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Author Report for: Saunders D

Title: The zebrafish reference genome sequence and its relationship to the human genome
Howe K, Clark MD, Torroja CF, Torrance J, Berthelot C, Muffato M, Collins JE, Humphray S, McLaren K and Stemple DL <167 more author(s)> Howe K, Clark MD, Torroja CF, Torrance J, Berthelot C, Muffato M, Collins JE, Humphray S, McLaren K, Matthews L, Mclaren S, Sealy I, Caccamo M, Churcher C, Scott C, Barrett JC, Koch R, Rauch GJ, White S, Chow W, Kilian B, Quintais LT, Guerra-Assuncao JA, Zhou Y, Gu Y, Yen J, Vogel JH, Eyre T, Redmond S, Banerjee R, Chi J, Fu B, Langley E, Maguire SF, Laird GK, Lloyd D, Kenyon E, Donaldson S, Sehra H, Almeida-King J, Loveland J, Trevanion S, Jones M, Quail M, Willey D, Hunt A, Burton J, Sims S, McLay K, Plumb B, Davis J, Clee C, Oliver K, Clark R, Riddle C, Elliot D, Threadgold G, Harden G, Ware D, Begum S, Mortimore B, Kerry G, Heath P, Phillimore B, Tracey A, Corby N, Dunn M, Johnson C, Wood J, Clark S, Pelan S, Griffiths G, Smith M, Glithero R, Howden P, Barker N, Lloyd C, Stevens C, Harley J, Holt K, Panagiotidis G, Lovell J, Beasley H, Henderson C, Gordon D, Auger K, Wright D, Collins J, Raisen C, Dyer L, Leung K, Robertson L, Ambridge K, Leongamornlert D, McGuire S, Gilderthorp R, Griffiths C, Manthravadi D, Nichol S, Barker G, Whitehead S, Kay M, Brown J, Murnane C, Gray E, Humphries M, Sycamore N, Barker D, Saunders D, Wallis J, Babbage A, Hammond S, Mashreghi-Mohammadi M, Barr L, Martin S, Wray P, Ellington A, Matthews N, Ellwood M, Woodmansey R, Clark G, Cooper J, Tromans A, Grafham D, Skuce C, Pandian R, Andrews R, Harrison E, Kimberley A, Garnett J, Fosker N, Hall R, Garner P, Kelly D, Bird C, Palmer S, Gehring I, Berger A, Dooley CM, Ersan-Urun Z, Eser C, Geiger H, Geisler M, Karotki L, Kirn A, Konantz J, Konantz M, Oberlander M, Rudolph-Geiger S, Teucke M, Lanz C, Raddatz G, Osoegawa K, Zhu B, Rapp A, Widaa S, Langford C, Yang F, Schuster SC, Carter NP, Harrow J, Ning Z, Herrero J, Searle SM, Enright A, Geisler R, Plasterk RH, Lee C, Westerfield M, de Jong PJ, Zon LI, Postlethwait JH, Nusslein-Volhard C, Hubbard TJ, Roest Crollius H, Rogers J, Stemple DL (- 167)
Ref: Nature, 496:498, 2013 : PubMed
Abstract


ESTHER: Howe_2013_Nature_496_498
PubMedSearch: Howe 2013 Nature 496 498
PubMedID: 23594743
Gene_locus related to this paper: danre-1neur, danre-ABHD10b, danre-a9jrf7, danre-d2x2g3, danre-e7ezq9, danre-e7ff77, danre-ndr3, danre-nlgn4a, danre-q1mti5, danre-q6nyz4, danre-q6p2u2, danre-q7t359, danre-q08c93, danre-A2BGU9, danre-f1q676, danre-e7f0z8, danre-e7ez27, danre-e7f2w1, danre-f1qid7, danre-a0a0g2kru2, danre-f1qla7, danre-a9jr90, danre-e7f070, danre-f172a, danre-e7fb35, danre-a7mbu9, danre-f1qtr2

Abstract

Zebrafish have become a popular organism for the study of vertebrate gene function. The virtually transparent embryos of this species, and the ability to accelerate genetic studies by gene knockdown or overexpression, have led to the widespread use of zebrafish in the detailed investigation of vertebrate gene function and increasingly, the study of human genetic disease. However, for effective modelling of human genetic disease it is important to understand the extent to which zebrafish genes and gene structures are related to orthologous human genes. To examine this, we generated a high-quality sequence assembly of the zebrafish genome, made up of an overlapping set of completely sequenced large-insert clones that were ordered and oriented using a high-resolution high-density meiotic map. Detailed automatic and manual annotation provides evidence of more than 26,000 protein-coding genes, the largest gene set of any vertebrate so far sequenced. Comparison to the human reference genome shows that approximately 70% of human genes have at least one obvious zebrafish orthologue. In addition, the high quality of this genome assembly provides a clearer understanding of key genomic features such as a unique repeat content, a scarcity of pseudogenes, an enrichment of zebrafish-specific genes on chromosome 4 and chromosomal regions that influence sex determination.



        

Title: Complete genome sequence and comparative genome analysis of enteropathogenic Escherichia coli O127:H6 strain E2348/69
Iguchi A, Thomson NR, Ogura Y, Saunders D, Ooka T, Henderson IR, Harris D, Asadulghani M, Kurokawa K and Frankel G <7 more author(s)> Iguchi A, Thomson NR, Ogura Y, Saunders D, Ooka T, Henderson IR, Harris D, Asadulghani M, Kurokawa K, Dean P, Kenny B, Quail MA, Thurston S, Dougan G, Hayashi T, Parkhill J, Frankel G (- 7)
Ref: Journal of Bacteriology, 191:347, 2009 : PubMed
Abstract


ESTHER: Iguchi_2009_J.Bacteriol_191_347
PubMedSearch: Iguchi 2009 J.Bacteriol 191 347
PubMedID: 18952797
Gene_locus related to this paper: ecoli-Aes, ecoli-rutD, ecoli-bioh, ecoli-C0410, ecoli-C4836, ecoli-dlhh, ecoli-entf, ecoli-fes, ecoli-pldb, ecoli-ptrb, ecoli-yafa, ecoli-yaim, ecoli-ybff, ecoli-ycfp, ecoli-ycjy, ecoli-yeiG, ecoli-YFBB, ecoli-yghX, ecoli-yhet, ecoli-yiel, ecoli-yjfp, ecoli-ypfh, ecoli-ypt1, ecoli-yqia, ecoli-YfhR

Abstract

Enteropathogenic Escherichia coli (EPEC) was the first pathovar of E. coli to be implicated in human disease; however, no EPEC strain has been fully sequenced until now. Strain E2348/69 (serotype O127:H6 belonging to E. coli phylogroup B2) has been used worldwide as a prototype strain to study EPEC biology, genetics, and virulence. Studies of E2348/69 led to the discovery of the locus of enterocyte effacement-encoded type III secretion system (T3SS) and its cognate effectors, which play a vital role in attaching and effacing lesion formation on gut epithelial cells. In this study, we determined the complete genomic sequence of E2348/69 and performed genomic comparisons with other important E. coli strains. We identified 424 E2348/69-specific genes, most of which are carried on mobile genetic elements, and a number of genetic traits specifically conserved in phylogroup B2 strains irrespective of their pathotypes, including the absence of the ETT2-related T3SS, which is present in E. coli strains belonging to all other phylogroups. The genome analysis revealed the entire gene repertoire related to E2348/69 virulence. Interestingly, E2348/69 contains only 21 intact T3SS effector genes, all of which are carried on prophages and integrative elements, compared to over 50 effector genes in enterohemorrhagic E. coli O157. As E2348/69 is the most-studied pathogenic E. coli strain, this study provides a genomic context for the vast amount of existing experimental data. The unexpected simplicity of the E2348/69 T3SS provides the first opportunity to fully dissect the entire virulence strategy of attaching and effacing pathogens in the genomic context.



        

Title: Comparative genomics of the fungal pathogens Candida dubliniensis and Candida albicans
Jackson AP, Gamble JA, Yeomans T, Moran GP, Saunders D, Harris D, Aslett M, Barrell JF, Butler G and Berriman M <16 more author(s)> Jackson AP, Gamble JA, Yeomans T, Moran GP, Saunders D, Harris D, Aslett M, Barrell JF, Butler G, Citiulo F, Coleman DC, de Groot PW, Goodwin TJ, Quail MA, McQuillan J, Munro CA, Pain A, Poulter RT, Rajandream MA, Renauld H, Spiering MJ, Tivey A, Gow NA, Barrell B, Sullivan DJ, Berriman M (- 16)
Ref: Genome Res, 19:2231, 2009 : PubMed
Abstract


ESTHER: Jackson_2009_Genome.Res_19_2231
PubMedSearch: Jackson 2009 Genome.Res 19 2231
PubMedID: 19745113
Gene_locus related to this paper: canal-ATG15, canal-c4yl13, canal-ppme1, canal-q5a0c9, canal-q5ad17, canal-q5ady2, canal-q5ag57, canal-q5ai12, canal-q5akz5, canal-q5apu4, canal-q59m48, canal-q59nw6, candc-b9w8x6, candc-b9w8x7, candc-b9w905, candc-b9wa64, candc-b9wc27, candc-b9wc30, candc-b9wc93, candc-b9wce3, candc-b9wdh9, candc-b9wds3, candc-b9whs3, candc-b9whs6, candc-b9whv2, candc-b9wi60, candc-b9wid3, candc-b9wje5, candc-b9wk97, candc-CduLAc, candc-b9wkf5, candc-b9wkj1, candc-b9wlf0, candc-b9wmt8, candc-b9wmx4, candc-b9wc51, candc-b9wa43, candc-b9wl19, candc-kex1

Abstract

Candida dubliniensis is the closest known relative of Candida albicans, the most pathogenic yeast species in humans. However, despite both species sharing many phenotypic characteristics, including the ability to form true hyphae, C. dubliniensis is a significantly less virulent and less versatile pathogen. Therefore, to identify C. albicans-specific genes that may be responsible for an increased capacity to cause disease, we have sequenced the C. dubliniensis genome and compared it with the known C. albicans genome sequence. Although the two genome sequences are highly similar and synteny is conserved throughout, 168 species-specific genes are identified, including some encoding known hyphal-specific virulence factors, such as the aspartyl proteinases Sap4 and Sap5 and the proposed invasin Als3. Among the 115 pseudogenes confirmed in C. dubliniensis are orthologs of several filamentous growth regulator (FGR) genes that also have suspected roles in pathogenesis. However, the principal differences in genomic repertoire concern expansion of the TLO gene family of putative transcription factors and the IFA family of putative transmembrane proteins in C. albicans, which represent novel candidate virulence-associated factors. The results suggest that the recent evolutionary histories of C. albicans and C. dubliniensis are quite different. While gene families instrumental in pathogenesis have been elaborated in C. albicans, C. dubliniensis has lost genomic capacity and key pathogenic functions. This could explain why C. albicans is a more potent pathogen in humans than C. dubliniensis.



        

Title: Newly introduced genomic prophage islands are critical determinants of in vivo competitiveness in the Liverpool Epidemic Strain of Pseudomonas aeruginosa
Winstanley C, Langille MG, Fothergill JL, Kukavica-Ibrulj I, Paradis-Bleau C, Sanschagrin F, Thomson NR, Winsor GL, Quail MA and Levesque RC <9 more author(s)> Winstanley C, Langille MG, Fothergill JL, Kukavica-Ibrulj I, Paradis-Bleau C, Sanschagrin F, Thomson NR, Winsor GL, Quail MA, Lennard N, Bignell A, Clarke L, Seeger K, Saunders D, Harris D, Parkhill J, Hancock RE, Brinkman FS, Levesque RC (- 9)
Ref: Genome Res, 19:12, 2009 : PubMed
Abstract


ESTHER: Winstanley_2009_Genome.Res_19_12
PubMedSearch: Winstanley 2009 Genome.Res 19 12
PubMedID: 19047519
Gene_locus related to this paper: pseae-clipa, pseae-CPO, pseae-llipa, pseae-metx, pseae-PA0201, pseae-PA0231, pseae-PA0308, pseae-PA0368, pseae-PA0480, pseae-PA0502, pseae-PA0543, pseae-PA0599, pseae-PA1166, pseae-PA1291, pseae-PA1304, pseae-PA1510, pseae-PA1558, pseae-PA1597, pseae-PA1907, pseae-PA2086, pseae-PA2098, pseae-PA2302, pseae-PA2425, pseae-PA2451, pseae-PA2540, pseae-PA2682, pseae-PA2689, pseae-PA2745, pseae-PA2764, pseae-PA2927, pseae-PA2934, pseae-PA2949, pseae-PA3132, pseae-PA3301, pseae-PA3324, pseae-PA3327, pseae-PA3429, pseae-PA3586, pseae-PA3628, pseae-PA3695, pseae-PA3859, pseae-PA3994, pseae-PA4152, pseae-PA4968, pseae-PA5080, pseae-PCHC, pseae-PCHF, pseae-PHAC2, pseae-phaD, pseae-phag, pseae-Q9APW4, pseae-rhla, pseae-q9i252

Abstract

Pseudomonas aeruginosa isolates have a highly conserved core genome representing up to 90% of the total genomic sequence with additional variable accessory genes, many of which are found in genomic islands or islets. The identification of the Liverpool Epidemic Strain (LES) in a children's cystic fibrosis (CF) unit in 1996 and its subsequent observation in several centers in the United Kingdom challenged the previous widespread assumption that CF patients acquire only unique strains of P. aeruginosa from the environment. To learn about the forces that shaped the development of this important epidemic strain, the genome of the earliest archived LES isolate, LESB58, was sequenced. The sequence revealed the presence of many large genomic islands, including five prophage clusters, one defective (pyocin) prophage cluster, and five non-phage islands. To determine the role of these clusters, an unbiased signature tagged mutagenesis study was performed, followed by selection in the chronic rat lung infection model. Forty-seven mutants were identified by sequencing, including mutants in several genes known to be involved in Pseudomonas infection. Furthermore, genes from four prophage clusters and one genomic island were identified and in direct competition studies with the parent isolate; four were demonstrated to strongly impact on competitiveness in the chronic rat lung infection model. This strongly indicates that enhanced in vivo competitiveness is a major driver for maintenance and diversifying selection of these genomic prophage genes.



        

Title: The complete genome, comparative and functional analysis of Stenotrophomonas maltophilia reveals an organism heavily shielded by drug resistance determinants
Crossman LC, Gould VC, Dow JM, Vernikos GS, Okazaki A, Sebaihia M, Saunders D, Arrowsmith C, Carver T and Avison MB <15 more author(s)> Crossman LC, Gould VC, Dow JM, Vernikos GS, Okazaki A, Sebaihia M, Saunders D, Arrowsmith C, Carver T, Peters N, Adlem E, Kerhornou A, Lord A, Murphy L, Seeger K, Squares R, Rutter S, Quail MA, Rajandream MA, Harris D, Churcher C, Bentley SD, Parkhill J, Thomson NR, Avison MB (- 15)
Ref: Genome Biol, 9:R74, 2008 : PubMed
Abstract


ESTHER: Crossman_2008_Genome.Biol_9_R74
PubMedSearch: Crossman 2008 Genome.Biol 9 R74
PubMedID: 18419807
Gene_locus related to this paper: strm5-b4sjf3, strm5-b4sly1, strm5-b4smq6, strm5-b4st20, strm5-bioh, strmk-b2fhb1, strmk-b2fju9, strmk-b2fkx8, strmk-b2fl50, strmk-b2fl54, strmk-b2flj0, strmk-b2fnc5, strmk-b2fre3, strmk-b2frm1, strmk-b2frs0, strmk-b2fsp0, strmk-b2ftw9, strmk-b2fuf3, strmk-metx, xanma-P95782, strmk-b2fmj5, strmk-b2fpy9, strmk-b2ftk7, strmk-b2frv5

Abstract

BACKGROUND: Stenotrophomonas maltophilia is a nosocomial opportunistic pathogen of the Xanthomonadaceae. The organism has been isolated from both clinical and soil environments in addition to the sputum of cystic fibrosis patients and the immunocompromised. Whilst relatively distant phylogenetically, the closest sequenced relatives of S. maltophilia are the plant pathogenic xanthomonads. RESULTS: The genome of the bacteremia-associated isolate S. maltophilia K279a is 4,851,126 bp and of high G+C content. The sequence reveals an organism with a remarkable capacity for drug and heavy metal resistance. In addition to a number of genes conferring resistance to antimicrobial drugs of different classes via alternative mechanisms, nine resistance-nodulation-division (RND)-type putative antimicrobial efflux systems are present. Functional genomic analysis confirms a role in drug resistance for several of the novel RND efflux pumps. S. maltophilia possesses potentially mobile regions of DNA and encodes a number of pili and fimbriae likely to be involved in adhesion and biofilm formation that may also contribute to increased antimicrobial drug resistance. CONCLUSION: The panoply of antimicrobial drug resistance genes and mobile genetic elements found suggests that the organism can act as a reservoir of antimicrobial drug resistance determinants in a clinical environment, which is an issue of considerable concern.



        

Title: Common inheritance of chromosome Ia associated with clonal expansion of Toxoplasma gondii
Khan A, Bohme U, Kelly KA, Adlem E, Brooks K, Simmonds M, Mungall K, Quail MA, Arrowsmith C and Ajioka JW <29 more author(s)> Khan A, Bohme U, Kelly KA, Adlem E, Brooks K, Simmonds M, Mungall K, Quail MA, Arrowsmith C, Chillingworth T, Churcher C, Harris D, Collins M, Fosker N, Fraser A, Hance Z, Jagels K, Moule S, Murphy L, O'Neil S, Rajandream MA, Saunders D, Seeger K, Whitehead S, Mayr T, Xuan X, Watanabe J, Suzuki Y, Wakaguri H, Sugano S, Sugimoto C, Paulsen I, Mackey AJ, Roos DS, Hall N, Berriman M, Barrell B, Sibley LD, Ajioka JW (- 29)
Ref: Genome Res, 16:1119, 2006 : PubMed
Abstract


ESTHER: Khan_2006_Genome.Res_16_1119
PubMedSearch: Khan 2006 Genome.Res 16 1119
PubMedID: 16902086
Gene_locus related to this paper: toxgo-q1jt22

Abstract

Toxoplasma gondii is a globally distributed protozoan parasite that can infect virtually all warm-blooded animals and humans. Despite the existence of a sexual phase in the life cycle, T. gondii has an unusual population structure dominated by three clonal lineages that predominate in North America and Europe, (Types I, II, and III). These lineages were founded by common ancestors approximately10,000 yr ago. The recent origin and widespread distribution of the clonal lineages is attributed to the circumvention of the sexual cycle by a new mode of transmission-asexual transmission between intermediate hosts. Asexual transmission appears to be multigenic and although the specific genes mediating this trait are unknown, it is predicted that all members of the clonal lineages should share the same alleles. Genetic mapping studies suggested that chromosome Ia was unusually monomorphic compared with the rest of the genome. To investigate this further, we sequenced chromosome Ia and chromosome Ib in the Type I strain, RH, and the Type II strain, ME49. Comparative genome analyses of the two chromosomal sequences revealed that the same copy of chromosome Ia was inherited in each lineage, whereas chromosome Ib maintained the same high frequency of between-strain polymorphism as the rest of the genome. Sampling of chromosome Ia sequence in seven additional representative strains from the three clonal lineages supports a monomorphic inheritance, which is unique within the genome. Taken together, our observations implicate a specific combination of alleles on chromosome Ia in the recent origin and widespread success of the clonal lineages of T. gondii.



        

Title: The genome of the social amoeba Dictyostelium discoideum
Eichinger L, Pachebat JA, Glockner G, Rajandream MA, Sucgang R, Berriman M, Song J, Olsen R, Szafranski K and Kuspa A <87 more author(s)> Eichinger L, Pachebat JA, Glockner G, Rajandream MA, Sucgang R, Berriman M, Song J, Olsen R, Szafranski K, Xu Q, Tunggal B, Kummerfeld S, Madera M, Konfortov BA, Rivero F, Bankier AT, Lehmann R, Hamlin N, Davies R, Gaudet P, Fey P, Pilcher K, Chen G, Saunders D, Sodergren E, Davis P, Kerhornou A, Nie X, Hall N, Anjard C, Hemphill L, Bason N, Farbrother P, Desany B, Just E, Morio T, Rost R, Churcher C, Cooper J, Haydock S, van Driessche N, Cronin A, Goodhead I, Muzny D, Mourier T, Pain A, Lu M, Harper D, Lindsay R, Hauser H, James K, Quiles M, Madan Babu M, Saito T, Buchrieser C, Wardroper A, Felder M, Thangavelu M, Johnson D, Knights A, Loulseged H, Mungall K, Oliver K, Price C, Quail MA, Urushihara H, Hernandez J, Rabbinowitsch E, Steffen D, Sanders M, Ma J, Kohara Y, Sharp S, Simmonds M, Spiegler S, Tivey A, Sugano S, White B, Walker D, Woodward J, Winckler T, Tanaka Y, Shaulsky G, Schleicher M, Weinstock G, Rosenthal A, Cox EC, Chisholm RL, Gibbs R, Loomis WF, Platzer M, Kay RR, Williams J, Dear PH, Noegel AA, Barrell B, Kuspa A (- 87)
Ref: Nature, 435:43, 2005 : PubMed
Abstract


ESTHER: Eichinger_2005_Nature_435_43
PubMedSearch: Eichinger 2005 Nature 435 43
PubMedID: 15875012
Gene_locus related to this paper: dicdi-abhd, dicdi-ACHE, dicdi-apra, dicdi-cinbp, dicdi-CMBL, dicdi-crysp, dicdi-DPOA, dicdi-P90528, dicdi-ppme1, dicdi-Q8MYE7, dicdi-q54cf7, dicdi-q54cl7, dicdi-q54cm0, dicdi-q54ct5, dicdi-q54cu1, dicdi-q54d54, dicdi-q54d66, dicdi-q54dj5, dicdi-q54dy7, dicdi-q54ek1, dicdi-q54eq6, dicdi-q54et1, dicdi-q54et7, dicdi-q54f01, dicdi-q54g24, dicdi-q54g47, dicdi-q54gi7, dicdi-q54gw5, dicdi-q54gx3, dicdi-q54h23, dicdi-q54h73, dicdi-q54i38, dicdi-q54ie5, dicdi-q54in4, dicdi-q54kz1, dicdi-q54l36, dicdi-q54li1, dicdi-q54m29, dicdi-q54n21, dicdi-q54n35, dicdi-q54n85, dicdi-q54qe7, dicdi-q54qi3, dicdi-q54qk2, dicdi-q54rl3, dicdi-q54rl8, dicdi-q54sy6, dicdi-q54sz3, dicdi-q54t49, dicdi-q54t91, dicdi-q54th2, dicdi-q54u01, dicdi-q54vc2, dicdi-q54vw1, dicdi-q54xe3, dicdi-q54xl3, dicdi-q54xu1, dicdi-q54xu2, dicdi-q54y48, dicdi-q54yd0, dicdi-q54ye0, dicdi-q54yl1, dicdi-q54yr8, dicdi-q54z90, dicdi-q55bx3, dicdi-q55d01, dicdi-q55d81, dicdi-q55du6, dicdi-q55eu1, dicdi-q55eu8, dicdi-q55fk4, dicdi-q55gk7, dicdi-Q54ZA6, dicdi-q86h82, dicdi-Q86HC9, dicdi-Q86HM5, dicdi-Q86HM6, dicdi-q86iz7, dicdi-q86jb6, dicdi-Q86KU7, dicdi-q550s3, dicdi-q552c0, dicdi-q553t5, dicdi-q555e5, dicdi-q555h0, dicdi-q555h1, dicdi-q557k5, dicdi-q558u2, dicdi-Q869Q8, dicdi-u554, dicdi-y9086, dicdi-q54r44, dicdi-f172a

Abstract

The social amoebae are exceptional in their ability to alternate between unicellular and multicellular forms. Here we describe the genome of the best-studied member of this group, Dictyostelium discoideum. The gene-dense chromosomes of this organism encode approximately 12,500 predicted proteins, a high proportion of which have long, repetitive amino acid tracts. There are many genes for polyketide synthases and ABC transporters, suggesting an extensive secondary metabolism for producing and exporting small molecules. The genome is rich in complex repeats, one class of which is clustered and may serve as centromeres. Partial copies of the extrachromosomal ribosomal DNA (rDNA) element are found at the ends of each chromosome, suggesting a novel telomere structure and the use of a common mechanism to maintain both the rDNA and chromosomal termini. A proteome-based phylogeny shows that the amoebozoa diverged from the animal-fungal lineage after the plant-animal split, but Dictyostelium seems to have retained more of the diversity of the ancestral genome than have plants, animals or fungi.



        

Title: The genome of the kinetoplastid parasite, Leishmania major
Ivens AC, Peacock CS, Worthey EA, Murphy L, Aggarwal G, Berriman M, Sisk E, Rajandream MA, Adlem E and Myler PJ <91 more author(s)> Ivens AC, Peacock CS, Worthey EA, Murphy L, Aggarwal G, Berriman M, Sisk E, Rajandream MA, Adlem E, Aert R, Anupama A, Apostolou Z, Attipoe P, Bason N, Bauser C, Beck A, Beverley SM, Bianchettin G, Borzym K, Bothe G, Bruschi CV, Collins M, Cadag E, Ciarloni L, Clayton C, Coulson RM, Cronin A, Cruz AK, Davies RM, De Gaudenzi J, Dobson DE, Duesterhoeft A, Fazelina G, Fosker N, Frasch AC, Fraser A, Fuchs M, Gabel C, Goble A, Goffeau A, Harris D, Hertz-Fowler C, Hilbert H, Horn D, Huang Y, Klages S, Knights A, Kube M, Larke N, Litvin L, Lord A, Louie T, Marra M, Masuy D, Matthews K, Michaeli S, Mottram JC, Muller-Auer S, Munden H, Nelson S, Norbertczak H, Oliver K, O'Neil S, Pentony M, Pohl TM, Price C, Purnelle B, Quail MA, Rabbinowitsch E, Reinhardt R, Rieger M, Rinta J, Robben J, Robertson L, Ruiz JC, Rutter S, Saunders D, Schafer M, Schein J, Schwartz DC, Seeger K, Seyler A, Sharp S, Shin H, Sivam D, Squares R, Squares S, Tosato V, Vogt C, Volckaert G, Wambutt R, Warren T, Wedler H, Woodward J, Zhou S, Zimmermann W, Smith DF, Blackwell JM, Stuart KD, Barrell B, Myler PJ (- 91)
Ref: Science, 309:436, 2005 : PubMed
Abstract


ESTHER: Ivens_2005_Science_309_436
PubMedSearch: Ivens 2005 Science 309 436
PubMedID: 16020728
Gene_locus related to this paper: leima-e9ady6, leima-L2464.12, leima-L2802.02, leima-OPB, leima-q4fw33, leima-q4fwg8, leima-q4fwj0, leima-q4fya7, leima-q4q0a1, leima-q4q0t5, leima-q4q0v0, leima-q4q1h9, leima-q4q2c9, leima-q4q4j7, leima-q4q4t6, leima-q4q5j1, leima-q4q6e9, leima-q4q7v8, leima-q4q8a8, leima-q4q9g9, leima-q4q080, leima-q4q398, leima-q4q615, leima-q4q819, leima-q4q871, leima-q4q942, leima-q4qae7, leima-q4qb85, leima-q4qdz7, leima-q4qe26, leima-q4qe31, leima-q4qe85, leima-q4qe86, leima-q4qe87, leima-q4qe90, leima-q4qec8, leima-q4qgz4, leima-q4qgz5, leima-q4qhs0, leima-q4qj45

Abstract

Leishmania species cause a spectrum of human diseases in tropical and subtropical regions of the world. We have sequenced the 36 chromosomes of the 32.8-megabase haploid genome of Leishmania major (Friedlin strain) and predict 911 RNA genes, 39 pseudogenes, and 8272 protein-coding genes, of which 36% can be ascribed a putative function. These include genes involved in host-pathogen interactions, such as proteolytic enzymes, and extensive machinery for synthesis of complex surface glycoconjugates. The organization of protein-coding genes into long, strand-specific, polycistronic clusters and lack of general transcription factors in the L. major, Trypanosoma brucei, and Trypanosoma cruzi (Tritryp) genomes suggest that the mechanisms regulating RNA polymerase II-directed transcription are distinct from those operating in other eukaryotes, although the trypanosomatids appear capable of chromatin remodeling. Abundant RNA-binding proteins are encoded in the Tritryp genomes, consistent with active posttranscriptional regulation of gene expression.



        

Title: Genomic sequence of the pathogenic and allergenic filamentous fungus Aspergillus fumigatus
Nierman WC, Pain A, Anderson MJ, Wortman JR, Kim HS, Arroyo J, Berriman M, Abe K, Archer DB and Denning DW <87 more author(s)> Nierman WC, Pain A, Anderson MJ, Wortman JR, Kim HS, Arroyo J, Berriman M, Abe K, Archer DB, Bermejo C, Bennett J, Bowyer P, Chen D, Collins M, Coulsen R, Davies R, Dyer PS, Farman M, Fedorova N, Feldblyum TV, Fischer R, Fosker N, Fraser A, Garcia JL, Garcia MJ, Goble A, Goldman GH, Gomi K, Griffith-Jones S, Gwilliam R, Haas B, Haas H, Harris D, Horiuchi H, Huang J, Humphray S, Jimenez J, Keller N, Khouri H, Kitamoto K, Kobayashi T, Konzack S, Kulkarni R, Kumagai T, Lafon A, Latge JP, Li W, Lord A, Lu C, Majoros WH, May GS, Miller BL, Mohamoud Y, Molina M, Monod M, Mouyna I, Mulligan S, Murphy L, O'Neil S, Paulsen I, Penalva MA, Pertea M, Price C, Pritchard BL, Quail MA, Rabbinowitsch E, Rawlins N, Rajandream MA, Reichard U, Renauld H, Robson GD, Rodriguez de Cordoba S, Rodriguez-Pena JM, Ronning CM, Rutter S, Salzberg SL, Sanchez M, Sanchez-Ferrero JC, Saunders D, Seeger K, Squares R, Squares S, Takeuchi M, Tekaia F, Turner G, Vazquez de Aldana CR, Weidman J, White O, Woodward J, Yu JH, Fraser C, Galagan JE, Asai K, Machida M, Hall N, Barrell B, Denning DW (- 87)
Ref: Nature, 438:1151, 2005 : PubMed
Abstract


ESTHER: Nierman_2005_Nature_438_1151
PubMedSearch: Nierman 2005 Nature 438 1151
PubMedID: 16372009
Gene_locus related to this paper: aspfc-b0xp50, aspfc-b0xu40, aspfc-b0xzj6, aspfc-dpp5, aspfu-apth1, aspfu-axe1, aspfu-CBPYA, aspfu-faec, aspfu-kex1, aspfu-ppme1, aspfu-q4wa39, aspfu-q4wa78, aspfu-q4wf56, aspfu-q4wg73, aspfu-q4wk44, aspfu-q4wkh6, aspfu-q4wnx3, aspfu-q4wpb9, aspfu-q4wqv2, aspfu-q4wub2, aspfu-q4wxr1, aspfu-q4x0n6, aspfu-q4x1n0, aspfu-q5vjg7, neofi-a1cwa6, neofi-a1dfr9, aspfm-a0a084bf80, aspfu-fmac

Abstract

Aspergillus fumigatus is exceptional among microorganisms in being both a primary and opportunistic pathogen as well as a major allergen. Its conidia production is prolific, and so human respiratory tract exposure is almost constant. A. fumigatus is isolated from human habitats and vegetable compost heaps. In immunocompromised individuals, the incidence of invasive infection can be as high as 50% and the mortality rate is often about 50% (ref. 2). The interaction of A. fumigatus and other airborne fungi with the immune system is increasingly linked to severe asthma and sinusitis. Although the burden of invasive disease caused by A. fumigatus is substantial, the basic biology of the organism is mostly obscure. Here we show the complete 29.4-megabase genome sequence of the clinical isolate Af293, which consists of eight chromosomes containing 9,926 predicted genes. Microarray analysis revealed temperature-dependent expression of distinct sets of genes, as well as 700 A. fumigatus genes not present or significantly diverged in the closely related sexual species Neosartorya fischeri, many of which may have roles in the pathogenicity phenotype. The Af293 genome sequence provides an unparalleled resource for the future understanding of this remarkable fungus.



        

Title: Genome of the host-cell transforming parasite Theileria annulata compared with T. parva
Pain A, Renauld H, Berriman M, Murphy L, Yeats CA, Weir W, Kerhornou A, Aslett M, Bishop R and Hall N <40 more author(s)> Pain A, Renauld H, Berriman M, Murphy L, Yeats CA, Weir W, Kerhornou A, Aslett M, Bishop R, Bouchier C, Cochet M, Coulson RM, Cronin A, de Villiers EP, Fraser A, Fosker N, Gardner M, Goble A, Griffiths-Jones S, Harris DE, Katzer F, Larke N, Lord A, Maser P, McKellar S, Mooney P, Morton F, Nene V, O'Neil S, Price C, Quail MA, Rabbinowitsch E, Rawlings ND, Rutter S, Saunders D, Seeger K, Shah T, Squares R, Squares S, Tivey A, Walker AR, Woodward J, Dobbelaere DA, Langsley G, Rajandream MA, McKeever D, Shiels B, Tait A, Barrell B, Hall N (- 40)
Ref: Science, 309:131, 2005 : PubMed
Abstract


ESTHER: Pain_2005_Science_309_131
PubMedSearch: Pain 2005 Science 309 131
PubMedID: 15994557
Gene_locus related to this paper: thean-q4u9u6, thean-q4ub48, thean-q4ubz1, thean-q4uc78, thean-q4uc93, thean-q4uck1, thean-q4udw9, thean-q4ue56, thean-q4uf06, thean-q4ug98, thean-q4uhj9, thepa-q4n349

Abstract

Theileria annulata and T. parva are closely related protozoan parasites that cause lymphoproliferative diseases of cattle. We sequenced the genome of T. annulata and compared it with that of T. parva to understand the mechanisms underlying transformation and tropism. Despite high conservation of gene sequences and synteny, the analysis reveals unequally expanded gene families and species-specific genes. We also identify divergent families of putative secreted polypeptides that may reduce immune recognition, candidate regulators of host-cell transformation, and a Theileria-specific protein domain [frequently associated in Theileria (FAINT)] present in a large number of secreted proteins.



        

Title: Insight into the genome of Aspergillus fumigatus: analysis of a 922 kb region encompassing the nitrate assimilation gene cluster
Pain A, Woodward J, Quail MA, Anderson MJ, Clark R, Collins M, Fosker N, Fraser A, Harris D and Hall N <15 more author(s)> Pain A, Woodward J, Quail MA, Anderson MJ, Clark R, Collins M, Fosker N, Fraser A, Harris D, Larke N, Murphy L, Humphray S, O'Neil S, Pertea M, Price C, Rabbinowitsch E, Rajandream MA, Salzberg S, Saunders D, Seeger K, Sharp S, Warren T, Denning DW, Barrell B, Hall N (- 15)
Ref: Fungal Genet Biol, 41:443, 2004 : PubMed
Abstract


ESTHER: Pain_2004_Fungal.Genet.Biol_41_443
PubMedSearch: Pain 2004 Fungal.Genet.Biol 41 443
PubMedID: 14998527
Gene_locus related to this paper: aspfu-q6my76, aspfu-q6myf7, aspfu-q6myz3

Abstract

Aspergillus fumigatus is the most ubiquitous opportunistic filamentous fungal pathogen of human. As an initial step toward sequencing the entire genome of A. fumigatus, which is estimated to be approximately 30 Mb in size, we have sequenced a 922 kb region, contained within 16 overlapping bacterial artificial chromosome (BAC) clones. Fifty-four percent of the DNA is predicted to be coding with 341 putative protein coding genes. Functional classification of the proteins showed the presence of a higher proportion of enzymes and membrane transporters when compared to those of Saccharomyces cerevisiae. In addition to the nitrate assimilation gene cluster, the quinate utilisation gene cluster is also present on this 922 kb genomic sequence. We observed large scale synteny between A. fumigatus and Aspergillus nidulans by comparing this sequence to the A. nidulans genetic map of linkage group VIII.



        

Title: Comparative analysis of the genome sequences of Bordetella pertussis, Bordetella parapertussis and Bordetella bronchiseptica
Parkhill J, Sebaihia M, Preston A, Murphy LD, Thomson N, Harris DE, Holden MT, Churcher CM, Bentley SD and Maskell DJ <43 more author(s)> Parkhill J, Sebaihia M, Preston A, Murphy LD, Thomson N, Harris DE, Holden MT, Churcher CM, Bentley SD, Mungall KL, Cerdeno-Tarraga AM, Temple L, James K, Harris B, Quail MA, Achtman M, Atkin R, Baker S, Basham D, Bason N, Cherevach I, Chillingworth T, Collins M, Cronin A, Davis P, Doggett J, Feltwell T, Goble A, Hamlin N, Hauser H, Holroyd S, Jagels K, Leather S, Moule S, Norberczak H, O'Neil S, Ormond D, Price C, Rabbinowitsch E, Rutter S, Sanders M, Saunders D, Seeger K, Sharp S, Simmonds M, Skelton J, Squares R, Squares S, Stevens K, Unwin L, Whitehead S, Barrell BG, Maskell DJ (- 43)
Ref: Nat Genet, 35:32, 2003 : PubMed
Abstract


ESTHER: Parkhill_2003_Nat.Genet_35_32
PubMedSearch: Parkhill 2003 Nat.Genet 35 32
PubMedID: 12910271
Gene_locus related to this paper: borbr-BB0273, borbr-BB0570, borbr-BB0670, borbr-BB1064, borbr-BB1079, borbr-BB1247, borbr-BB1498, borbr-BB2718, borbr-BB4129, borbr-BB4247, borbr-MHPC, borbr-q7wdw1, borbr-q7wiz8, borbr-q7wk25, borbr-q7wmc2, borbr-q7wpd9, borpa-q7w3f3, borpa-q7w9v8, borpe-BIOH, borpe-BP0300, borpe-BP2114, borpe-BP2146, borpe-BP2511, borpe-BP3096, borpe-BP3623, borpe-BP3691, borpe-CATD2, borpe-METX, borpe-O30449, borpe-PHBC, borpe-q7vsl4, borpe-q7vt07, borpe-q7vtg0, borpe-q7vtv2, borpe-q7vus4, borpe-q7vuv4, borpe-q7vv11, borpe-q7vv48, borpe-q7vvf6, borpe-q7vwu4, borpe-q7vyn0, borpe-q7vyq4, borpe-q7vz26, borpe-q7vzb4, borpe-q7vzj6, borpe-q7w073

Abstract

Bordetella pertussis, Bordetella parapertussis and Bordetella bronchiseptica are closely related Gram-negative beta-proteobacteria that colonize the respiratory tracts of mammals. B. pertussis is a strict human pathogen of recent evolutionary origin and is the primary etiologic agent of whooping cough. B. parapertussis can also cause whooping cough, and B. bronchiseptica causes chronic respiratory infections in a wide range of animals. We sequenced the genomes of B. bronchiseptica RB50 (5,338,400 bp; 5,007 predicted genes), B. parapertussis 12822 (4,773,551 bp; 4,404 genes) and B. pertussis Tohama I (4,086,186 bp; 3,816 genes). Our analysis indicates that B. parapertussis and B. pertussis are independent derivatives of B. bronchiseptica-like ancestors. During the evolution of these two host-restricted species there was large-scale gene loss and inactivation; host adaptation seems to be a consequence of loss, not gain, of function, and differences in virulence may be related to loss of regulatory or control functions.



        

Title: Complete genome sequence of the model actinomycete Streptomyces coelicolor A3(2)
Bentley SD, Chater KF, Cerdeno-Tarraga AM, Challis GL, Thomson NR, James KD, Harris DE, Quail MA, Kieser H and Hopwood DA <33 more author(s)> Bentley SD, Chater KF, Cerdeno-Tarraga AM, Challis GL, Thomson NR, James KD, Harris DE, Quail MA, Kieser H, Harper D, Bateman A, Brown S, Chandra G, Chen CW, Collins M, Cronin A, Fraser A, Goble A, Hidalgo J, Hornsby T, Howarth S, Huang CH, Kieser T, Larke L, Murphy L, Oliver K, O'Neil S, Rabbinowitsch E, Rajandream MA, Rutherford K, Rutter S, Seeger K, Saunders D, Sharp S, Squares R, Squares S, Taylor K, Warren T, Wietzorrek A, Woodward J, Barrell BG, Parkhill J, Hopwood DA (- 33)
Ref: Nature, 417:141, 2002 : PubMed
Abstract


ESTHER: Bentley_2002_Nature_417_141
PubMedSearch: Bentley 2002 Nature 417 141
PubMedID: 12000953
Gene_locus related to this paper: strco-cxest, strco-cxest2, strco-ester, strco-estli, strco-MMYT, strco-ORF3, strco-q9f2m1, strco-q9rdq9, strco-q9x8r0, strco-SC1A6.21, strco-SC3F7.14, strco-SC4C2.18, strco-SC10F4.23, strco-SCBAC20F6.10, strco-SCD95A, strco-SCE8.12C, strco-SCE63.01, strco-SCF43.16C, strco-SCJ9A.33C, strco-SCO0047, strco-SCO0135, strco-SCO0490, strco-SCO0503, strco-SCO0556.1, strco-SCO0556.2, strco-SCO1265, strco-SCO2123, strco-SCO2516, strco-SCO2723, strco-SCO2761, strco-SCO3396, strco-SCO3772, strco-SCO4160, strco-SCO4900, strco-SCO5215, strco-SCO5489, strco-SCO5986, strco-SCO6351, strco-SCO6488, strco-SCO7057, strco-SCO7121, strco-SCO7396, strco-SCO7609, strco-SCOT, strco-SLPD, strco-TAP

Abstract

Streptomyces coelicolor is a representative of the group of soil-dwelling, filamentous bacteria responsible for producing most natural antibiotics used in human and veterinary medicine. Here we report the 8,667,507 base pair linear chromosome of this organism, containing the largest number of genes so far discovered in a bacterium. The 7,825 predicted genes include more than 20 clusters coding for known or predicted secondary metabolites. The genome contains an unprecedented proportion of regulatory genes, predominantly those likely to be involved in responses to external stimuli and stresses, and many duplicated gene sets that may represent 'tissue-specific' isoforms operating in different phases of colonial development, a unique situation for a bacterium. An ancient synteny was revealed between the central 'core' of the chromosome and the whole chromosome of pathogens Mycobacterium tuberculosis and Corynebacterium diphtheriae. The genome sequence will greatly increase our understanding of microbial life in the soil as well as aiding the generation of new drug candidates by genetic engineering.



        

Title: The genome sequence of Schizosaccharomyces pombe
Wood V, Gwilliam R, Rajandream MA, Lyne M, Lyne R, Stewart A, Sgouros J, Peat N, Hayles J and Nurse P <124 more author(s)> Wood V, Gwilliam R, Rajandream MA, Lyne M, Lyne R, Stewart A, Sgouros J, Peat N, Hayles J, Baker S, Basham D, Bowman S, Brooks K, Brown D, Brown S, Chillingworth T, Churcher C, Collins M, Connor R, Cronin A, Davis P, Feltwell T, Fraser A, Gentles S, Goble A, Hamlin N, Harris D, Hidalgo J, Hodgson G, Holroyd S, Hornsby T, Howarth S, Huckle EJ, Hunt S, Jagels K, James K, Jones L, Jones M, Leather S, McDonald S, McLean J, Mooney P, Moule S, Mungall K, Murphy L, Niblett D, Odell C, Oliver K, O'Neil S, Pearson D, Quail MA, Rabbinowitsch E, Rutherford K, Rutter S, Saunders D, Seeger K, Sharp S, Skelton J, Simmonds M, Squares R, Squares S, Stevens K, Taylor K, Taylor RG, Tivey A, Walsh S, Warren T, Whitehead S, Woodward J, Volckaert G, Aert R, Robben J, Grymonprez B, Weltjens I, Vanstreels E, Rieger M, Schafer M, Muller-Auer S, Gabel C, Fuchs M, Dusterhoft A, Fritzc C, Holzer E, Moestl D, Hilbert H, Borzym K, Langer I, Beck A, Lehrach H, Reinhardt R, Pohl TM, Eger P, Zimmermann W, Wedler H, Wambutt R, Purnelle B, Goffeau A, Cadieu E, Dreano S, Gloux S, Lelaure V, Mottier S, Galibert F, Aves SJ, Xiang Z, Hunt C, Moore K, Hurst SM, Lucas M, Rochet M, Gaillardin C, Tallada VA, Garzon A, Thode G, Daga RR, Cruzado L, Jimenez J, Sanchez M, del Rey F, Benito J, Dominguez A, Revuelta JL, Moreno S, Armstrong J, Forsburg SL, Cerutti L, Lowe T, McCombie WR, Paulsen I, Potashkin J, Shpakovski GV, Ussery D, Barrell BG, Nurse P (- 124)
Ref: Nature, 415:871, 2002 : PubMed
Abstract


ESTHER: Wood_2002_Nature_415_871
PubMedSearch: Wood 2002 Nature 415 871
PubMedID: 11859360
Gene_locus related to this paper: schpo-APTH1, schpo-be46, schpo-BST1, schpo-C2E11.08, schpo-C14C4.15C, schpo-C22H12.03, schpo-C23C4.16C, schpo-C57A10.08C, schpo-dyr, schpo-este1, schpo-KEX1, schpo-PCY1, schpo-pdat, schpo-PLG7, schpo-ppme1, schpo-q9c0y8, schpo-SPAC4A8.06C, schpo-C22A12.06C, schpo-SPAC977.15, schpo-SPAPB1A11.02, schpo-SPBC14C8.15, schpo-SPBC530.12C, schpo-SPBC1711.12, schpo-SPBPB2B2.02, schpo-SPCC5E4.05C, schpo-SPCC417.12, schpo-SPCC1672.09, schpo-yb4e, schpo-yblh, schpo-ydw6, schpo-ye7a, schpo-ye63, schpo-ye88, schpo-yeld, schpo-yk68, schpo-clr3, schpo-ykv6

Abstract

We have sequenced and annotated the genome of fission yeast (Schizosaccharomyces pombe), which contains the smallest number of protein-coding genes yet recorded for a eukaryote: 4,824. The centromeres are between 35 and 110 kilobases (kb) and contain related repeats including a highly conserved 1.8-kb element. Regions upstream of genes are longer than in budding yeast (Saccharomyces cerevisiae), possibly reflecting more-extended control regions. Some 43% of the genes contain introns, of which there are 4,730. Fifty genes have significant similarity with human disease genes; half of these are cancer related. We identify highly conserved genes important for eukaryotic cell organization including those required for the cytoskeleton, compartmentation, cell-cycle control, proteolysis, protein phosphorylation and RNA splicing. These genes may have originated with the appearance of eukaryotic life. Few similarly conserved genes that are important for multicellular organization were identified, suggesting that the transition from prokaryotes to eukaryotes required more new genes than did the transition from unicellular to multicellular organization.