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2. Targeted enrichment outperforms other enrichment techniques and enables more multi-species RNA-Seq analyses.

Author

Chung, Matthew, Teigen, Laura, Liu, Hong, Libro, Silvia, Shetty, Amol, Kumar, Nikhil, Zhao, Xuechu, Bromley, Robin E, Tallon, Luke J, Sadzewicz, Lisa, Fraser, Claire M, Rasko, David A, Filler, Scott G, Foster, Jeremy M, Michalski, Michelle L, Bruno, Vincent M, and Dunning Hotopp, Julie C

Subjects
Animals, Brugia malayi, Wolbachia, Aspergillus fumigatus, RNA, Bacterial, RNA, Fungal, RNA, Helminth, RNA, Messenger, Sequence Analysis, RNA, RNA, Bacterial, Fungal, Helminth, Messenger, Sequence Analysis, Infectious Diseases, Genetics, Biochemistry and Cell Biology, Other Physical Sciences
Abstract

Enrichment methodologies enable the analysis of minor members in multi-species transcriptomic data. We compared the standard enrichment of bacterial and eukaryotic mRNA to a targeted enrichment using an Agilent SureSelect (AgSS) capture for Brugia malayi, Aspergillus fumigatus, and the Wolbachia endosymbiont of B. malayi (wBm). Without introducing significant systematic bias, the AgSS quantitatively enriched samples, resulting in more reads mapping to the target organism. The AgSS-enriched libraries consistently had a positive linear correlation with their unenriched counterparts (r2 = 0.559-0.867). Up to a 2,242-fold enrichment of RNA from the target organism was obtained following a power law (r2 = 0.90), with the greatest fold enrichment achieved in samples with the largest ratio difference between the major and minor members. While using a single total library for prokaryote and eukaryote enrichment from a single RNA sample could be beneficial for samples where RNA is limiting, we observed a decrease in reads mapping to protein coding genes and an increase in multi-mapping reads to rRNAs in AgSS enrichments from eukaryotic total RNA libraries compared to eukaryotic poly(A)-enriched libraries. Our results support a recommendation of using AgSS targeted enrichment on poly(A)-enriched libraries for eukaryotic captures, and total RNA libraries for prokaryotic captures, to increase the robustness of multi-species transcriptomic studies.

Published
2018

5. Complete genome sequence of the aerobic CO-oxidizing thermophile Thermomicrobium roseum.

Author

Wu, Dongying, Raymond, Jason, Wu, Martin, Chatterji, Sourav, Ren, Qinghu, Graham, Joel E, Bryant, Donald A, Robb, Frank, Colman, Albert, Tallon, Luke J, Badger, Jonathan H, Madupu, Ramana, Ward, Naomi L, and Eisen, Jonathan A

Subjects
Flagella, Bacteria, Aerobic, Chloroflexi, Gram-Negative Bacteria, Carbon Monoxide, DNA, Circular, Sequence Analysis, DNA, Hot Springs, Phylogeny, Chemotaxis, Photosynthesis, Genome, Bacterial, Metabolic Networks and Pathways, General Science & Technology
Abstract

In order to enrich the phylogenetic diversity represented in the available sequenced bacterial genomes and as part of an "Assembling the Tree of Life" project, we determined the genome sequence of Thermomicrobium roseum DSM 5159. T. roseum DSM 5159 is a red-pigmented, rod-shaped, Gram-negative extreme thermophile isolated from a hot spring that possesses both an atypical cell wall composition and an unusual cell membrane that is composed entirely of long-chain 1,2-diols. Its genome is composed of two circular DNA elements, one of 2,006,217 bp (referred to as the chromosome) and one of 919,596 bp (referred to as the megaplasmid). Strikingly, though few standard housekeeping genes are found on the megaplasmid, it does encode a complete system for chemotaxis including both chemosensory components and an entire flagellar apparatus. This is the first known example of a complete flagellar system being encoded on a plasmid and suggests a straightforward means for lateral transfer of flagellum-based motility. Phylogenomic analyses support the recent rRNA-based analyses that led to T. roseum being removed from the phylum Thermomicrobia and assigned to the phylum Chloroflexi. Because T. roseum is a deep-branching member of this phylum, analysis of its genome provides insights into the evolution of the Chloroflexi. In addition, even though this species is not photosynthetic, analysis of the genome provides some insight into the origins of photosynthesis in the Chloroflexi. Metabolic pathway reconstructions and experimental studies revealed new aspects of the biology of this species. For example, we present evidence that T. roseum oxidizes CO aerobically, making it the first thermophile known to do so. In addition, we propose that glycosylation of its carotenoids plays a crucial role in the adaptation of the cell membrane to this bacterium's thermophilic lifestyle. Analyses of published metagenomic sequences from two hot springs similar to the one from which this strain was isolated, show that close relatives of T. roseum DSM 5159 are present but have some key differences from the strain sequenced.

Published
2009

6. Refined annotation and assembly of the Tetrahymena thermophila genome sequence through EST analysis, comparative genomic hybridization, and targeted gap closure.

Author

Coyne, Robert S, Thiagarajan, Mathangi, Jones, Kristie M, Wortman, Jennifer R, Tallon, Luke J, Haas, Brian J, Cassidy-Hanley, Donna M, Wiley, Emily A, Smith, Joshua J, Collins, Kathleen, Lee, Suzanne R, Couvillion, Mary T, Liu, Yifan, Garg, Jyoti, Pearlman, Ronald E, Hamilton, Eileen P, Orias, Eduardo, Eisen, Jonathan A, and Methé, Barbara A

Subjects
Macronucleus, Micronucleus, Germline, Animals, Tetrahymena thermophila, Nucleic Acid Hybridization, Genes, Protozoan, Genome, Protozoan, Expressed Sequence Tags, Micronucleus, Germline, Genes, Protozoan, Genome, Genetics, Biotechnology, Human Genome, Generic Health Relevance, Bioinformatics, Biological Sciences, Medical and Health Sciences, Information and Computing Sciences
Abstract

BackgroundTetrahymena thermophila, a widely studied model for cellular and molecular biology, is a binucleated single-celled organism with a germline micronucleus (MIC) and somatic macronucleus (MAC). The recent draft MAC genome assembly revealed low sequence repetitiveness, a result of the epigenetic removal of invasive DNA elements found only in the MIC genome. Such low repetitiveness makes complete closure of the MAC genome a feasible goal, which to achieve would require standard closure methods as well as removal of minor MIC contamination of the MAC genome assembly. Highly accurate preliminary annotation of Tetrahymena's coding potential was hindered by the lack of both comparative genomic sequence information from close relatives and significant amounts of cDNA evidence, thus limiting the value of the genomic information and also leaving unanswered certain questions, such as the frequency of alternative splicing.ResultsWe addressed the problem of MIC contamination using comparative genomic hybridization with purified MIC and MAC DNA probes against a whole genome oligonucleotide microarray, allowing the identification of 763 genome scaffolds likely to contain MIC-limited DNA sequences. We also employed standard genome closure methods to essentially finish over 60% of the MAC genome. For the improvement of annotation, we have sequenced and analyzed over 60,000 verified EST reads from a variety of cellular growth and development conditions. Using this EST evidence, a combination of automated and manual reannotation efforts led to updates that affect 16% of the current protein-coding gene models. By comparing EST abundance, many genes showing apparent differential expression between these conditions were identified. Rare instances of alternative splicing and uses of the non-standard amino acid selenocysteine were also identified.ConclusionWe report here significant progress in genome closure and reannotation of Tetrahymena thermophila. Our experience to date suggests that complete closure of the MAC genome is attainable. Using the new EST evidence, automated and manual curation has resulted in substantial improvements to the over 24,000 gene models, which will be valuable to researchers studying this model organism as well as for comparative genomics purposes.

Published
2008

7. Macronuclear genome sequence of the ciliate Tetrahymena thermophila, a model eukaryote.

Author

Eisen, Jonathan A, Coyne, Robert S, Wu, Martin, Wu, Dongying, Thiagarajan, Mathangi, Wortman, Jennifer R, Badger, Jonathan H, Ren, Qinghu, Amedeo, Paolo, Jones, Kristie M, Tallon, Luke J, Delcher, Arthur L, Salzberg, Steven L, Silva, Joana C, Haas, Brian J, Majoros, William H, Farzad, Maryam, Carlton, Jane M, Smith, Roger K, Garg, Jyoti, Pearlman, Ronald E, Karrer, Kathleen M, Sun, Lei, Manning, Gerard, Elde, Nels C, Turkewitz, Aaron P, Asai, David J, Wilkes, David E, Wang, Yufeng, Cai, Hong, Collins, Kathleen, Stewart, B Andrew, Lee, Suzanne R, Wilamowska, Katarzyna, Weinberg, Zasha, Ruzzo, Walter L, Wloga, Dorota, Gaertig, Jacek, Frankel, Joseph, Tsao, Che-Chia, Gorovsky, Martin A, Keeling, Patrick J, Waller, Ross F, Patron, Nicola J, Cherry, J Michael, Stover, Nicholas A, Krieger, Cynthia J, del Toro, Christina, Ryder, Hilary F, Williamson, Sondra C, Barbeau, Rebecca A, Hamilton, Eileen P, and Orias, Eduardo

Abstract

The ciliate Tetrahymena thermophila is a model organism for molecular and cellular biology. Like other ciliates, this species has separate germline and soma functions that are embodied by distinct nuclei within a single cell. The germline-like micronucleus (MIC) has its genome held in reserve for sexual reproduction. The soma-like macronucleus (MAC), which possesses a genome processed from that of the MIC, is the center of gene expression and does not directly contribute DNA to sexual progeny. We report here the shotgun sequencing, assembly, and analysis of the MAC genome of T. thermophila, which is approximately 104 Mb in length and composed of approximately 225 chromosomes. Overall, the gene set is robust, with more than 27,000 predicted protein-coding genes, 15,000 of which have strong matches to genes in other organisms. The functional diversity encoded by these genes is substantial and reflects the complexity of processes required for a free-living, predatory, single-celled organism. This is highlighted by the abundance of lineage-specific duplications of genes with predicted roles in sensing and responding to environmental conditions (e.g., kinases), using diverse resources (e.g., proteases and transporters), and generating structural complexity (e.g., kinesins and dyneins). In contrast to the other lineages of alveolates (apicomplexans and dinoflagellates), no compelling evidence could be found for plastid-derived genes in the genome. UGA, the only T. thermophila stop codon, is used in some genes to encode selenocysteine, thus making this organism the first known with the potential to translate all 64 codons in nuclear genes into amino acids. We present genomic evidence supporting the hypothesis that the excision of DNA from the MIC to generate the MAC specifically targets foreign DNA as a form of genome self-defense. The combination of the genome sequence, the functional diversity encoded therein, and the presence of some pathways missing from other model organisms makes T. thermophila an ideal model for functional genomic studies to address biological, biomedical, and biotechnological questions of fundamental importance.

Published
2006

8. Metabolic complementarity and genomics of the dual bacterial symbiosis of sharpshooters

Author

Wu, Dongying, Daugherty, Sean C, Van Aken, Susan E, Pai, Grace H, Watkins, Kisha L, Khouri, Hoda, Tallon, Luke J, Zaborsky, Jennifer M, Dunbar, Helen E, Tran, Phat L, Moran, Nancy A, and Eisen, Jonathan A

Subjects
symbioses, symbionts, genomics, evolution, PIerce's Disease, phylogenomics, DNA repair, sharpshooters, insects, amino-acids, metabolism
Abstract

Mutualistic intracellular symbiosis between bacteria and insects is a widespread phenomenon that has contributed to the global success of insects. The symbionts, by provisioning nutrients lacking from diets, allow various insects to occupy or dominate ecological niches that might otherwise be unavailable. One such insect is the glassy-winged sharpshooter ( Homalodisca coagulata), which feeds on xylem fluid, a diet exceptionally poor in organic nutrients. Phylogenetic studies based on rRNA have shown two types of bacterial symbionts to be coevolving with sharpshooters: the gamma-proteobacterium Baumannia cicadellinicola and the Bacteroidetes species Sulcia muelleri. We report here the sequencing and analysis of the 686,192-base pair genome of B. cicadellinicola and approximately 150 kilobase pairs of the small genome of S. muelleri, both isolated from H. coagulata. Our study, which to our knowledge is the first genomic analysis of an obligate symbiosis involving multiple partners, suggests striking complementarity in the biosynthetic capabilities of the two symbionts: B. cicadellinicola devotes a substantial portion of its genome to the biosynthesis of vitamins and cofactors required by animals and lacks most amino acid biosynthetic pathways, whereas S. muelleri apparently produces most or all of the essential amino acids needed by its host. This finding, along with other results of our genome analysis, suggests the existence of metabolic codependency among the two unrelated endosymbionts and their insect host. This dual symbiosis provides a model case for studying correlated genome evolution and genome reduction involving multiple organisms in an intimate, obligate mutualistic relationship. In addition, our analysis provides insight for the first time into the differences in symbionts between insects ( e. g., aphids) that feed on phloem versus those like H. coagulata that feed on xylem. Finally, the genomes of these two symbionts provide potential targets for controlling plant pathogens such as Xylella fastidiosa, a major agroeconomic problem, for which H. coagulata and other sharpshooters serve as vectors of transmission.

Published
2006

9. Life in hot carbon monoxide: the complete genome sequence of Carboxydothermus hydrogenoformans Z-2901.

Author

Wu, Martin, Ren, Qinghu, Durkin, A Scott, Daugherty, Sean C, Brinkac, Lauren M, Dodson, Robert J, Madupu, Ramana, Sullivan, Steven A, Kolonay, James F, Haft, Daniel H, Nelson, William C, Tallon, Luke J, Jones, Kristine M, Ulrich, Luke E, Gonzalez, Juan M, Zhulin, Igor B, Robb, Frank T, and Eisen, Jonathan A

Subjects
Peptococcaceae, Carbon Monoxide, Sequence Analysis, DNA, Genomics, Base Sequence, Oxidative Stress, Genes, Bacterial, Genome, Bacterial, Models, Biological, Molecular Sequence Data, Hot Temperature, Genes, Bacterial, Genome, Models, Biological, Sequence Analysis, DNA, Genetics, Developmental Biology
Abstract

We report here the sequencing and analysis of the genome of the thermophilic bacterium Carboxydothermus hydrogenoformans Z-2901. This species is a model for studies of hydrogenogens, which are diverse bacteria and archaea that grow anaerobically utilizing carbon monoxide (CO) as their sole carbon source and water as an electron acceptor, producing carbon dioxide and hydrogen as waste products. Organisms that make use of CO do so through carbon monoxide dehydrogenase complexes. Remarkably, analysis of the genome of C. hydrogenoformans reveals the presence of at least five highly differentiated anaerobic carbon monoxide dehydrogenase complexes, which may in part explain how this species is able to grow so much more rapidly on CO than many other species. Analysis of the genome also has provided many general insights into the metabolism of this organism which should make it easier to use it as a source of biologically produced hydrogen gas. One surprising finding is the presence of many genes previously found only in sporulating species in the Firmicutes Phylum. Although this species is also a Firmicutes, it was not known to sporulate previously. Here we show that it does sporulate and because it is missing many of the genes involved in sporulation in other species, this organism may serve as a "minimal" model for sporulation studies. In addition, using phylogenetic profile analysis, we have identified many uncharacterized gene families found in all known sporulating Firmicutes, but not in any non-sporulating bacteria, including a sigma factor not known to be involved in sporulation previously.

Published
2005

10. Strains used in whole organism Plasmodium falciparum vaccine trials differ in genome structure, sequence, and immunogenic potential

Author

Moser, Kara A., Drábek, Elliott F., Dwivedi, Ankit, Stucke, Emily M., Crabtree, Jonathan, Dara, Antoine, Shah, Zalak, Adams, Matthew, Li, Tao, Rodrigues, Priscila T., Koren, Sergey, Phillippy, Adam M., Munro, James B., Ouattara, Amed, Sparklin, Benjamin C., Dunning Hotopp, Julie C., Lyke, Kirsten E., Sadzewicz, Lisa, Tallon, Luke J., Spring, Michele D., Jongsakul, Krisada, Lon, Chanthap, Saunders, David L., Ferreira, Marcelo U., Nyunt, Myaing M., Laufer, Miriam K., Travassos, Mark A., Sauerwein, Robert W., Takala-Harrison, Shannon, Fraser, Claire M., Sim, B. Kim Lee, Hoffman, Stephen L., Plowe, Christopher V., and Silva, Joana C.

Published
2020
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13. Genomic diversity of 2010 Haitian cholera outbreak strains

Author

Hasan, Nur A., Choi, Seon Young, Eppinger, Mark, Clark, Philip W., Chen, Arlene, Alam, Munirul, Haley, Bradd J., Taviani, Elisa, Hine, Erin, Su, Qi, Tallon, Luke J., Prosper, Joseph B., Furth, Keziah, Hoq, M. M., Li, Huai, Fraser-Liggett, Claire M., Cravioto, Alejandro, Huq, Anwar, Ravel, Jacques, Cebula, Thomas A., and Colwell, Rita R.

Published
2012

14. Highly Specialized Carbohydrate Metabolism Capability in Bifidobacterium Strains Associated with Intestinal Barrier Maturation in Early Preterm Infants

Author

Ma, Bing, primary, Sundararajan, Sripriya, additional, Nadimpalli, Gita, additional, France, Michael, additional, McComb, Elias, additional, Rutt, Lindsay, additional, Lemme-Dumit, Jose M., additional, Janofsky, Elise, additional, Roskes, Lisa S., additional, Gajer, Pawel, additional, Fu, Li, additional, Yang, Hongqiu, additional, Humphrys, Mike, additional, Tallon, Luke J., additional, Sadzewicz, Lisa, additional, Pasetti, Marcela F., additional, Ravel, Jacques, additional, and Viscardi, Rose M., additional

Published
2022
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15. Identification of protective and broadly conserved vaccine antigens from the genome of extraintestinal pathogenic Escherichia coli

Author

Moriel, Danilo Gomes, Bertoldi, Isabella, Spagnuolo, Angela, Marchi, Sara, Rosini, Roberto, Nesta, Barbara, Pastorello, Ilaria, Corea, Vanja A. Mariani, Torricelli, Giulia, Cartocci, Elena, Savino, Silvana, Scarselli, Maria, Dobrindt, Ulrich, Hacker, Jörg, Tettelin, Hervé, Tallon, Luke J., Sullivan, Steven, Wieler, Lothar H., Ewers, Christa, Pickard, Derek, Dougan, Gordon, Fontana, Maria Rita, Rappuoli, Rino, Pizza, Mariagrazia, and Serino, Laura

Published
2010

18. Successful Profiling of Plasmodium falciparum var Gene Expression in Clinical Samples via a Custom Capture Array

Author

Stucke, Emily M., primary, Dara, Antoine, additional, Dwivedi, Ankit, additional, Hodges, Theresa K., additional, Ott, Sandra, additional, Coulibaly, Drissa, additional, Koné, Abdoulaye K., additional, Traoré, Karim, additional, Guindo, Bouréima, additional, Tangara, Bourama M., additional, Niangaly, Amadou, additional, Daou, Modibo, additional, Diarra, Issa, additional, Tolo, Youssouf, additional, Sissoko, Mody, additional, Tallon, Luke J., additional, Sadzewicz, Lisa, additional, Zhou, Albert E., additional, Laurens, Matthew B., additional, Ouattara, Amed, additional, Kouriba, Bourema, additional, Doumbo, Ogobara K., additional, Takala-Harrison, Shannon, additional, Serre, David, additional, Plowe, Christopher V., additional, Thera, Mahamadou A., additional, Travassos, Mark A., additional, and Silva, Joana C., additional

Published
2021
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19. X-treme loss of sequence diversity linked to neo-X chromosomes in filarial nematodes

Author

Mattick, John, primary, Libro, Silvia, additional, Bromley, Robin, additional, Chaicumpa, Wanpen, additional, Chung, Matthew, additional, Cook, Darren, additional, Khan, Mohammad Behram, additional, Kumar, Nikhil, additional, Lau, Yee-Ling, additional, Misra-Bhattacharya, Shailja, additional, Rao, Ramakrishna, additional, Sadzewicz, Lisa, additional, Saeung, Atiporn, additional, Shahab, Mohd, additional, Sparklin, Benjamin C., additional, Steven, Andrew, additional, Turner, Joseph D., additional, Tallon, Luke J., additional, Taylor, Mark J., additional, Moorhead, Andrew R., additional, Michalski, Michelle, additional, Foster, Jeremy M., additional, and Dunning Hotopp, Julie C., additional

Published
2021
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21. Additional file 3 of Comparative Analysis of Genome of Ehrlichia sp. HF, a Model Bacterium to Study Fatal Human Ehrlichiosis

Author

Lin, Mingqun, Qingming Xiong, Chung, Matthew, Daugherty, Sean C., Nagaraj, Sushma, Sengamalay, Naomi, Ott, Sandra, Godinez, Al, Tallon, Luke J., Sadzewicz, Lisa, Fraser, Claire, Hotopp, Julie C. Dunning, and Rikihisa, Yasuko

Abstract

Additional file 3: Table S3. Ehrlichia sp. HF-specific proteins by 2-way comparison analysis

Published
2021
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22. Additional file 4 of Comparative Analysis of Genome of Ehrlichia sp. HF, a Model Bacterium to Study Fatal Human Ehrlichiosis

Author

Lin, Mingqun, Qingming Xiong, Chung, Matthew, Daugherty, Sean C., Nagaraj, Sushma, Sengamalay, Naomi, Ott, Sandra, Godinez, Al, Tallon, Luke J., Sadzewicz, Lisa, Fraser, Claire, Hotopp, Julie C. Dunning, and Rikihisa, Yasuko

Subjects
animal diseases, parasitic diseases, education, bacterial infections and mycoses, health care economics and organizations
Abstract

Additional file 4: Table S4. Internal Repeats of Ehrlichia Tandem Repeat Proteins

Published
2021
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23. Additional file 2 of Comparative Analysis of Genome of Ehrlichia sp. HF, a Model Bacterium to Study Fatal Human Ehrlichiosis

Author

Lin, Mingqun, Qingming Xiong, Chung, Matthew, Daugherty, Sean C., Nagaraj, Sushma, Sengamalay, Naomi, Ott, Sandra, Godinez, Al, Tallon, Luke J., Sadzewicz, Lisa, Fraser, Claire, Hotopp, Julie C. Dunning, and Rikihisa, Yasuko

Abstract

Additional file 2: Table S2. Ehrlichia species-specific proteins by 4-way comparison analysis

Published
2021
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26. Haplotype-resolved diverse human genomes and integrated analysis of structural variation

Author

Ebert, Peter, primary, Audano, Peter A., additional, Zhu, Qihui, additional, Rodriguez-Martin, Bernardo, additional, Porubsky, David, additional, Bonder, Marc Jan, additional, Sulovari, Arvis, additional, Ebler, Jana, additional, Zhou, Weichen, additional, Serra Mari, Rebecca, additional, Yilmaz, Feyza, additional, Zhao, Xuefang, additional, Hsieh, PingHsun, additional, Lee, Joyce, additional, Kumar, Sushant, additional, Lin, Jiadong, additional, Rausch, Tobias, additional, Chen, Yu, additional, Ren, Jingwen, additional, Santamarina, Martin, additional, Höps, Wolfram, additional, Ashraf, Hufsah, additional, Chuang, Nelson T., additional, Yang, Xiaofei, additional, Munson, Katherine M., additional, Lewis, Alexandra P., additional, Fairley, Susan, additional, Tallon, Luke J., additional, Clarke, Wayne E., additional, Basile, Anna O., additional, Byrska-Bishop, Marta, additional, Corvelo, André, additional, Evani, Uday S., additional, Lu, Tsung-Yu, additional, Chaisson, Mark J. P., additional, Chen, Junjie, additional, Li, Chong, additional, Brand, Harrison, additional, Wenger, Aaron M., additional, Ghareghani, Maryam, additional, Harvey, William T., additional, Raeder, Benjamin, additional, Hasenfeld, Patrick, additional, Regier, Allison A., additional, Abel, Haley J., additional, Hall, Ira M., additional, Flicek, Paul, additional, Stegle, Oliver, additional, Gerstein, Mark B., additional, Tubio, Jose M. C., additional, Mu, Zepeng, additional, Li, Yang I., additional, Shi, Xinghua, additional, Hastie, Alex R., additional, Ye, Kai, additional, Chong, Zechen, additional, Sanders, Ashley D., additional, Zody, Michael C., additional, Talkowski, Michael E., additional, Mills, Ryan E., additional, Devine, Scott E., additional, Lee, Charles, additional, Korbel, Jan O., additional, Marschall, Tobias, additional, and Eichler, Evan E., additional

Published
2021
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27. Soluble Sema4D in Plasma of Head and Neck Squamous Cell Carcinoma Patients Is Associated With Underlying Non-Inflamed Tumor Profile

Author

Younis, Rania H., primary, Ghita, Ioana, additional, Elnaggar, Manar, additional, Chaisuparat, Risa, additional, Theofilou, Vasileios Ionas, additional, Dyalram, Donita, additional, Ord, Robert A., additional, Davila, Eduardo, additional, Tallon, Luke J., additional, Papadimitriou, John C., additional, Webb, Tonya J., additional, Bentzen, Søren M., additional, and Lubek, Joshua E., additional

Published
2021
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28. FADU: a Quantification Tool for Prokaryotic Transcriptomic Analyses

Author

Chung, Matthew, primary, Adkins, Ricky S., additional, Mattick, John S. A., additional, Bradwell, Katie R., additional, Shetty, Amol C., additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Fraser, Claire M., additional, Rasko, David A., additional, Mahurkar, Anup, additional, and Dunning Hotopp, Julie C., additional

Published
2021
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30. Sequence and analysis of chromosome 1 of the plant Arabidopsis thaliana

Author

Theologis, Athanasios, Ecker, Joseph R., Palm, Curtis J., Federspiel, Nancy A., Kaul, Samir, White, Owen, Alonso, Jose, Altafi, Hootan, Araujo, Rina, Bowman, Cheryl L., Brooks, Shelise Y., Buehler, Eugen, Chan, April, Chao, Qimin, Chen, Huaming, Cheuk, Rosa F., Chin, Christina W., Chung, Mike K., Conn, Lane, Conway, Aaron B., Conway, Andrew R., Creasy, Todd H., Dewar, Ken, Dunn, Patrick, Etgu, Pelin, Feldblyum, Tamara V., Feng, JiDong, Fong, Betty, Fujii, Claire Y., Gill, John E., Goldsmith, Andrew D., Haas, Brian, Hansen, Nancy F., Hughes, Beth, Huizar, Lucas, Hunter, Jonathan L., Jenkins, Jennifer, Johnson-Hopson, Chanda, Khan, Shehnaz, Khaykin, Elizabeth, Kim, Christopher J., Koo, Hean L., Kremenetskaia, Irina, Kurtz, David B., Kwan, Andrea, Lam, Bao, Langin-Hooper, Stephanie, Lee, Andrew, Lee, Jeong M., Lenz, Catherine A., Li, Joycelyn. H., Li, YaPing, Lin, Xiaoying, Liu, Shirley X., Liu, Zhaoying A., Luros, Jason S., Maiti, Rama, Marziali, Andre, Militscher, Jennifer, Miranda, Molly, Nguyen, Michelle, Nierman, William C., Osborne, Brian I., Pai, Grace, Peterson, Jeremy, Pham, Paul K., Rizzo, Michael, Rooney, Timothy, Rowley, Don, Sakano, Hitomi, Salzberg, Steven L., Schwartz, Jody R., Shinn, Paul, Southwick, Audrey M., Sun, Hui, Tallon, Luke J., Tambunga, Gabriel, Toriumi, Mitsue J., Town, Christopher D., Utterback, Teresa, Van Aken, Susan, Vaysberg, Maria, Vysotskaia, Valentina S., Walker, Michelle, Wu, Dongying, Yu, Guixia, Fraser, Claire M., Venter, J. Craig, and Davis, Ronald W.

Published
2000
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31. An integrated map of genetic variation from 1,092 human genomes

Author

McVean, Gil A., Altshuler, David M., Durbin, Richard M., Abecasis, Gonçalo R., Bentley, David R., Chakravarti, Aravinda, Clark, Andrew G., Donnelly, Peter, Eichler, Evan E., Flicek, Paul, Gabriel, Stacey B., Gibbs, Richard A., Green, Eric D., Hurles, Matthew E., Knoppers, Bartha M., Korbel, Jan O., Lander, Eric S., Lee, Charles, Lehrach, Hans, Mardis, Elaine R., Marth, Gabor T., Nickerson, Deborah A., Schmidt, Jeanette P., Sherry, Stephen T., Wang, Jun, Wilson, Richard K., Dinh, Huyen, Kovar, Christie, Lee, Sandra, Lewis, Lora, Muzny, Donna, Reid, Jeff, Wang, Min, Wang, Jun, Fang, Xiaodong, Guo, Xiaosen, Jian, Min, Jiang, Hui, Jin, Xin, Li, Guoqing, Li, Jingxiang, Li, Yingrui, Li, Zhuo, Liu, Xiao, Lu, Yao, Ma, Xuedi, Su, Zhe, Tai, Shuaishuai, Tang, Meifang, Wang, Bo, Wang, Guangbiao, Wu, Honglong, Wu, Renhua, Yin, Ye, Zhang, Wenwei, Zhao, Jiao, Zhao, Meiru, Zheng, Xiaole, Zhou, Yan, Lander, Eric S., Gabriel, Stacey B., Gupta, Namrata, Flicek, Paul, Clarke, Laura, Leinonen, Rasko, Smith, Richard E., Zheng-Bradley, Xiangqun, Bentley, David R., Grocock, Russell, Humphray, Sean, James, Terena, Kingsbury, Zoya, Lehrach, Hans, Sudbrak, Ralf, Albrecht, Marcus W., Amstislavskiy, Vyacheslav S., Borodina, Tatiana A., Lienhard, Matthias, Mertes, Florian, Sultan, Marc, Timmermann, Bernd, Yaspo, Marie-Laure, Sherry, Stephen T., McVean, Gil A., Mardis, Elaine R., Wilson, Richard K., Fulton, Lucinda, Fulton, Robert, Weinstock, George M., Durbin, Richard M., Balasubramaniam, Senduran, Burton, John, Danecek, Petr, Keane, Thomas M., Kolb-Kokocinski, Anja, McCarthy, Shane, Stalker, James, Quail, Michael, Schmidt, Jeanette P., Davies, Christopher J., Gollub, Jeremy, Webster, Teresa, Wong, Brant, Zhan, Yiping, Auton, Adam, Yu, Fuli, Bainbridge, Matthew, Challis, Danny, Evani, Uday S., Lu, James, Nagaswamy, Uma, Sabo, Aniko, Wang, Yi, Yu, Jin, Coin, Lachlan J. M., Fang, Lin, Li, Qibin, Li, Zhenyu, Lin, Haoxiang, Liu, Binghang, Luo, Ruibang, Qin, Nan, Shao, Haojing, Wang, Bingqiang, Xie, Yinlong, Ye, Chen, Yu, Chang, Zhang, Fan, Zheng, Hancheng, Zhu, Hongmei, Garrison, Erik P., Kural, Deniz, Lee, Wan-Ping, Fung Leong, Wen, Ward, Alistair N., Wu, Jiantao, Zhang, Mengyao, Lee, Charles, Griffin, Lauren, Hsieh, Chih-Heng, Mills, Ryan E., Shi, Xinghua, von Grotthuss, Marcin, Zhang, Chengsheng, Daly, Mark J., DePristo, Mark A., Banks, Eric, Bhatia, Gaurav, Carneiro, Mauricio O., del Angel, Guillermo, Genovese, Giulio, Handsaker, Robert E., Hartl, Chris, McCarroll, Steven A., Nemesh, James C., Poplin, Ryan E., Schaffner, Stephen F., Shakir, Khalid, Yoon, Seungtai C., Lihm, Jayon, Makarov, Vladimir, Jin, Hanjun, Kim, Wook, Cheol Kim, Ki, Korbel, Jan O., Rausch, Tobias, Beal, Kathryn, Cunningham, Fiona, Herrero, Javier, McLaren, William M., Ritchie, Graham R. S., Clark, Andrew G., Gottipati, Srikanth, Keinan, Alon, Rodriguez-Flores, Juan L., Sabeti, Pardis C., Grossman, Sharon R., Tabrizi, Shervin, Tariyal, Ridhi, Cooper, David N., Ball, Edward V., Stenson, Peter D., Barnes, Bret, Bauer, Markus, Keira Cheetham, R., Cox, Tony, Eberle, Michael, Kahn, Scott, Murray, Lisa, Peden, John, Shaw, Richard, Ye, Kai, Batzer, Mark A., Konkel, Miriam K., Walker, Jerilyn A., MacArthur, Daniel G., Lek, Monkol, Sudbrak, Herwig, Ralf, Shriver, Mark D., Bustamante, Carlos D., Byrnes, Jake K., De La Vega, Francisco M., Gravel, Simon, Kenny, Eimear E., Kidd, Jeffrey M., Lacroute, Phil, Maples, Brian K., Moreno-Estrada, Andres, Zakharia, Fouad, Halperin, Eran, Baran, Yael, Craig, David W., Christoforides, Alexis, Homer, Nils, Izatt, Tyler, Kurdoglu, Ahmet A., Sinari, Shripad A., Squire, Kevin, Xiao, Chunlin, Sebat, Jonathan, Bafna, Vineet, Ye, Kenny, Burchard, Esteban G., Hernandez, Ryan D., Gignoux, Christopher R., Haussler, David, Katzman, Sol J., James Kent, W., Howie, Bryan, Ruiz-Linares, Andres, Dermitzakis, Emmanouil T., Lappalainen, Tuuli, Devine, Scott E., Liu, Xinyue, Maroo, Ankit, Tallon, Luke J., Rosenfeld, Jeffrey A., Min Kang, Hyun, Anderson, Paul, Angius, Andrea, Bigham, Abigail, Blackwell, Tom, Busonero, Fabio, Cucca, Francesco, Fuchsberger, Christian, Jones, Chris, Jun, Goo, Li, Yun, Lyons, Robert, Maschio, Andrea, Porcu, Eleonora, Reinier, Fred, Sanna, Serena, Schlessinger, David, Sidore, Carlo, Tan, Adrian, Kate Trost, Mary, Awadalla, Philip, Hodgkinson, Alan, Lunter, Gerton, McVean, Gil A., Marchini, Jonathan L., Myers, Simon, Churchhouse, Claire, Delaneau, Olivier, Gupta-Hinch, Anjali, Iqbal, Zamin, Mathieson, Iain, Rimmer, Andy, Xifara, Dionysia K., Oleksyk, Taras K., Fu, Yunxin, Liu, Xiaoming, Xiong, Momiao, Jorde, Lynn, Witherspoon, David, Xing, Jinchuan, Eichler, Evan E., Browning, Brian L., Alkan, Can, Hajirasouliha, Iman, Hormozdiari, Fereydoun, Ko, Arthur, Sudmant, Peter H., Mardis, Elaine R., Chen, Ken, Chinwalla, Asif, Ding, Li, Dooling, David, Koboldt, Daniel C., McLellan, Michael D., Wallis, John W., Wendl, Michael C., Zhang, Qunyuan, Hurles, Matthew E., Tyler-Smith, Chris, Albers, Cornelis A., Ayub, Qasim, Chen, Yuan, Coffey, Alison J., Colonna, Vincenza, Huang, Ni, Jostins, Luke, Li, Heng, Scally, Aylwyn, Walter, Klaudia, Xue, Yali, Zhang, Yujun, Gerstein, Mark B., Abyzov, Alexej, Balasubramanian, Suganthi, Chen, Jieming, Clarke, Declan, Fu, Yao, Habegger, Lukas, Harmanci, Arif O., Jin, Mike, Khurana, Ekta, Jasmine Mu, Xinmeng, Sisu, Cristina, Lee, Charles, McCarroll, Steven A., Degenhardt, Jeremiah, Korbel, Jan O., Stütz, Adrian M., Church, Deanna, Michaelson, Jacob J., Eichler, Evan E., Hurles, Matthew E., Blackburne, Ben, Lindsay, Sarah J., Ning, Zemin, DePristo, Mark A., Min Kang, Hyun, Mardis, Elaine R., Yu, Fuli, Michelson, Leslie P., Tyler-Smith, Chris, Frankish, Adam, Harrow, Jennifer, Fowler, Gerald, Hale, Walker, Kalra, Divya, Flicek, Paul, Clarke, Laura, Barker, Jonathan, Kelman, Gavin, Kulesha, Eugene, Radhakrishnan, Rajesh, Roa, Asier, Smirnov, Dmitriy, Streeter, Ian, Toneva, Iliana, Vaughan, Brendan, Sherry, Stephen T., Ananiev, Victor, Belaia, Zinaida, Beloslyudtsev, Dimitriy, Bouk, Nathan, Chen, Chao, Cohen, Robert, Cook, Charles, Garner, John, Hefferon, Timothy, Kimelman, Mikhail, Liu, Chunlei, Lopez, John, Meric, Peter, OʼSullivan, Chris, Ostapchuk, Yuri, Phan, Lon, Ponomarov, Sergiy, Schneider, Valerie, Shekhtman, Eugene, Sirotkin, Karl, Slotta, Douglas, Zhang, Hua, Chakravarti, Aravinda, Knoppers, Bartha M., Barnes, Kathleen C., Beiswanger, Christine, Burchard, Esteban G., Bustamante, Carlos D., Cai, Hongyu, Cao, Hongzhi, Durbin, Richard M., Gharani, Neda, Henn, Brenna, Jones, Danielle, Jorde, Lynn, Kaye, Jane S., Kent, Alastair, Kerasidou, Angeliki, Mathias, Rasika, Ossorio, Pilar N., Parker, Michael, Reich, David, Rotimi, Charles N., Royal, Charmaine D., Sandoval, Karla, Su, Yeyang, Sudbrak, Ralf, Tian, Zhongming, Tishkoff, Sarah, Toji, Lorraine H., Tyler-Smith, Chris, Via, Marc, Wang, Yuhong, Yang, Huanming, Yang, Ling, Zhu, Jiayong, Bodmer, Walter, Bedoya, Gabriel, Ruiz-Linares, Andres, Zhi Ming, Cai, Yang, Gao, Jia You, Chu, Peltonen, Leena, Garcia-Montero, Andres, Orfao, Alberto, Dutil, Julie, Martinez-Cruzado, Juan C., Oleksyk, Taras K., Brooks, Lisa D., Felsenfeld, Adam L., McEwen, Jean E., Clemm, Nicholas C., Duncanson, Audrey, Dunn, Michael, Guyer, Mark S., Peterson, Jane L., Abecasis, Goncalo R., and Auton, Adam

Published
2012
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32. De novo assembly of 64 haplotype-resolved human genomes of diverse ancestry and integrated analysis of structural variation

Author

Ebert, Peter, primary, Audano, Peter A., additional, Zhu, Qihui, additional, Rodriguez-Martin, Bernardo, additional, Porubsky, David, additional, Bonder, Marc Jan, additional, Sulovari, Arvis, additional, Ebler, Jana, additional, Zhou, Weichen, additional, Mari, Rebecca Serra, additional, Yilmaz, Feyza, additional, Zhao, Xuefang, additional, Hsieh, PingHsun, additional, Lee, Joyce, additional, Kumar, Sushant, additional, Lin, Jiadong, additional, Rausch, Tobias, additional, Chen, Yu, additional, Ren, Jingwen, additional, Santamarina, Martin, additional, Höps, Wolfram, additional, Ashraf, Hufsah, additional, Chuang, Nelson T., additional, Yang, Xiaofei, additional, Munson, Katherine M., additional, Lewis, Alexandra P., additional, Fairley, Susan, additional, Tallon, Luke J., additional, Clarke, Wayne E., additional, Basile, Anna O., additional, Byrska-Bishop, Marta, additional, Corvelo, André, additional, Chaisson, Mark J.P., additional, Chen, Junjie, additional, Li, Chong, additional, Brand, Harrison, additional, Wenger, Aaron M., additional, Ghareghani, Maryam, additional, Harvey, William T., additional, Raeder, Benjamin, additional, Hasenfeld, Patrick, additional, Regier, Allison, additional, Abel, Haley, additional, Hall, Ira, additional, Flicek, Paul, additional, Stegle, Oliver, additional, Gerstein, Mark B., additional, Tubio, Jose M.C., additional, Mu, Zepeng, additional, Li, Yang I., additional, Shi, Xinghua, additional, Hastie, Alex R., additional, Ye, Kai, additional, Chong, Zechen, additional, Sanders, Ashley D., additional, Zody, Michael C., additional, Talkowski, Michael E., additional, Mills, Ryan E., additional, Devine, Scott E., additional, Lee, Charles, additional, Korbel, Jan O., additional, Marschall, Tobias, additional, and Eichler, Evan E., additional

Published
2020
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33. Complete Mitochondrial Genome Sequence of Mansonella perstans

Author

Chung, Matthew, primary, Aluvathingal, Jain, additional, Bromley, Robin E., additional, Nadendla, Suvarna, additional, Fombad, Fanny F., additional, Kien, Chi A., additional, Gandjui, Narcisse V. T., additional, Njouendou, Abdel J., additional, Ritter, Manuel, additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Wanji, Samuel, additional, Hoerauf, Achim, additional, Pfarr, Kenneth, additional, and Dunning Hotopp, Julie C., additional

Published
2020
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35. Nearly Complete Genome Sequence of Brugia pahangi FR3

Author

Mattick, John, primary, Libro, Silvia, additional, Sparklin, Benjamin C., additional, Chung, Matthew, additional, Bromley, Robin E., additional, Nadendla, Suvarna, additional, Zhao, Xuechu, additional, Ott, Sandra, additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Michalski, Michelle L., additional, Foster, Jeremy M., additional, and Dunning Hotopp, Julie C., additional

Published
2020
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36. Complete Genome Sequence of w Bp, the Wolbachia Endosymbiont of Brugia pahangi FR3

Author

Lebov, Jarrett F., primary, Mattick, John, additional, Libro, Silvia, additional, Sparklin, Benjamin C., additional, Chung, Matthew, additional, Bromley, Robin E., additional, Nadendla, Suvarna, additional, Zhao, Xuechu, additional, Ott, Sandra, additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Michalski, Michelle L., additional, Foster, Jeremy M., additional, and Dunning Hotopp, Julie C., additional

Published
2020
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39. Sequence and analysis of chromosome 2 of the plant Arabidopsis thaliana

Author

Lin, Xiaoying, Kaul, Samir, Rounsley, Steve, Shea, Terrance P., Benito, Maria-Ines, Town, Christopher D., Fujii, claire Y., Mason, Tanya, Bowman, Cheryl L., Barnstead, Mary, Feldblyum, Tamara V., Buell, C. Robin, Ketchum, Karen A., Lee, John, Ronning, Catherine M., Koo, Hean L., Moffat, Kelly S., Cronin, Lisa A., Shen, Mian, Pai, Grace, Aken, Susan Van, Umayam, Lowell, Tallon, Luke J., Gill, John E., Adams, Mark D., Carrera, Ana J., Creasy, Todd H., Goodman, Howard M., Somerville, Chris R., Copenhaver, Greg P., Preuss, Daphne, Nierman, William C., White, Owen, Eisen, Jonathan A., Salzberg, Steven L., Fraser, Claire M., and Venter, J. Craig

Subjects
Arabidopsis thaliana -- Genetic aspects, Plant chromosomes -- Research, Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

It has been possible to identify the sequence of chromosome 2 from the Columbia ecotype of Arabidopsis thaliana in two gap-free assemblies of 3.6 Mb and 16 Mb. The two assemblies terminate in blocks of 180-bp repeats, with the repeats representing the inner boundaries of the completed sequence. Within the genetically defined centromere, there is a stretch of 270 kb of sequence that is almost identical to that of the Arabidopsis mitochondrial gene. It cannot be established whether the observed sequence polymorphisms are the result of divergence of the insertion from the mitochondrial genome or of differences among ecotypes.

Published
1999

40. The R1 resistance gene cluster contains three groups of independently evolving, type I R1 homologues and shows substantial structural variation among haplotypes of Solanum demissum

Author

Kuang, Hanhui, Wei, Fusheng, Marano, María Rosa, Wirtz, Uwe, Wang, Xiaoxue, Liu, Jia, Shum, Wai Pun, Zaborsky, Jennifer, Tallon, Luke J., Rensink, Willem, Lobst, Stacey, Zhang, Peifen, Tornqvist, Carl-Erik, Tek, Ahmet, Bamberg, John, Helgeson, John, Fry, William, You, Frank, Luo, Ming-Cheng, Jiang, Jiming, Buell, C. Robin, and Baker, Barbara

Published
2005

41. Efficient subtraction of insect rRNA prior to transcriptome analysis of Wolbachia-Drosophila lateral gene transfer

Author

Kumar Nikhil, Creasy Todd, Sun Yezhou, Flowers Melissa, Tallon Luke J, and Dunning Hotopp Julie C

Subjects
Wolbachia, Drosophila ananassae, RNASeq, Transcriptomics, Lateral gene transfer, Horizontal gene transfer, Endosymbiont, Insect vector, Medicine, Biology (General), QH301-705.5, Science (General), Q1-390
Abstract

Abstract Background Numerous methods exist for enriching bacterial or mammalian mRNA prior to transcriptome experiments. Yet there persists a need for methods to enrich for mRNA in non-mammalian animal systems. For example, insects contain many important and interesting obligate intracellular bacteria, including endosymbionts and vector-borne pathogens. Such obligate intracellular bacteria are difficult to study by traditional methods. Therefore, genomics has greatly increased our understanding of these bacteria. Efficient subtraction methods are needed for removing both bacteria and insect rRNA in these systems to enable transcriptome-based studies. Findings A method is described that efficiently removes >95% of insect rRNA from total RNA samples, as determined by microfluidics and transcriptome sequencing. This subtraction yielded a 6.2-fold increase in mRNA abundance. Such a host rRNA-depletion strategy, in combination with bacterial rRNA depletion, is necessary to analyze transcription of obligate intracellular bacteria. Here, transcripts were identified that arise from a lateral gene transfer of an entire Wolbachia bacterial genome into a Drosophila ananassae chromosome. In this case, an rRNA depletion strategy is preferred over polyA-based enrichment since transcripts arising from bacteria-to-animal lateral gene transfer may not be poly-adenylated. Conclusions This enrichment method yields a significant increase in mRNA abundance when poly-A selection is not suitable. It can be used in combination with bacterial rRNA subtraction to enable experiments to simultaneously measure bacteria and insect mRNA in vector and endosymbiont biology experiments.

Published
2012
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42. Drug Repurposing of Bromodomain Inhibitors as Potential Novel Therapeutic Leads for Lymphatic Filariasis Guided by Multispecies Transcriptomics

Author

Chung, Matthew, primary, Teigen, Laura E., additional, Libro, Silvia, additional, Bromley, Robin E., additional, Olley, Dustin, additional, Kumar, Nikhil, additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Mahurkar, Anup, additional, Foster, Jeremy M., additional, Michalski, Michelle L., additional, and Dunning Hotopp, Julie C., additional

Published
2019
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43. Strains used in whole organismPlasmodium falciparumvaccine trials differ in genome structure, sequence, and immunogenic potential

Author

Moser, Kara A., primary, Drábek, Elliott F., additional, Dwivedi, Ankit, additional, Crabtree, Jonathan, additional, Stucke, Emily M., additional, Dara, Antoine, additional, Shah, Zalak, additional, Adams, Matthew, additional, Li, Tao, additional, Rodrigues, Priscila T., additional, Koren, Sergey, additional, Phillippy, Adam M., additional, Ouattara, Amed, additional, Lyke, Kirsten E., additional, Sadzewicz, Lisa, additional, Tallon, Luke J., additional, Spring, Michele D., additional, Jongsakul, Krisada, additional, Lon, Chanthap, additional, Saunders, David L., additional, Ferreira, Marcelo U., additional, Nyunt, Myaing M., additional, Laufer, Miriam K., additional, Travassos, Mark A., additional, Sauerwein, Robert W., additional, Takala-Harrison, Shannon, additional, Fraser, Claire M., additional, Sim, B. Kim Lee, additional, Hoffman, Stephen L., additional, Plowe, Christopher V., additional, and Silva, Joana C., additional

Published
2019
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44. Intratumor genetic heterogeneity in squamous cell carcinoma of the oral cavity

Author

Zandberg, Dan P., primary, Tallon, Luke J., additional, Nagaraj, Sushma, additional, Sadzewicz, Lisa K., additional, Zhang, Yuji, additional, Strome, Maxwell B., additional, Zhao, Xuechu E., additional, Vavikolanu, Kranthi, additional, Zhang, Xiaoyu, additional, Papadimitriou, John C., additional, Hubbard, Fleesie A., additional, Bentzen, Søren M., additional, Strome, Scott E., additional, and Fraser, Claire M., additional

Published
2019
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45. Refined annotation and assembly of the Tetrahymena thermophila genome sequence through EST analysis, comparative genomic hybridization, and targeted gap closure

Author

Lee Suzanne R, Collins Kathleen, Smith Joshua J, Wiley Emily A, Cassidy-Hanley Donna M, Haas Brian J, Tallon Luke J, Wortman Jennifer R, Jones Kristie M, Thiagarajan Mathangi, Coyne Robert S, Couvillion Mary T, Liu Yifan, Garg Jyoti, Pearlman Ronald E, Hamilton Eileen P, Orias Eduardo, Eisen Jonathan A, and Methé Barbara A

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background Tetrahymena thermophila, a widely studied model for cellular and molecular biology, is a binucleated single-celled organism with a germline micronucleus (MIC) and somatic macronucleus (MAC). The recent draft MAC genome assembly revealed low sequence repetitiveness, a result of the epigenetic removal of invasive DNA elements found only in the MIC genome. Such low repetitiveness makes complete closure of the MAC genome a feasible goal, which to achieve would require standard closure methods as well as removal of minor MIC contamination of the MAC genome assembly. Highly accurate preliminary annotation of Tetrahymena's coding potential was hindered by the lack of both comparative genomic sequence information from close relatives and significant amounts of cDNA evidence, thus limiting the value of the genomic information and also leaving unanswered certain questions, such as the frequency of alternative splicing. Results We addressed the problem of MIC contamination using comparative genomic hybridization with purified MIC and MAC DNA probes against a whole genome oligonucleotide microarray, allowing the identification of 763 genome scaffolds likely to contain MIC-limited DNA sequences. We also employed standard genome closure methods to essentially finish over 60% of the MAC genome. For the improvement of annotation, we have sequenced and analyzed over 60,000 verified EST reads from a variety of cellular growth and development conditions. Using this EST evidence, a combination of automated and manual reannotation efforts led to updates that affect 16% of the current protein-coding gene models. By comparing EST abundance, many genes showing apparent differential expression between these conditions were identified. Rare instances of alternative splicing and uses of the non-standard amino acid selenocysteine were also identified. Conclusion We report here significant progress in genome closure and reannotation of Tetrahymena thermophila. Our experience to date suggests that complete closure of the MAC genome is attainable. Using the new EST evidence, automated and manual curation has resulted in substantial improvements to the over 24,000 gene models, which will be valuable to researchers studying this model organism as well as for comparative genomics purposes.

Published
2008
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46. Structure and evolution of a proviral locus of Glyptapanteles indiensis bracovirus

Author

Fadrosh Douglas W, Pedroni Monica J, Schatz Michael C, Fuester Roger W, Tallon Luke J, Hostetler Jessica B, Gundersen-Rindal Dawn E, Desjardins Christopher A, Haas Brian J, Toms Bradley S, Chen Dan, and Nene Vishvanath

Subjects
Microbiology, QR1-502
Abstract

Abstract Background Bracoviruses (BVs), a group of double-stranded DNA viruses with segmented genomes, are mutualistic endosymbionts of parasitoid wasps. Virus particles are replication deficient and are produced only by female wasps from proviral sequences integrated into the wasp genome. Virus particles are injected along with eggs into caterpillar hosts, where viral gene expression facilitates parasitoid survival and therefore perpetuation of proviral DNA. Here we describe a 223 kbp region of Glyptapanteles indiensis genomic DNA which contains a part of the G. indiensis bracovirus (GiBV) proviral genome. Results Eighteen of ~24 GiBV viral segment sequences are encoded by 7 non-overlapping sets of BAC clones, revealing that some proviral segment sequences are separated by long stretches of intervening DNA. Two overlapping BACs, which contain a locus of 8 tandemly arrayed proviral segments flanked on either side by ~35 kbp of non-packaged DNA, were sequenced and annotated. Structural and compositional analyses of this cluster revealed it exhibits a G+C and nucleotide composition distinct from the flanking DNA. By analyzing sequence polymorphisms in the 8 GiBV viral segment sequences, we found evidence for widespread selection acting on both protein-coding and non-coding DNA. Comparative analysis of viral and proviral segment sequences revealed a sequence motif involved in the excision of proviral genome segments which is highly conserved in two other bracoviruses. Conclusion Contrary to current concepts of bracovirus proviral genome organization our results demonstrate that some but not all GiBV proviral segment sequences exist in a tandem array. Unexpectedly, non-coding DNA in the 8 proviral genome segments which typically occupies ~70% of BV viral genomes is under selection pressure suggesting it serves some function(s). We hypothesize that selection acting on GiBV proviral sequences maintains the genetic island-like nature of the cluster of proviral genome segments described herein. In contrast to large differences in the predicted gene composition of BV genomes, sequences that appear to mediate processes of viral segment formation, such as proviral segment excision and circularization, appear to be highly conserved, supporting the hypothesis of a single origin for BVs.

Published
2007
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47. Complete plastid genome sequence of Daucus carota: Implications for biotechnology and phylogeny of angiosperms

Author

Ruhlman Tracey, Lee Seung-Bum, Jansen Robert K, Hostetler Jessica B, Tallon Luke J, Town Christopher D, and Daniell Henry

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background Carrot (Daucus carota) is a major food crop in the US and worldwide. Its capacity for storage and its lifecycle as a biennial make it an attractive species for the introduction of foreign genes, especially for oral delivery of vaccines and other therapeutic proteins. Until recently efforts to express recombinant proteins in carrot have had limited success in terms of protein accumulation in the edible tap roots. Plastid genetic engineering offers the potential to overcome this limitation, as demonstrated by the accumulation of BADH in chromoplasts of carrot taproots to confer exceedingly high levels of salt resistance. The complete plastid genome of carrot provides essential information required for genetic engineering. Additionally, the sequence data add to the rapidly growing database of plastid genomes for assessing phylogenetic relationships among angiosperms. Results The complete carrot plastid genome is 155,911 bp in length, with 115 unique genes and 21 duplicated genes within the IR. There are four ribosomal RNAs, 30 distinct tRNA genes and 18 intron-containing genes. Repeat analysis reveals 12 direct and 2 inverted repeats ≥ 30 bp with a sequence identity ≥ 90%. Phylogenetic analysis of nucleotide sequences for 61 protein-coding genes using both maximum parsimony (MP) and maximum likelihood (ML) were performed for 29 angiosperms. Phylogenies from both methods provide strong support for the monophyly of several major angiosperm clades, including monocots, eudicots, rosids, asterids, eurosids II, euasterids I, and euasterids II. Conclusion The carrot plastid genome contains a number of dispersed direct and inverted repeats scattered throughout coding and non-coding regions. This is the first sequenced plastid genome of the family Apiaceae and only the second published genome sequence of the species-rich euasterid II clade. Both MP and ML trees provide very strong support (100% bootstrap) for the sister relationship of Daucus with Panax in the euasterid II clade. These results provide the best taxon sampling of complete chloroplast genomes and the strongest support yet for the sister relationship of Caryophyllales to the asterids. The availability of the complete plastid genome sequence should facilitate improved transformation efficiency and foreign gene expression in carrot through utilization of endogenous flanking sequences and regulatory elements.

Published
2006
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48. The complete chloroplast genome sequence of Gossypium hirsutum: organization and phylogenetic relationships to other angiosperms

Author

Town Christopher D, Tallon Luke J, Hostetler Jessica B, Jansen Robert K, Kaittanis Charalambos, Lee Seung-Bum, and Daniell Henry

Subjects
Biotechnology, TP248.13-248.65, Genetics, QH426-470
Abstract

Abstract Background Cotton (Gossypium hirsutum) is the most important fiber crop grown in 90 countries. In 2004–2005, US farmers planted 79% of the 5.7-million hectares of nuclear transgenic cotton. Unfortunately, genetically modified cotton has the potential to hybridize with other cultivated and wild relatives, resulting in geographical restrictions to cultivation. However, chloroplast genetic engineering offers the possibility of containment because of maternal inheritance of transgenes. The complete chloroplast genome of cotton provides essential information required for genetic engineering. In addition, the sequence data were used to assess phylogenetic relationships among the major clades of rosids using cotton and 25 other completely sequenced angiosperm chloroplast genomes. Results The complete cotton chloroplast genome is 160,301 bp in length, with 112 unique genes and 19 duplicated genes within the IR, containing a total of 131 genes. There are four ribosomal RNAs, 30 distinct tRNA genes and 17 intron-containing genes. The gene order in cotton is identical to that of tobacco but lacks rpl22 and infA. There are 30 direct and 24 inverted repeats 30 bp or longer with a sequence identity ≥ 90%. Most of the direct repeats are within intergenic spacer regions, introns and a 72 bp-long direct repeat is within the psaA and psaB genes. Comparison of protein coding sequences with expressed sequence tags (ESTs) revealed nucleotide substitutions resulting in amino acid changes in ndhC, rpl23, rpl20, rps3 and clpP. Phylogenetic analysis of a data set including 61 protein-coding genes using both maximum likelihood and maximum parsimony were performed for 28 taxa, including cotton and five other angiosperm chloroplast genomes that were not included in any previous phylogenies. Conclusion Cotton chloroplast genome lacks rpl22 and infA and contains a number of dispersed direct and inverted repeats. RNA editing resulted in amino acid changes with significant impact on their hydropathy. Phylogenetic analysis provides strong support for the position of cotton in the Malvales in the eurosids II clade sister to Arabidopsis in the Brassicales. Furthermore, there is strong support for the placement of the Myrtales sister to the eurosid I clade, although expanded taxon sampling is needed to further test this relationship.

Published
2006
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