Serap

Subjects
Biological Sciences, Genetics, Vector-Borne Diseases, Biotechnology, Infectious Diseases, Infection, Good Health and Well Being, Animals, DNA Transposable Elements, Drosophila melanogaster, Female, Gene Expression Regulation, Genes, Insect, Genes, X-Linked, Genome, Insect, Genomics, Geography, Insect Proteins, Insect Vectors, Male, Mutagenesis, Insertional, Phylogeny, Repetitive Sequences, Nucleic Acid, Sequence Homology, Amino Acid, Synteny, Trypanosoma, Tsetse Flies, Wolbachia, Tsetse, Trypanosomiasis, Hematophagy, Lactation, Disease, Neglected, Symbiosis, Environmental Sciences, Information and Computing Sciences, Bioinformatics
Abstract

BackgroundTsetse flies (Glossina sp.) are the vectors of human and animal trypanosomiasis throughout sub-Saharan Africa. Tsetse flies are distinguished from other Diptera by unique adaptations, including lactation and the birthing of live young (obligate viviparity), a vertebrate blood-specific diet by both sexes, and obligate bacterial symbiosis. This work describes the comparative analysis of six Glossina genomes representing three sub-genera: Morsitans (G. morsitans morsitans, G. pallidipes, G. austeni), Palpalis (G. palpalis, G. fuscipes), and Fusca (G. brevipalpis) which represent different habitats, host preferences, and vectorial capacity.ResultsGenomic analyses validate established evolutionary relationships and sub-genera. Syntenic analysis of Glossina relative to Drosophila melanogaster shows reduced structural conservation across the sex-linked X chromosome. Sex-linked scaffolds show increased rates of female-specific gene expression and lower evolutionary rates relative to autosome associated genes. Tsetse-specific genes are enriched in protease, odorant-binding, and helicase activities. Lactation-associated genes are conserved across all Glossina species while male seminal proteins are rapidly evolving. Olfactory and gustatory genes are reduced across the genus relative to other insects. Vision-associated Rhodopsin genes show conservation of motion detection/tracking functions and variance in the Rhodopsin detecting colors in the blue wavelength ranges.ConclusionsExpanded genomic discoveries reveal the genetics underlying Glossina biology and provide a rich body of knowledge for basic science and disease control. They also provide insight into the evolutionary biology underlying novel adaptations and are relevant to applied aspects of vector control such as trap design and discovery of novel pest and disease control strategies.

Published
2019

2. The Glossina Genome Cluster: Comparative Genomic Analysis of the Vectors of African Trypanosomes

Author

Attardo, Geoffrey M, Abd-Alla, Adly MM, Acosta-Serrano, Alvaro, Allen, James E, Bateta, Rosemary, Benoit, Joshua B, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel B, Farrow, David W, Friedrich, Markus, Hua-Van, Aurélie, Jennings, Emily C, Larkin, Denis M, Lawson, Daniel, Lehane, Michael J, Lenis, Vasileios P, Lowy-Gallego, Ernesto, Macharia, Rosaline W, Malacrida, Anna R, Marco, Heather G, Masiga, Daniel, Maslen, Gareth L, Matetovici, Irina, Meisel, Richard P, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang J, Minx, Patrick, Mireji, Paul O, Ometto, Lino, Parker, Andrew G, Rio, Rita, Rose, Clair, Rosendale, Andrew J, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin T, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Van Den Abbeele, Jan, Vigneron, Aurelien, Wang, Jingwen, Warren, Wesley C, Waterhouse, Robert M, Weirauch, Matthew T, Weiss, Brian L, Wilson, Richard K, Zhao, Xin, and Aksoy, Serap

Subjects
Biological Sciences, Genetics, Infectious Diseases, Vector-Borne Diseases, Biotechnology, Infection, Good Health and Well Being
Abstract

Background: Tsetse flies (Glossina sp.) are the sole vectors of human and animal trypanosomiasis throughout sub-Saharan Africa. Tsetse are distinguished from other Diptera by unique adaptations, including lactation and the birthing of live young (obligate viviparity), a vertebrate blood specific diet by both sexes and obligate bacterial symbiosis. This work describes comparative analysis of six Glossina genomes representing three sub-genera: Morsitans (G. morsitans morsitans (G.m. morsitans), G. pallidipes, G. austeni), Palpalis (G. palpalis, G. fuscipes) and Fusca (G. brevipalpis) which represent different habitats, host preferences and vectorial capacity. Results: Genomic analyses validate established evolutionary relationships and sub-genera. Syntenic analysis of Glossina relative to Drosophila melanogaster shows reduced structural conservation across the sex-linked X chromosome. Sex linked scaffolds show increased rates of female specific gene expression and lower evolutionary rates relative to autosome associated genes. Tsetse specific genes are enriched in protease, odorant binding and helicase activities. Lactation associated genes are conserved across all Glossina species while male seminal proteins are rapidly evolving. Olfactory and gustatory genes are reduced across the genus relative to other characterized insects. Vision associated Rhodopsin genes show conservation of motion detection/tracking functions and significant variance in the Rhodopsin detecting colors in the blue wavelength ranges. Conclusions: Expanded genomic discoveries reveal the genetics underlying Glossina biology and provide a rich body of knowledge for basic science and disease control. They also provide insight into the evolutionary biology underlying novel adaptations and are relevant to applied aspects of vector control such as trap design and discovery of novel pest and disease control strategies.

Published
2019

4. Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveal highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M, Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L, and Aksoy, Serap

Subjects
Biological Sciences, Nutrition, Genetics, Biotechnology, Vector-Borne Diseases, 2.2 Factors relating to the physical environment, Aetiology, Zero Hunger, Amino Acids, Animals, Carbohydrate Metabolism, Chaperonin 60, Female, Metabolome, Sequence Analysis, RNA, Symbiosis, Transcriptome, Tsetse Flies, Vitamin B Complex, Wigglesworthia, tsetse, Wigglesworthia symbiosis, transcriptomic profiling, metabolomic analysis, vitamin biosynthesis, mutualism, Agricultural and Veterinary Sciences, Medical and Health Sciences, Agricultural, veterinary and food sciences, Biological sciences, Environmental sciences
Abstract

Insects with restricted diets rely on obligate microbes to fulfil nutritional requirements essential for biological function. Tsetse flies, vectors of African trypanosome parasites, feed exclusively on vertebrate blood and harbour the obligate endosymbiont Wigglesworthia glossinidia. Without Wigglesworthia, tsetse are unable to reproduce. These symbionts are sheltered within specialized cells (bacteriocytes) that form the midgut-associated bacteriome organ. To decipher the core functions of this symbiosis essential for tsetse's survival, we performed dual-RNA-seq analysis of the bacteriome, coupled with metabolomic analysis of bacteriome and haemolymph collected from normal and symbiont-cured (sterile) females. Bacteriocytes produce immune regulatory peptidoglycan recognition protein (pgrp-lb) that protects Wigglesworthia, and a multivitamin transporter (smvt) that can aid in nutrient dissemination. Wigglesworthia overexpress a molecular chaperone (GroEL) to augment their translational/transport machinery and biosynthesize an abundance of B vitamins (specifically B1-, B2-, B3- and B6-associated metabolites) to supplement the host's nutritionally deficient diet. The absence of Wigglesworthia's contributions disrupts multiple metabolic pathways impacting carbohydrate and amino acid metabolism. These disruptions affect the dependent downstream processes of nucleotide biosynthesis and metabolism and biosynthesis of S-adenosyl methionine (SAM), an essential cofactor. This holistic fundamental knowledge of the symbiotic dialogue highlights new biological targets for the development of innovative vector control methods.

Published
2017

5. Multi-Omics Analysis Of Antiviral Interactions Of Elizabethkingia anophelis And Zika Virus

Author

Omme, Sultana Fatema, primary, Wang, Junyao, additional, Sifuna, Millicent, additional, Rodriguez, Jacqueline, additional, Owusu, Rhoda, additional, Goli, Mona, additional, Jiang, Peilin, additional, Purba, Wazia, additional, Nwaiwu, Judith, additional, Brelsfoard, Corey, additional, Vigneron, Aurelien, additional, Kramer, Laura, additional, Ciota, Alexander, additional, Mechref, Yehia, additional, and Onyango, Maria Gorreti, additional

Published
2023
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11. Additional file 2 of Zika virus and temperature modulate Elizabethkingia anophelis in Aedes albopictus

Author

Onyango, Maria G., Lange, Rachel, Bialosuknia, Sean, Payne, Anne, Mathias, Nicholas, Kuo, Lili, Vigneron, Aurelien, Nag, Dilip, Kramer, Laura D., and Ciota, Alexander T.

Subjects
fungi, respiratory system, human activities
Abstract

Additional file 2: Figure S2. A box plot file showing the impact of temperature increase on individual midgut diversity.

Published
2021
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15. Additional file 13: of Comparative genomic analysis of six Glossina genomes, vectors of African trypanosomes

Author

Attardo, Geoffrey, Adly Abd-Alla, Acosta-Serrano, Alvaro, Allen, James, Bateta, Rosemary, Benoit, Joshua, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel, Farrow, David, Friedrich, Markus, Aurélie Hua-Van, Jennings, Emily, Larkin, Denis, Lawson, Daniel, Lehane, Michael, Lenis, Vasileios, Lowy-Gallego, Ernesto, Macharia, Rosaline, Malacrida, Anna, Marco, Heather, Masiga, Daniel, Maslen, Gareth, Matetovici, Irina, Meisel, Richard, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang, Minx, Patrick, Mireji, Paul, Ometto, Lino, Parker, Andrew, Rio, Rita, Rose, Clair, Rosendale, Andrew, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Abbeele, Jan, Vigneron, Aurelien, Jingwen Wang, Warren, Wesley, Waterhouse, Robert, Weirauch, Matthew, Weiss, Brian, Wilson, Richard, Zhao, Xin, and Aksoy, Serap

Abstract

Review history. (DOCX 31 kb)

Published
2019
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17. Figure S5: Differential metabolite abundances and enzyme transcription between control and symbiont-cured tsetse in the glycogen metabolism pathway from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Abstract

Metabolite data was derived from bacteriome specific metabolomic analysis. Differential enzyme transcription was derived from transcriptomic data from whole guts of control and aposymbiotic flies. Enzymes are represented as rectangles and defined by their KEGG Enzyme ID numbers and metabolites/cofactors are represented as circles and are labeled with metabolite names. Enzyme and metabolite symbols are colored to reflect their increased (blue) or decreased (red) expression (for enzymes) or abundance (for metabolites). Light blue/red symbols represent changes in abundance approaching significance (p-value between 0.1 - 0.05). Green symbols reflect Wigglesworthia derived enzymes/metabolites. Numerical representation of metabolite data is in Table S7 and enzyme gene expression data is in Table S9.

Published
2017
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18. Figure S7: Differential metabolite abundances and enzyme associated gene expression in the pyrimidine metabolism pathway between control and aposymbiotic tsetse from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Abstract

Metabolite data was derived from bacteriome specific metabolomic analysis. Differential enzyme transcription was derived from transcriptomic data from whole guts of control and aposymbiotic flies. Enzymes are represented as rectangles and defined by their KEGG Enzyme ID numbers and metabolites/cofactors are represented as circles and are labeled with metabolite names. Enzyme and metabolite symbols are colored to reflect their increased (blue) or decreased (red) expression (for enzymes) or abundance (for metabolites). Light blue/red symbols represent changes in abundance approaching significance (p-value between 0.1 - 0.05). Green symbols reflect Wigglesworthia derived enzymes/metabolites. Numerical representation of metabolite data is in Table S7 and enzyme gene expression data is in Table S9.

Published
2017
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19. Figure S1: Read-mapping statistics of bacteriome RNA-Seq Data from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
parasitic diseases
Abstract

Graphical representation of the proportion of bacteriome transcriptome reads mapping to annotated and unannotated Glossina sequences, bacterial transcripts (Wigglesworthia + Sodalis), mitochondrial transcripts and viral transcripts. Side bars represent proportions of reads mapped to Wigglesworthia and Glossina RNA classes (See table S2 for details).

Published
2017
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20. Table S1: Transcriptomic and metabolomic datasets utilized in this study from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Abstract

This table contains the individual RNA-seq and metabolomic data sets utilized in this paper. Associated SRA numbers of tables are listed.

Published
2017
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21. Figure S3: Gene ontology analysis of bacteriocyte-enriched products associated with molecular functions from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Abstract

Bars represent the sum of the RPKM values of the transcripts associated with the respective GO molecular function categories. Numbers next to the right of the bars represent the number of genes associated with each category (see also Table S4).

Published
2017
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22. Figure S4: Differential expression of bacteriocyte enriched genes in aposymbiotic and trypanosome infected flies with additional annotations from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
fungi
Abstract

This graph represents the differential expression of the 252 bacteriocyte enriched genes (relative to the midgut) in the whole gut tissue of aposymbiotic flies (x-axis) and trypanosome infected flies (y-axis). Data point sizes represent the expression level (Log2 of counts per million (CPM) values) in the bacteriome-specific transcriptome. Transcripts were categorized as significantly up- or down-regulated if they were scored as differentially expressed by edgeR analysis with a P-value of less than 0.05 and a false discovery rate (FDR) score of less than 0.05 (see also Table S6 for detailed annotations).

Published
2017
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24. Comparative genomic analysis of six Glossinagenomes, vectors of African trypanosomes

Author

Attardo, Geoffrey, Abd-Alla, Adly, Acosta-Serrano, Alvaro, Allen, James, Bateta, Rosemary, Benoit, Joshua, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel, Farrow, David, Friedrich, Markus, Hua-Van, Aurélie, Jennings, Emily, Larkin, Denis, Lawson, Daniel, Lehane, Michael, Lenis, Vasileios, Lowy-Gallego, Ernesto, Macharia, Rosaline, Malacrida, Anna, Marco, Heather, Masiga, Daniel, Maslen, Gareth, Matetovici, Irina, Meisel, Richard, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang, Minx, Patrick, Mireji, Paul, Ometto, Lino, Parker, Andrew, Rio, Rita, Rose, Clair, Rosendale, Andrew, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Abbeele, Jan, Vigneron, Aurelien, Wang, Jingwen, Warren, Wesley, Waterhouse, Robert, Weirauch, Matthew, Weiss, Brian, Wilson, Richard, Zhao, Xin, and Aksoy, Serap

Abstract

Tsetse flies (Glossinasp.) are the vectors of human and animal trypanosomiasis throughout sub-Saharan Africa. Tsetse flies are distinguished from other Diptera by unique adaptations, including lactation and the birthing of live young (obligate viviparity), a vertebrate blood-specific diet by both sexes, and obligate bacterial symbiosis. This work describes the comparative analysis of six Glossinagenomes representing three sub-genera: Morsitans(G. morsitans morsitans, G. pallidipes, G. austeni), Palpalis(G. palpalis, G. fuscipes), and Fusca(G. brevipalpis) which represent different habitats, host preferences, and vectorial capacity. Genomic analyses validate established evolutionary relationships and sub-genera. Syntenic analysis of Glossinarelative to Drosophila melanogastershows reduced structural conservation across the sex-linked X chromosome. Sex-linked scaffolds show increased rates of female-specific gene expression and lower evolutionary rates relative to autosome associated genes. Tsetse-specific genes are enriched in protease, odorant-binding, and helicase activities. Lactation-associated genes are conserved across all Glossinaspecies while male seminal proteins are rapidly evolving. Olfactory and gustatory genes are reduced across the genus relative to other insects. Vision-associated Rhodopsin genes show conservation of motion detection/tracking functions and variance in the Rhodopsin detecting colors in the blue wavelength ranges. Expanded genomic discoveries reveal the genetics underlying Glossinabiology and provide a rich body of knowledge for basic science and disease control. They also provide insight into the evolutionary biology underlying novel adaptations and are relevant to applied aspects of vector control such as trap design and discovery of novel pest and disease control strategies.

Published
2019
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25. Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveal highly integrated physiological networks.

Author

XiaoLi Bing, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
INSECTS, TSETSE-flies, FLIES, METABOLOMICS, METABOLISM
Abstract

Insects with restricted diets rely on obligate microbes to fulfil nutritional requirements essential for biological function. Tsetse flies, vectors of African trypanosome parasites, feed exclusively on vertebrate blood and harbour the obligate endosymbiont Wigglesworthia glossinidia. Without Wigglesworthia, tsetse are unable to reproduce. These symbionts are sheltered within specialized cells (bacteriocytes) that form the midgut-associated bacteriome organ. To decipher the core functions of this symbiosis essential for tsetse's survival, we performed dual-RNA-seq analysis of the bacteriome, coupledwith metabolomic analysis of bacteriome and haemolymph collected from normal and symbiont-cured (sterile) females. Bacteriocytes produce immune regulatory peptidoglycan recognition protein ( pgrp-lb) that protects Wigglesworthia, and a multivitamin transporter (smvt) that can aid in nutrient dissemination. Wigglesworthia overexpress a molecular chaperone (GroEL) to augment their translational/transport machinery and biosynthesize an abundance of B vitamins (specifically B1-, B2-, B3- and B6-associated metabolites) to supplement the host's nutritionally deficient diet. The absence of Wigglesworthia's contributions disrupts multiple metabolic pathways impacting carbohydrate and amino acid metabolism. These disruptions affect the dependent downstream processes of nucleotide biosynthesis and metabolism and biosynthesis of S-adenosyl methionine (SAM), an essential cofactor. This holistic fundamental knowledge of the symbiotic dialogue highlights new biological targets for the development of innovative vector control methods. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Figure S2: PCA analysis of gut and bacteriome RNA-Seq Datasets from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
parasitic diseases, 3. Good health
Abstract

Principal component analysis of variability between whole Glossina gut transcriptome replicates and bacteriome specific transcriptome replicates.

27. Figure S2: PCA analysis of gut and bacteriome RNA-Seq Datasets from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
parasitic diseases, 3. Good health
Abstract

Principal component analysis of variability between whole Glossina gut transcriptome replicates and bacteriome specific transcriptome replicates.

28. Additional file 2: of Comparative genomic analysis of six Glossina genomes, vectors of African trypanosomes

Author

Attardo, Geoffrey, Adly Abd-Alla, Acosta-Serrano, Alvaro, Allen, James, Bateta, Rosemary, Benoit, Joshua, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel, Farrow, David, Friedrich, Markus, Aurélie Hua-Van, Jennings, Emily, Larkin, Denis, Lawson, Daniel, Lehane, Michael, Lenis, Vasileios, Lowy-Gallego, Ernesto, Macharia, Rosaline, Malacrida, Anna, Marco, Heather, Masiga, Daniel, Maslen, Gareth, Matetovici, Irina, Meisel, Richard, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang, Minx, Patrick, Mireji, Paul, Ometto, Lino, Parker, Andrew, Rio, Rita, Rose, Clair, Rosendale, Andrew, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Abbeele, Jan, Vigneron, Aurelien, Jingwen Wang, Warren, Wesley, Waterhouse, Robert, Weirauch, Matthew, Weiss, Brian, Wilson, Richard, Zhao, Xin, and Aksoy, Serap

Subjects
3. Good health
Abstract

Supplemental Figures S1-S12 and associated captions. (PDF 2260 kb)

29. Materials and Methods from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
2. Zero hunger
Abstract

Insects with restricted diets rely on obligate microbes to fulfil nutritional requirements essential for biological function. Tsetse flies, vectors of African trypanosome parasites, feed exclusively on vertebrate blood and harbour the obligate endosymbiont Wigglesworthia glossinidia. Without Wigglesworthia, tsetse are unable to reproduce. These symbionts are sheltered within specialized cells (bacteriocytes) that form the midgut-associated bacteriome organ. To decipher the core functions of this symbiosis essential for tsetse's survival, we performed Dual-RNA-Seq analysis of the bacteriome, coupled with metabolomic analysis of bacteriome and haemolymph collected from normal and symbiont-cured (sterile) females. Bacteriocytes produce immune regulatory Peptidoglycan Recognition Protein (pgrp-lb) that protects Wigglesworthia, and a multivitamin transporter (smvt) that can aid in nutrient dissemination. Wigglesworthia overexpress a molecular chaperone (GroEL) to augment their translational/transport machinery and biosynthesize an abundance of B-vitamins (specifically B1-, B2-, B3- and B6-associated metabolites) to supplement the host's nutritionally deficient diet. The absence of Wigglesworthia's contributions disrupts multiple metabolic pathways impacting carbohydrate and amino acid metabolism. These disruptions affect the dependent downstream processes of nucleotide biosynthesis and metabolism and biosynthesis of S-adenosyl methionine (SAM), an essential cofactor. This holistic fundamental knowledge of the symbiotic dialogue highlights new biological targets for development of innovative vector control methods.

30. Additional file 2: of Comparative genomic analysis of six Glossina genomes, vectors of African trypanosomes

Author

Attardo, Geoffrey, Adly Abd-Alla, Acosta-Serrano, Alvaro, Allen, James, Bateta, Rosemary, Benoit, Joshua, Bourtzis, Kostas, Caers, Jelle, Caljon, Guy, Christensen, Mikkel, Farrow, David, Friedrich, Markus, Aurélie Hua-Van, Jennings, Emily, Larkin, Denis, Lawson, Daniel, Lehane, Michael, Lenis, Vasileios, Lowy-Gallego, Ernesto, Macharia, Rosaline, Malacrida, Anna, Marco, Heather, Masiga, Daniel, Maslen, Gareth, Matetovici, Irina, Meisel, Richard, Meki, Irene, Michalkova, Veronika, Miller, Wolfgang, Minx, Patrick, Mireji, Paul, Ometto, Lino, Parker, Andrew, Rio, Rita, Rose, Clair, Rosendale, Andrew, Rota-Stabelli, Omar, Savini, Grazia, Schoofs, Liliane, Scolari, Francesca, Swain, Martin, Takáč, Peter, Tomlinson, Chad, Tsiamis, George, Abbeele, Jan, Vigneron, Aurelien, Jingwen Wang, Warren, Wesley, Waterhouse, Robert, Weirauch, Matthew, Weiss, Brian, Wilson, Richard, Zhao, Xin, and Aksoy, Serap

Subjects
3. Good health
Abstract

Supplemental Figures S1-S12 and associated captions. (PDF 2260 kb)

31. Figure S2: PCA analysis of gut and bacteriome RNA-Seq Datasets from Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia: transcriptomic and metabolomic landscapes reveals highly integrated physiological networks

Author

Bing, XiaoLi, Attardo, Geoffrey M., Vigneron, Aurelien, Aksoy, Emre, Scolari, Francesca, Malacrida, Anna, Weiss, Brian L., and Aksoy, Serap

Subjects
parasitic diseases, 3. Good health
Abstract

Principal component analysis of variability between whole Glossina gut transcriptome replicates and bacteriome specific transcriptome replicates.

32. Unravelling the relationship between the tsetse fly and its obligate symbiont Wigglesworthia : transcriptomic and metabolomic landscapes reveal highly integrated physiological networks.

Author

Bing X, Attardo GM, Vigneron A, Aksoy E, Scolari F, Malacrida A, Weiss BL, and Aksoy S

Subjects
Amino Acids metabolism, Animals, Carbohydrate Metabolism, Chaperonin 60 metabolism, Female, Sequence Analysis, RNA, Tsetse Flies metabolism, Vitamin B Complex biosynthesis, Metabolome, Symbiosis, Transcriptome, Tsetse Flies microbiology, Wigglesworthia metabolism
Abstract

Insects with restricted diets rely on obligate microbes to fulfil nutritional requirements essential for biological function. Tsetse flies, vectors of African trypanosome parasites, feed exclusively on vertebrate blood and harbour the obligate endosymbiont Wigglesworthia glossinidia. Without Wigglesworthia , tsetse are unable to reproduce. These symbionts are sheltered within specialized cells (bacteriocytes) that form the midgut-associated bacteriome organ. To decipher the core functions of this symbiosis essential for tsetse's survival, we performed dual-RNA-seq analysis of the bacteriome, coupled with metabolomic analysis of bacteriome and haemolymph collected from normal and symbiont-cured (sterile) females. Bacteriocytes produce immune regulatory peptidoglycan recognition protein ( pgrp-lb ) that protects Wigglesworthia , and a multivitamin transporter ( smvt ) that can aid in nutrient dissemination. Wigglesworthia overexpress a molecular chaperone (GroEL) to augment their translational/transport machinery and biosynthesize an abundance of B vitamins (specifically B 1 -, B 2 -, B 3 - and B 6 -associated metabolites) to supplement the host's nutritionally deficient diet. The absence of Wigglesworthia's contributions disrupts multiple metabolic pathways impacting carbohydrate and amino acid metabolism. These disruptions affect the dependent downstream processes of nucleotide biosynthesis and metabolism and biosynthesis of S -adenosyl methionine (SAM), an essential cofactor. This holistic fundamental knowledge of the symbiotic dialogue highlights new biological targets for the development of innovative vector control methods., (© 2017 The Authors.)

Published
2017
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