Your search keyword '"Kaithakottil, G."' showing total 21 results

1. Chromosome-level genome sequence of the Genetically Improved Farmed Tilapia (GIFT, Oreochromis niloticus) highlights regions of introgression with O. mossambicus

Author

Etherington, G. J., Nash, W., Ciezarek, A., Mehta, T. K., Barria, A., Peñaloza, C., Khan, M. G. Q., Durrant, A., Forrester, N., Fraser, F., Irish, N., Kaithakottil, G. G., Lipscombe, J., Trong, T., Watkins, C., Swarbreck, D., Angiolini, E., Cnaani, A., Gharbi, K., Houston, R. D., Benzie, J. A. H., and Haerty, W.

Published

2022

2. Additional file 2 of Chromosome-level genome sequence of the Genetically Improved Farmed Tilapia (GIFT, Oreochromis niloticus) highlights regions of introgression with O. mossambicus

Author

Etherington, G. J., Nash, W., Ciezarek, A., Mehta, T. K., Barria, A., Peñaloza, C., Khan, M. G. Q., Durrant, A., Forrester, N., Fraser, F., Irish, N., Kaithakottil, G. G., Lipscombe, J., Trong, T., Watkins, C., Swarbreck, D., Angiolini, E., Cnaani, A., Gharbi, K., Houston, R. D., Benzie, J. A. H., and Haerty, W.

Abstract

Additional file 2: Supplementary Figure 1. Comparison of genomic and genetic positions of the SNP markers of the genetic map.

Published

2023

3. Additional file 4 of Chromosome-level genome sequence of the Genetically Improved Farmed Tilapia (GIFT, Oreochromis niloticus) highlights regions of introgression with O. mossambicus

Author

Etherington, G. J., Nash, W., Ciezarek, A., Mehta, T. K., Barria, A., Peñaloza, C., Khan, M. G. Q., Durrant, A., Forrester, N., Fraser, F., Irish, N., Kaithakottil, G. G., Lipscombe, J., Trong, T., Watkins, C., Swarbreck, D., Angiolini, E., Cnaani, A., Gharbi, K., Houston, R. D., Benzie, J. A. H., and Haerty, W.

Abstract

Additional file 4: Supplementary Figure 2. Phylogenetic representation across genomes of species as estimated by TWISST. A) Relative weighting of each phylogeny across the O. niloticus UMD genome assembly. The colours refer to the phylogenies provided in panel B. B) Normalized weights across the O. niloticus UMD genome assembly for the three different phylogenies.

Published

2023

4. Additional file 5 of Chromosome-level genome sequence of the Genetically Improved Farmed Tilapia (GIFT, Oreochromis niloticus) highlights regions of introgression with O. mossambicus

Author

Etherington, G. J., Nash, W., Ciezarek, A., Mehta, T. K., Barria, A., Peñaloza, C., Khan, M. G. Q., Durrant, A., Forrester, N., Fraser, F., Irish, N., Kaithakottil, G. G., Lipscombe, J., Trong, T., Watkins, C., Swarbreck, D., Angiolini, E., Cnaani, A., Gharbi, K., Houston, R. D., Benzie, J. A. H., and Haerty, W.

Abstract

Additional file 5: Supplementary Figure 3. A). Phylogenetic representation across LG3 of species as estimated by TWISST. B) Normalized weights across LG3 for the different phylogenies.

Published

2023

5. Additional file 7 of Chromosome-level genome sequence of the Genetically Improved Farmed Tilapia (GIFT, Oreochromis niloticus) highlights regions of introgression with O. mossambicus

Author

Etherington, G. J., Nash, W., Ciezarek, A., Mehta, T. K., Barria, A., Peñaloza, C., Khan, M. G. Q., Durrant, A., Forrester, N., Fraser, F., Irish, N., Kaithakottil, G. G., Lipscombe, J., Trong, T., Watkins, C., Swarbreck, D., Angiolini, E., Cnaani, A., Gharbi, K., Houston, R. D., Benzie, J. A. H., and Haerty, W.

Abstract

Additional file 7: Supplementary Figure 4. Gene Ontology analysis (Molecular Function, Cellular Components, KEGG Pathway) for the genes identified within O. mossambicus introgressed regions.

Published

2023

6. Shifting the limits in wheat research and breeding using a fully annotated reference genome

Author

Appels, R., Eversole, K., Feuillet, C., Keller, B., Rogers, J., Stein, N., Pozniak, C.J., Choulet, F., Distelfeld, A., Poland, J., Ronen, G., Barad, O., Baruch, K., Keeble-Gagnère, G., Mascher, M., Sharpe, A.G., Ben-Zvi, G., Josselin, A-A, Himmelbach, A., Balfourier, F., Gutierrez-Gonzalez, J., Hayden, M., Koh, C., Muehlbauer, G., Pasam, R.K., Paux, E., Rigault, P., Tibbits, J., Tiwari, V., Spannagl, M., Lang, D., Gundlach, H., Haberer, G., Mayer, K.F.X., Ormanbekova, D., Prade, V., Šimková, H., Wicker, T., Swarbreck, D., Rimbert, H., Felder, M., Guilhot, N., Kaithakottil, G., Keilwagen, J., Leroy, P., Lux, T., Twardziok, S., Venturini, L., Juhász, A., Abrouk, M., Fischer, I., Uauy, C., Borrill, P., Ramirez-Gonzalez, R.H., Arnaud, D., Chalabi, S., Chalhoub, B., Cory, A., Datla, R., Davey, M.W., Jacobs, J., Robinson, S.J., Steuernagel, B., van Ex, F., Wulff, B.B.H., Benhamed, M., Bendahmane, A., Concia, L., Latrasse, D., Alaux, M., Bartoš, J., Bellec, A., Berges, H., Doležel, J., Frenkel, Z., Gill, B., Korol, A., Letellier, T., Olsen, O-A, Singh, K., Valárik, M., van der Vossen, E., Vautrin, S., Weining, S., Fahima, T., Glikson, V., Raats, D., Číhalíková, J., Toegelová, H., Vrána, J., Sourdille, P., Darrier, B., Barabaschi, D., Cattivelli, L., Hernandez, P., Galvez, S., Budak, H., Jones, J.D.G., Witek, K., Yu, G., Small, I., Melonek, J., Zhou, R., Belova, T., Kanyuka, K., King, R., Nilsen, K., Walkowiak, S., Cuthbert, R., Knox, R., Wiebe, K., Xiang, D., Rohde, A., Gold, T., Čížková, J., Akpinar, B.A., Biyiklioglu, S., Gao, L., N’Daiye, A., Kubaláková, M., Šafář, J., Alfama, F., Adam-Blondon, A-F, Flores, R., Guerche, C., Loaec, M., Quesneville, H., Condie, J., Ens, J., Koh, C.S., Maclachlan, R., Tan, Y., Alberti, A., Aury, J-M, Barbe, V., Couloux, A., Cruaud, C., Labadie, K., Mangenot, S., Wincker, P., Kaur, G., Luo, M., Sehgal, S., Chhuneja, P., Gupta, O.P., Jindal, S., Kaur, P., Malik, P., Sharma, P., Yadav, B., Singh, N.K., Khurana, J.P., Chaudhary, C., Khurana, P., Kumar, V., Mahato, A., Mathur, S., Sevanthi, A., Sharma, N., Tomar, R.S., Holušová, K., Plíhal, O., Clark, M.D., Heavens, D., Kettleborough, G., Wright, J., Balcárková, B., Hu, Y., Salina, E., Ravin, N., Skryabin, K., Beletsky, A., Kadnikov, V., Mardanov, A., Nesterov, M., Rakitin, A., Sergeeva, E., Handa, H., Kanamori, H., Katagiri, S., Kobayashi, F., Nasuda, S., Tanaka, T., Wu, J., Cattonaro, F., Jiumeng, M., Kugler, K.G., Pfeifer, M., Sandve, S., Xun, X., Zhan, B., Batley, J., Bayer, P.E., Edwards, D., Hayashi, S., Tulpová, Z., Visendi, P., Cui, L., Du, X., Feng, K., Nie, X., Tong, W., Wang, L., Appels, R., Eversole, K., Feuillet, C., Keller, B., Rogers, J., Stein, N., Pozniak, C.J., Choulet, F., Distelfeld, A., Poland, J., Ronen, G., Barad, O., Baruch, K., Keeble-Gagnère, G., Mascher, M., Sharpe, A.G., Ben-Zvi, G., Josselin, A-A, Himmelbach, A., Balfourier, F., Gutierrez-Gonzalez, J., Hayden, M., Koh, C., Muehlbauer, G., Pasam, R.K., Paux, E., Rigault, P., Tibbits, J., Tiwari, V., Spannagl, M., Lang, D., Gundlach, H., Haberer, G., Mayer, K.F.X., Ormanbekova, D., Prade, V., Šimková, H., Wicker, T., Swarbreck, D., Rimbert, H., Felder, M., Guilhot, N., Kaithakottil, G., Keilwagen, J., Leroy, P., Lux, T., Twardziok, S., Venturini, L., Juhász, A., Abrouk, M., Fischer, I., Uauy, C., Borrill, P., Ramirez-Gonzalez, R.H., Arnaud, D., Chalabi, S., Chalhoub, B., Cory, A., Datla, R., Davey, M.W., Jacobs, J., Robinson, S.J., Steuernagel, B., van Ex, F., Wulff, B.B.H., Benhamed, M., Bendahmane, A., Concia, L., Latrasse, D., Alaux, M., Bartoš, J., Bellec, A., Berges, H., Doležel, J., Frenkel, Z., Gill, B., Korol, A., Letellier, T., Olsen, O-A, Singh, K., Valárik, M., van der Vossen, E., Vautrin, S., Weining, S., Fahima, T., Glikson, V., Raats, D., Číhalíková, J., Toegelová, H., Vrána, J., Sourdille, P., Darrier, B., Barabaschi, D., Cattivelli, L., Hernandez, P., Galvez, S., Budak, H., Jones, J.D.G., Witek, K., Yu, G., Small, I., Melonek, J., Zhou, R., Belova, T., Kanyuka, K., King, R., Nilsen, K., Walkowiak, S., Cuthbert, R., Knox, R., Wiebe, K., Xiang, D., Rohde, A., Gold, T., Čížková, J., Akpinar, B.A., Biyiklioglu, S., Gao, L., N’Daiye, A., Kubaláková, M., Šafář, J., Alfama, F., Adam-Blondon, A-F, Flores, R., Guerche, C., Loaec, M., Quesneville, H., Condie, J., Ens, J., Koh, C.S., Maclachlan, R., Tan, Y., Alberti, A., Aury, J-M, Barbe, V., Couloux, A., Cruaud, C., Labadie, K., Mangenot, S., Wincker, P., Kaur, G., Luo, M., Sehgal, S., Chhuneja, P., Gupta, O.P., Jindal, S., Kaur, P., Malik, P., Sharma, P., Yadav, B., Singh, N.K., Khurana, J.P., Chaudhary, C., Khurana, P., Kumar, V., Mahato, A., Mathur, S., Sevanthi, A., Sharma, N., Tomar, R.S., Holušová, K., Plíhal, O., Clark, M.D., Heavens, D., Kettleborough, G., Wright, J., Balcárková, B., Hu, Y., Salina, E., Ravin, N., Skryabin, K., Beletsky, A., Kadnikov, V., Mardanov, A., Nesterov, M., Rakitin, A., Sergeeva, E., Handa, H., Kanamori, H., Katagiri, S., Kobayashi, F., Nasuda, S., Tanaka, T., Wu, J., Cattonaro, F., Jiumeng, M., Kugler, K.G., Pfeifer, M., Sandve, S., Xun, X., Zhan, B., Batley, J., Bayer, P.E., Edwards, D., Hayashi, S., Tulpová, Z., Visendi, P., Cui, L., Du, X., Feng, K., Nie, X., Tong, W., and Wang, L.

Abstract

Wheat is one of the major sources of food for much of the world. However, because bread wheat's genome is a large hybrid mix of three separate subgenomes, it has been difficult to produce a high-quality reference sequence. Using recent advances in sequencing, the International Wheat Genome Sequencing Consortium presents an annotated reference genome with a detailed analysis of gene content among subgenomes and the structural organization for all the chromosomes. Examples of quantitative trait mapping and CRISPR-based genome modification show the potential for using this genome in agricultural research and breeding. Ramírez-González et al. exploited the fruits of this endeavor to identify tissue-specific biased gene expression and coexpression networks during development and exposure to stress. These resources will accelerate our understanding of the genetic basis of bread wheat.

Published

2018

7. Rapid transcriptional plasticity of duplicated gene clusters enables a clonally reproducing aphid to colonise diverse plant species

Author

Tc, Mathers, Chen Y, Kaithakottil G, Legeai F, Sam Mugford, Baa-Puyoulet P, Bretaudeau A, Clavijo B, Colella S, Collin O, Dalmay T, Derrien T, Feng H, Gabaldón T, Jordan A, Julca I, Gj, Kettles, Kowitwanich K, Lavenier D, and Lenzi P

8. A haplotype-resolved chromosome-level genome assembly of Urochloa decumbens cv. Basilisk resolves its allopolyploid ancestry and composition.

Author

Ryan C, Fraser F, Irish N, Barker T, Knitlhoffer V, Durrant A, Reynolds G, Kaithakottil G, Swarbreck D, and De Vega JJ

Abstract

Haplotyped-resolved phased assemblies aim to capture the full allelic diversity in heterozygous and polyploid species to enable accurate genetic analyses. However, building non-collapsed references still presents a challenge. Here, we used long-range interaction Hi-C reads (high-throughput chromatin conformation capture) and HiFi PacBio reads to assemble the genome of the apomictic cultivar Basilisks from Urochloa decumbens (2n = 4x = 36), an outcrossed tetraploid Paniceae grass widely cropped to feed livestock in the tropics. We identified and removed Hi-C reads between homologous unitigs to facilitate their scaffolding and employed methods for the manual curation of rearrangements and misassemblies. Our final phased assembly included the four haplotypes in 36 chromosomes. We found that 18 chromosomes originated from diploid U. brizantha and the other 18 from either U. ruziziensis or diploid U. decumbens. We also identified a chromosomal translocation between chromosomes 5 and 32, as well as evidence of pairing exclusively within subgenomes, except for a homoeologous exchange in chromosome 21. Our results demonstrate that haplotype-aware assemblies accurately capture the allelic diversity in heterozygous species, making them the preferred option over collapsed-haplotype assemblies., (© The Author(s) 2025. Published by Oxford University Press on behalf of The Genetics Society of America.)

Published

2025

9. Nuclear and Mitochondrial Genome Assemblies for the Endangered Wood-Decaying Fungus Somion occarium.

Author

Hill R, McGowan J, Brabcová V, McTaggart S, Irish N, Barker T, Knitlhoffer V, Lucchini S, Baker K, Catchpole L, Watkins C, Gharbi K, Kaithakottil G, Tracey A, Wood JMD, Tomšovský M, Baldrian P, Swarbreck D, and Hall N

Subjects

Endangered Species, Wood microbiology, Genome, Mitochondrial, Genome, Fungal, Phylogeny

Abstract

Somion occarium is a wood-decaying bracket fungus belonging to an order known to be rich in useful chemical compounds. Despite its widespread distribution, S. occarium has been assessed as endangered on at least 1 national Red List, presumably due to loss of old-growth forest habitat. Here, we present a near-complete, annotated nuclear genome assembly for S. occarium consisting of 31 Mbp arranged in 11 pseudochromosomes-9 of which are telomere-to-telomere-as well as a complete mitochondrial genome assembly of 112.9 Kbp. We additionally performed phylogenomic analysis and annotated carbohydrate-active enzymes (CAZymes) to compare gene and CAZyme content across closely related species. This genome was sequenced as the representative for Kingdom Fungi in the European Reference Genome Atlas Pilot Project., (© The Author(s) 2025. Published by Oxford University Press on behalf of Society for Molecular Biology and Evolution.)

Published

2025

10. Chromosome-scale genome assembly and de novo annotation of Alopecurus aequalis.

Author

Wright J, Baker K, Barker T, Catchpole L, Durrant A, Fraser F, Gharbi K, Harrison C, Henderson S, Irish N, Kaithakottil G, Leitch IJ, Li J, Lucchini S, Neve P, Powell R, Rees H, Swarbreck D, Watkins C, Wood J, McTaggart S, Hall A, and MacGregor D

Subjects

Chromosomes, Plant genetics, Hordeum genetics, Molecular Sequence Annotation, Genome, Plant, Poaceae genetics

Abstract

Alopecurus aequalis is a winter annual or short-lived perennial bunchgrass which has in recent years emerged as the dominant agricultural weed of barley and wheat in certain regions of China and Japan, causing significant yield losses. Its robust tillering capacity and high fecundity, combined with the development of both target and non-target-site resistance to herbicides means it is a formidable challenge to food security. Here we report on a chromosome-scale assembly of A. aequalis with a genome size of 2.83 Gb. The genome contained 33,758 high-confidence protein-coding genes with functional annotation. Comparative genomics revealed that the genome structure of A. aequalis is more similar to Hordeum vulgare rather than the more closely related Alopecurus myosuroides., Competing Interests: Competing interests: The authors declare no competing interests., (© 2024. The Author(s).)

Published

2024

11. The genome sequence of the Violet Carpenter Bee, Xylocopa violacea (Linnaeus, 1785): a hymenopteran species undergoing range expansion.

Author

Nash WJ, Man A, McTaggart S, Baker K, Barker T, Catchpole L, Durrant A, Gharbi K, Irish N, Kaithakottil G, Ku D, Providence A, Shaw F, Swarbreck D, Watkins C, McCartney AM, Formenti G, Mouton A, Vella N, von Reumont BM, Vella A, and Haerty W

Subjects

Animals, Bees genetics, Male, Genome, Insect, Molecular Sequence Annotation, Sequence Analysis, DNA methods, Genome, Mitochondrial

Abstract

We present a reference genome assembly from an individual male Violet Carpenter Bee (Xylocopa violacea, Linnaeus 1758). The assembly is 1.02 gigabases in span. 48% of the assembly is scaffolded into 17 pseudo-chromosomal units. The mitochondrial genome has also been assembled and is 21.8 kilobases in length. The genome is highly repetitive, likely representing a highly heterochromatic architecture expected of bees from the genus Xylocopa. We also use an evidence-based methodology to annotate 10,152 high confidence coding genes. This genome was sequenced as part of the pilot project of the European Reference Genome Atlas (ERGA) and represents an important addition to the genomic resources available for Hymenoptera., Competing Interests: Competing interests: The authors declare no competing interests. Research Ethics statement: No approval of research ethics committees was required to accomplish the goals of this study because experimental work was conducted with an unregulated invertebrate species., (© 2024. The Author(s).)

Published

2024

12. Chromosome-scale genome assembly provides insights into rye biology, evolution and agronomic potential.

Author

Rabanus-Wallace MT, Hackauf B, Mascher M, Lux T, Wicker T, Gundlach H, Baez M, Houben A, Mayer KFX, Guo L, Poland J, Pozniak CJ, Walkowiak S, Melonek J, Praz CR, Schreiber M, Budak H, Heuberger M, Steuernagel B, Wulff B, Börner A, Byrns B, Čížková J, Fowler DB, Fritz A, Himmelbach A, Kaithakottil G, Keilwagen J, Keller B, Konkin D, Larsen J, Li Q, Myśków B, Padmarasu S, Rawat N, Sesiz U, Biyiklioglu-Kaya S, Sharpe A, Šimková H, Small I, Swarbreck D, Toegelová H, Tsvetkova N, Voylokov AV, Vrána J, Bauer E, Bolibok-Bragoszewska H, Doležel J, Hall A, Jia J, Korzun V, Laroche A, Ma XF, Ordon F, Özkan H, Rakoczy-Trojanowska M, Scholz U, Schulman AH, Siekmann D, Stojałowski S, Tiwari VK, Spannagl M, and Stein N

Subjects

Adaptation, Physiological genetics, Crops, Agricultural genetics, Crops, Agricultural immunology, Gene Expression Regulation, Plant, Genetic Introgression, Karyotype, Plant Immunity genetics, Plant Proteins metabolism, Secale immunology, Stress, Physiological, Chromosome Mapping methods, Genome, Plant, Plant Breeding methods, Plant Proteins genetics, Secale genetics, Triticum genetics

Abstract

Rye (Secale cereale L.) is an exceptionally climate-resilient cereal crop, used extensively to produce improved wheat varieties via introgressive hybridization and possessing the entire repertoire of genes necessary to enable hybrid breeding. Rye is allogamous and only recently domesticated, thus giving cultivated ryes access to a diverse and exploitable wild gene pool. To further enhance the agronomic potential of rye, we produced a chromosome-scale annotated assembly of the 7.9-gigabase rye genome and extensively validated its quality by using a suite of molecular genetic resources. We demonstrate applications of this resource with a broad range of investigations. We present findings on cultivated rye's incomplete genetic isolation from wild relatives, mechanisms of genome structural evolution, pathogen resistance, low-temperature tolerance, fertility control systems for hybrid breeding and the yield benefits of rye-wheat introgressions.

Published

2021

13. Sex-specific changes in the aphid DNA methylation landscape.

Author

Mathers TC, Mugford ST, Percival-Alwyn L, Chen Y, Kaithakottil G, Swarbreck D, Hogenhout SA, and van Oosterhout C

Subjects

Animals, Female, Gene Expression Profiling, Gene Expression Regulation, Genome, Insect, Male, X Chromosome genetics, Aphids genetics, DNA Methylation genetics, Sex Characteristics

Abstract

Aphids present an ideal system to study epigenetics as they can produce diverse, but genetically identical, morphs in response to environmental stimuli. Here, using whole genome bisulphite sequencing and transcriptome sequencing of the green peach aphid (Myzus persicae), we present the first detailed analysis of cytosine methylation in an aphid and investigate differences in the methylation and transcriptional landscapes of male and asexual female morphs. We found that methylation primarily occurs in a CG dinucleotide (CpG) context and that exons are highly enriched for methylated CpGs, particularly at the 3' end of genes. Methylation is positively associated with gene expression, and methylated genes are more stably expressed than unmethylated genes. Male and asexual female morphs have distinct methylation profiles. Strikingly, these profiles are divergent between the sex chromosome and the autosomes; autosomal genes are hypomethylated in males compared to asexual females, whereas genes belonging to the sex chromosome, which is haploid in males, are hypermethylated. Overall, we found correlated changes in methylation and gene expression between males and asexual females, and this correlation was particularly strong for genes located on the sex chromosome. Our results suggest that differential methylation of sex-biased genes plays a role in aphid sexual differentiation., (© 2019 The Authors. Molecular Ecology published by John Wiley & Sons Ltd.)

Published

2019

14. Efficient and accurate detection of splice junctions from RNA-seq with Portcullis.

Author

Mapleson D, Venturini L, Kaithakottil G, and Swarbreck D

Subjects

Animals, Arabidopsis genetics, Databases, Genetic, Drosophila genetics, High-Throughput Nucleotide Sequencing, Humans, RNA chemistry, RNA Splice Sites genetics, Sequence Analysis, RNA, RNA metabolism, RNA Splicing, Software

Abstract

Next-generation sequencing technologies enable rapid and cheap genome-wide transcriptome analysis, providing vital information about gene structure, transcript expression, and alternative splicing. Key to this is the accurate identification of exon-exon junctions from RNA sequenced (RNA-seq) reads. A number of RNA-seq aligners capable of splitting reads across these splice junctions (SJs) have been developed; however, it has been shown that while they correctly identify most genuine SJs available in a given sample, they also often produce large numbers of incorrect SJs. Here, we describe the extent of this problem using popular RNA-seq mapping tools and present a new method, called Portcullis, to rapidly filter false SJs derived from spliced alignments. We show that Portcullis distinguishes between genuine and false-positive junctions to a high degree of accuracy across different species, samples, expression levels, error profiles, and read lengths. Portcullis is portable, efficient, and, to our knowledge, currently the only SJ prediction tool that reliably scales for use with large RNA-seq datasets and large, highly fragmented genomes, while delivering accurate SJs.

Published

2018

15. The ash dieback invasion of Europe was founded by two genetically divergent individuals.

Author

McMullan M, Rafiqi M, Kaithakottil G, Clavijo BJ, Bilham L, Orton E, Percival-Alwyn L, Ward BJ, Edwards A, Saunders DGO, Garcia Accinelli G, Wright J, Verweij W, Koutsovoulos G, Yoshida K, Hosoya T, Williamson L, Jennings P, Ioos R, Husson C, Hietala AM, Vivian-Smith A, Solheim H, MaClean D, Fosker C, Hall N, Brown JKM, Swarbreck D, Blaxter M, Downie JA, and Clark MD

Subjects

Europe, Haplotypes genetics, Ascomycota genetics, Fraxinus microbiology, Genome, Fungal, Plant Diseases microbiology

Abstract

Accelerating international trade and climate change make pathogen spread an increasing concern. Hymenoscyphus fraxineus, the causal agent of ash dieback, is a fungal pathogen that has been moving across continents and hosts from Asian to European ash. Most European common ash trees (Fraxinus excelsior) are highly susceptible to H. fraxineus, although a minority (~5%) have partial resistance to dieback. Here, we assemble and annotate a H. fraxineus draft genome, which approaches chromosome scale. Pathogen genetic diversity across Europe and in Japan, reveals a strong bottleneck in Europe, though a signal of adaptive diversity remains in key host interaction genes. We find that the European population was founded by two divergent haploid individuals. Divergence between these haplotypes represents the ancestral polymorphism within a large source population. Subsequent introduction from this source would greatly increase adaptive potential of the pathogen. Thus, further introgression of H. fraxineus into Europe represents a potential threat and Europe-wide biological security measures are needed to manage this disease.

Published

2018

16. An improved assembly and annotation of the allohexaploid wheat genome identifies complete families of agronomic genes and provides genomic evidence for chromosomal translocations.

Author

Clavijo BJ, Venturini L, Schudoma C, Accinelli GG, Kaithakottil G, Wright J, Borrill P, Kettleborough G, Heavens D, Chapman H, Lipscombe J, Barker T, Lu FH, McKenzie N, Raats D, Ramirez-Gonzalez RH, Coince A, Peel N, Percival-Alwyn L, Duncan O, Trösch J, Yu G, Bolser DM, Namaati G, Kerhornou A, Spannagl M, Gundlach H, Haberer G, Davey RP, Fosker C, Palma FD, Phillips AL, Millar AH, Kersey PJ, Uauy C, Krasileva KV, Swarbreck D, Bevan MW, and Clark MD

Subjects

Algorithms, Contig Mapping standards, Molecular Sequence Annotation standards, Polymorphism, Genetic, Polyploidy, Contig Mapping methods, Genome, Plant, Molecular Sequence Annotation methods, Plant Proteins genetics, Translocation, Genetic, Triticum genetics

Abstract

Advances in genome sequencing and assembly technologies are generating many high-quality genome sequences, but assemblies of large, repeat-rich polyploid genomes, such as that of bread wheat, remain fragmented and incomplete. We have generated a new wheat whole-genome shotgun sequence assembly using a combination of optimized data types and an assembly algorithm designed to deal with large and complex genomes. The new assembly represents >78% of the genome with a scaffold N50 of 88.8 kb that has a high fidelity to the input data. Our new annotation combines strand-specific Illumina RNA-seq and Pacific Biosciences (PacBio) full-length cDNAs to identify 104,091 high-confidence protein-coding genes and 10,156 noncoding RNA genes. We confirmed three known and identified one novel genome rearrangements. Our approach enables the rapid and scalable assembly of wheat genomes, the identification of structural variants, and the definition of complete gene models, all powerful resources for trait analysis and breeding of this key global crop., (© 2017 Clavijo et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2017

17. Erratum to: Rapid transcriptional plasticity of duplicated gene clusters enables a clonally reproducing aphid to colonise diverse plant species.

Author

Mathers TC, Chen Y, Kaithakottil G, Legeai F, Mugford ST, Baa-Puyoulet P, Bretaudeau A, Clavijo B, Colella S, Collin O, Dalmay T, Derrien T, Feng H, Gabaldón T, Jordan A, Julca I, Kettles GJ, Kowitwanich K, Lavenier D, Lenzi P, Lopez-Gomollon S, Loska D, Mapleson D, Maumus F, Moxon S, Price DR, Sugio A, van Munster M, Uzest M, Waite D, Jander G, Tagu D, Wilson AC, van Oosterhout C, Swarbreck D, and Hogenhout SA

Published

2017

18. Rapid transcriptional plasticity of duplicated gene clusters enables a clonally reproducing aphid to colonise diverse plant species.

Author

Mathers TC, Chen Y, Kaithakottil G, Legeai F, Mugford ST, Baa-Puyoulet P, Bretaudeau A, Clavijo B, Colella S, Collin O, Dalmay T, Derrien T, Feng H, Gabaldón T, Jordan A, Julca I, Kettles GJ, Kowitwanich K, Lavenier D, Lenzi P, Lopez-Gomollon S, Loska D, Mapleson D, Maumus F, Moxon S, Price DR, Sugio A, van Munster M, Uzest M, Waite D, Jander G, Tagu D, Wilson AC, van Oosterhout C, Swarbreck D, and Hogenhout SA

Abstract

Background: The prevailing paradigm of host-parasite evolution is that arms races lead to increasing specialisation via genetic adaptation. Insect herbivores are no exception and the majority have evolved to colonise a small number of closely related host species. Remarkably, the green peach aphid, Myzus persicae, colonises plant species across 40 families and single M. persicae clonal lineages can colonise distantly related plants. This remarkable ability makes M. persicae a highly destructive pest of many important crop species., Results: To investigate the exceptional phenotypic plasticity of M. persicae, we sequenced the M. persicae genome and assessed how one clonal lineage responds to host plant species of different families. We show that genetically identical individuals are able to colonise distantly related host species through the differential regulation of genes belonging to aphid-expanded gene families. Multigene clusters collectively upregulate in single aphids within two days upon host switch. Furthermore, we demonstrate the functional significance of this rapid transcriptional change using RNA interference (RNAi)-mediated knock-down of genes belonging to the cathepsin B gene family. Knock-down of cathepsin B genes reduced aphid fitness, but only on the host that induced upregulation of these genes., Conclusions: Previous research has focused on the role of genetic adaptation of parasites to their hosts. Here we show that the generalist aphid pest M. persicae is able to colonise diverse host plant species in the absence of genetic specialisation. This is achieved through rapid transcriptional plasticity of genes that have duplicated during aphid evolution.

Published

2017

19. Genome sequence and genetic diversity of European ash trees.

Author

Sollars ES, Harper AL, Kelly LJ, Sambles CM, Ramirez-Gonzalez RH, Swarbreck D, Kaithakottil G, Cooper ED, Uauy C, Havlickova L, Worswick G, Studholme DJ, Zohren J, Salmon DL, Clavijo BJ, Li Y, He Z, Fellgett A, McKinney LV, Nielsen LR, Douglas GC, Kjær ED, Downie JA, Boshier D, Lee S, Clark J, Grant M, Bancroft I, Caccamo M, and Buggs RJ

Subjects

Ascomycota pathogenicity, Conserved Sequence genetics, Denmark, Fraxinus microbiology, Genes, Plant genetics, Genomics, Iridoid Glycosides metabolism, Plant Diseases microbiology, Plant Diseases prevention & control, Plant Proteins genetics, Population Density, Sequence Analysis, DNA, Species Specificity, Transcriptome, Trees microbiology, United Kingdom, Fraxinus genetics, Genetic Predisposition to Disease genetics, Genetic Variation, Genome, Plant genetics, Plant Diseases genetics, Trees genetics

Abstract

Ash trees (genus Fraxinus, family Oleaceae) are widespread throughout the Northern Hemisphere, but are being devastated in Europe by the fungus Hymenoscyphus fraxineus, causing ash dieback, and in North America by the herbivorous beetle Agrilus planipennis. Here we sequence the genome of a low-heterozygosity Fraxinus excelsior tree from Gloucestershire, UK, annotating 38,852 protein-coding genes of which 25% appear ash specific when compared with the genomes of ten other plant species. Analyses of paralogous genes suggest a whole-genome duplication shared with olive (Olea europaea, Oleaceae). We also re-sequence 37 F. excelsior trees from Europe, finding evidence for apparent long-term decline in effective population size. Using our reference sequence, we re-analyse association transcriptomic data, yielding improved markers for reduced susceptibility to ash dieback. Surveys of these markers in British populations suggest that reduced susceptibility to ash dieback may be more widespread in Great Britain than in Denmark. We also present evidence that susceptibility of trees to H. fraxineus is associated with their iridoid glycoside levels. This rapid, integrated, multidisciplinary research response to an emerging health threat in a non-model organism opens the way for mitigation of the epidemic.

Published

2017

20. Oakleaf: an S locus-linked mutation of Primula vulgaris that affects leaf and flower development.

Author

Cocker JM, Webster MA, Li J, Wright J, Kaithakottil G, Swarbreck D, and Gilmartin PM

Subjects

Chromosome Mapping, DNA, Plant analysis, Databases, Genetic, Gene Expression, Genotype, Molecular Sequence Data, Plant Development genetics, Primula growth & development, Transcriptome, Flowers growth & development, Genes, Plant, Genetic Loci, Mutation, Phenotype, Plant Leaves growth & development, Primula genetics

Abstract

In Primula vulgaris outcrossing is promoted through reciprocal herkogamy with insect-mediated cross-pollination between pin and thrum form flowers. Development of heteromorphic flowers is coordinated by genes at the S locus. To underpin construction of a genetic map facilitating isolation of these S locus genes, we have characterised Oakleaf, a novel S locus-linked mutant phenotype. We combine phenotypic observation of flower and leaf development, with classical genetic analysis and next-generation sequencing to address the molecular basis of Oakleaf. Oakleaf is a dominant mutation that affects both leaf and flower development; plants produce distinctive lobed leaves, with occasional ectopic meristems on the veins. This phenotype is reminiscent of overexpression of Class I KNOX-homeodomain transcription factors. We describe the structure and expression of all eight P. vulgaris PvKNOX genes in both wild-type and Oakleaf plants, and present comparative transcriptome analysis of leaves and flowers from Oakleaf and wild-type plants. Oakleaf provides a new phenotypic marker for genetic analysis of the Primula S locus. We show that none of the Class I PvKNOX genes are strongly upregulated in Oakleaf leaves and flowers, and identify cohorts of 507 upregulated and 314 downregulated genes in the Oakleaf mutant., (© 2015 The Authors. New Phytologist © 2015 New Phytologist Trust.)

Published

2015

21. High-resolution transcriptional analysis of the regulatory influence of cell-to-cell signalling reveals novel genes that contribute to Xanthomonas phytopathogenesis.

Author

An SQ, Febrer M, McCarthy Y, Tang DJ, Clissold L, Kaithakottil G, Swarbreck D, Tang JL, Rogers J, Dow JM, and Ryan RP

Subjects

Bacterial Proteins genetics, Gene Deletion, Gene Expression Profiling, Genes, Bacterial, Transcription Factors metabolism, Virulence Factors biosynthesis, Xanthomonas campestris genetics, Bacterial Proteins metabolism, Gene Expression Regulation, Bacterial, Host-Pathogen Interactions, Plant Diseases microbiology, Signal Transduction, Xanthomonas campestris pathogenicity

Abstract

The bacterium Xanthomonas campestris is an economically important pathogen of many crop species and a model for the study of bacterial phytopathogenesis. In X. campestris, a regulatory system mediated by the signal molecule DSF controls virulence to plants. The synthesis and recognition of the DSF signal depends upon different Rpf proteins. DSF signal generation requires RpfF whereas signal perception and transduction depends upon a system comprising the sensor RpfC and regulator RpfG. Here we have addressed the action and role of Rpf/DSF signalling in phytopathogenesis by high-resolution transcriptional analysis coupled to functional genomics. We detected transcripts for many genes that were unidentified by previous computational analysis of the genome sequence. Novel transcribed regions included intergenic transcripts predicted as coding or non-coding as well as those that were antisense to coding sequences. In total, mutation of rpfF, rpfG and rpfC led to alteration in transcript levels (more than fourfold) of approximately 480 genes. The regulatory influence of RpfF and RpfC demonstrated considerable overlap. Contrary to expectation, the regulatory influence of RpfC and RpfG had limited overlap, indicating complexities of the Rpf signalling system. Importantly, functional analysis revealed over 160 new virulence factors within the group of Rpf-regulated genes., (© 2013 The Authors. Molecular Microbiology published by John Wiley & Sons Ltd.)

Published

2013