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Author Report for: Ketchum KA

Title: Role of mobile DNA in the evolution of vancomycin-resistant Enterococcus faecalis
Paulsen IT, Banerjei L, Myers GS, Nelson KE, Seshadri R, Read TD, Fouts DE, Eisen JA, Gill SR and Fraser CM <22 more author(s)> Paulsen IT, Banerjei L, Myers GS, Nelson KE, Seshadri R, Read TD, Fouts DE, Eisen JA, Gill SR, Heidelberg JF, Tettelin H, Dodson RJ, Umayam L, Brinkac L, Beanan M, Daugherty S, DeBoy RT, Durkin S, Kolonay J, Madupu R, Nelson W, Vamathevan J, Tran B, Upton J, Hansen T, Shetty J, Khouri H, Utterback T, Radune D, Ketchum KA, Dougherty BA, Fraser CM (- 22)
Ref: Science, 299:2071, 2003 : PubMed
Abstract


ESTHER: Paulsen_2003_Science_299_2071
PubMedSearch: Paulsen 2003 Science 299 2071
PubMedID: 12663927
Gene_locus related to this paper: entfa-EF0101, entfa-EF0274, entfa-EF0381, entfa-EF0449, entfa-EF0667, entfa-EF0786, entfa-EF1028, entfa-EF1236, entfa-EF1505, entfa-EF1536, entfa-EF1670, entfa-EF2618, entfa-EF2728, entfa-EF2792, entfa-EF2963, entfa-EF3191

Abstract

The complete genome sequence of Enterococcus faecalis V583, a vancomycin-resistant clinical isolate, revealed that more than a quarter of the genome consists of probable mobile or foreign DNA. One of the predicted mobile elements is a previously unknown vanB vancomycin-resistance conjugative transposon. Three plasmids were identified, including two pheromone-sensing conjugative plasmids, one encoding a previously undescribed pheromone inhibitor. The apparent propensity for the incorporation of mobile elements probably contributed to the rapid acquisition and dissemination of drug resistance in the enterococci.



        

Title: The complete genome sequence of Chlorobium tepidum TLS, a photosynthetic, anaerobic, green-sulfur bacterium
Eisen JA, Nelson KE, Paulsen IT, Heidelberg JF, Wu M, Dodson RJ, Deboy R, Gwinn ML, Nelson WC and Fraser CM <25 more author(s)> Eisen JA, Nelson KE, Paulsen IT, Heidelberg JF, Wu M, Dodson RJ, Deboy R, Gwinn ML, Nelson WC, Haft DH, Hickey EK, Peterson JD, Durkin AS, Kolonay JL, Yang F, Holt I, Umayam LA, Mason T, Brenner M, Shea TP, Parksey D, Nierman WC, Feldblyum TV, Hansen CL, Craven MB, Radune D, Vamathevan J, Khouri H, White O, Gruber TM, Ketchum KA, Venter JC, Tettelin H, Bryant DA, Fraser CM (- 25)
Ref: Proceedings of the National Academy of Sciences of the United States of America, 99:9509, 2002 : PubMed
Abstract


ESTHER: Eisen_2002_Proc.Natl.Acad.Sci.U.S.A_99_9509
PubMedSearch: Eisen 2002 Proc.Natl.Acad.Sci.U.S.A 99 9509
PubMedID: 12093901
Gene_locus related to this paper: chlte-CT0177, chlte-CT0524, chlte-CT0717, chlte-CT0947, chlte-CT1208, chlte-CT1253, chlte-CT1301, chlte-CT1312, chlte-CT1856, chlte-CT1908, chlte-CT2087, chlte-CT2271, chlte-MENH, chlte-MET2, chlte-q4w546, chlte-q8kgb8

Abstract

The complete genome of the green-sulfur eubacterium Chlorobium tepidum TLS was determined to be a single circular chromosome of 2,154,946 bp. This represents the first genome sequence from the phylum Chlorobia, whose members perform anoxygenic photosynthesis by the reductive tricarboxylic acid cycle. Genome comparisons have identified genes in C. tepidum that are highly conserved among photosynthetic species. Many of these have no assigned function and may play novel roles in photosynthesis or photobiology. Phylogenomic analysis reveals likely duplications of genes involved in biosynthetic pathways for photosynthesis and the metabolism of sulfur and nitrogen as well as strong similarities between metabolic processes in C. tepidum and many Archaeal species.



        

Title: The sequence of the human genome
Venter JC, Adams MD, Myers EW, Li PW, Mural RJ, Sutton GG, Smith HO, Yandell M, Evans CA and Zhu X <264 more author(s)> Venter JC, Adams MD, Myers EW, Li PW, Mural RJ, Sutton GG, Smith HO, Yandell M, Evans CA, Holt RA, Gocayne JD, Amanatides P, Ballew RM, Huson DH, Wortman JR, Zhang Q, Kodira CD, Zheng XH, Chen L, Skupski M, Subramanian G, Thomas PD, Zhang J, Gabor Miklos GL, Nelson C, Broder S, Clark AG, Nadeau J, McKusick VA, Zinder N, Levine AJ, Roberts RJ, Simon M, Slayman C, Hunkapiller M, Bolanos R, Delcher A, Dew I, Fasulo D, Flanigan M, Florea L, Halpern A, Hannenhalli S, Kravitz S, Levy S, Mobarry C, Reinert K, Remington K, Abu-Threideh J, Beasley E, Biddick K, Bonazzi V, Brandon R, Cargill M, Chandramouliswaran I, Charlab R, Chaturvedi K, Deng Z, Di Francesco V, Dunn P, Eilbeck K, Evangelista C, Gabrielian AE, Gan W, Ge W, Gong F, Gu Z, Guan P, Heiman TJ, Higgins ME, Ji RR, Ke Z, Ketchum KA, Lai Z, Lei Y, Li Z, Li J, Liang Y, Lin X, Lu F, Merkulov GV, Milshina N, Moore HM, Naik AK, Narayan VA, Neelam B, Nusskern D, Rusch DB, Salzberg S, Shao W, Shue B, Sun J, Wang Z, Wang A, Wang X, Wang J, Wei M, Wides R, Xiao C, Yan C, Yao A, Ye J, Zhan M, Zhang W, Zhang H, Zhao Q, Zheng L, Zhong F, Zhong W, Zhu S, Zhao S, Gilbert D, Baumhueter S, Spier G, Carter C, Cravchik A, Woodage T, Ali F, An H, Awe A, Baldwin D, Baden H, Barnstead M, Barrow I, Beeson K, Busam D, Carver A, Center A, Cheng ML, Curry L, Danaher S, Davenport L, Desilets R, Dietz S, Dodson K, Doup L, Ferriera S, Garg N, Gluecksmann A, Hart B, Haynes J, Haynes C, Heiner C, Hladun S, Hostin D, Houck J, Howland T, Ibegwam C, Johnson J, Kalush F, Kline L, Koduru S, Love A, Mann F, May D, McCawley S, McIntosh T, McMullen I, Moy M, Moy L, Murphy B, Nelson K, Pfannkoch C, Pratts E, Puri V, Qureshi H, Reardon M, Rodriguez R, Rogers YH, Romblad D, Ruhfel B, Scott R, Sitter C, Smallwood M, Stewart E, Strong R, Suh E, Thomas R, Tint NN, Tse S, Vech C, Wang G, Wetter J, Williams S, Williams M, Windsor S, Winn-Deen E, Wolfe K, Zaveri J, Zaveri K, Abril JF, Guigo R, Campbell MJ, Sjolander KV, Karlak B, Kejariwal A, Mi H, Lazareva B, Hatton T, Narechania A, Diemer K, Muruganujan A, Guo N, Sato S, Bafna V, Istrail S, Lippert R, Schwartz R, Walenz B, Yooseph S, Allen D, Basu A, Baxendale J, Blick L, Caminha M, Carnes-Stine J, Caulk P, Chiang YH, Coyne M, Dahlke C, Mays A, Dombroski M, Donnelly M, Ely D, Esparham S, Fosler C, Gire H, Glanowski S, Glasser K, Glodek A, Gorokhov M, Graham K, Gropman B, Harris M, Heil J, Henderson S, Hoover J, Jennings D, Jordan C, Jordan J, Kasha J, Kagan L, Kraft C, Levitsky A, Lewis M, Liu X, Lopez J, Ma D, Majoros W, McDaniel J, Murphy S, Newman M, Nguyen T, Nguyen N, Nodell M, Pan S, Peck J, Peterson M, Rowe W, Sanders R, Scott J, Simpson M, Smith T, Sprague A, Stockwell T, Turner R, Venter E, Wang M, Wen M, Wu D, Wu M, Xia A, Zandieh A, Zhu X (- 264)
Ref: Science, 291:1304, 2001 : PubMed
Abstract


ESTHER: Venter_2001_Science_291_1304
PubMedSearch: Venter 2001 Science 291 1304
PubMedID: 11181995
Gene_locus related to this paper: human-AADAC, human-ABHD1, human-ABHD10, human-ABHD11, human-ACHE, human-BCHE, human-LDAH, human-ABHD18, human-CMBL, human-ABHD17A, human-KANSL3, human-LIPA, human-LYPLAL1, human-NDRG2, human-NLGN3, human-NLGN4X, human-NLGN4Y, human-PAFAH2, human-PREPL, human-RBBP9, human-SPG21

Abstract

A 2.91-billion base pair (bp) consensus sequence of the euchromatic portion of the human genome was generated by the whole-genome shotgun sequencing method. The 14.8-billion bp DNA sequence was generated over 9 months from 27,271,853 high-quality sequence reads (5.11-fold coverage of the genome) from both ends of plasmid clones made from the DNA of five individuals. Two assembly strategies-a whole-genome assembly and a regional chromosome assembly-were used, each combining sequence data from Celera and the publicly funded genome effort. The public data were shredded into 550-bp segments to create a 2.9-fold coverage of those genome regions that had been sequenced, without including biases inherent in the cloning and assembly procedure used by the publicly funded group. This brought the effective coverage in the assemblies to eightfold, reducing the number and size of gaps in the final assembly over what would be obtained with 5.11-fold coverage. The two assembly strategies yielded very similar results that largely agree with independent mapping data. The assemblies effectively cover the euchromatic regions of the human chromosomes. More than 90% of the genome is in scaffold assemblies of 100,000 bp or more, and 25% of the genome is in scaffolds of 10 million bp or larger. Analysis of the genome sequence revealed 26,588 protein-encoding transcripts for which there was strong corroborating evidence and an additional approximately 12,000 computationally derived genes with mouse matches or other weak supporting evidence. Although gene-dense clusters are obvious, almost half the genes are dispersed in low G+C sequence separated by large tracts of apparently noncoding sequence. Only 1.1% of the genome is spanned by exons, whereas 24% is in introns, with 75% of the genome being intergenic DNA. Duplications of segmental blocks, ranging in size up to chromosomal lengths, are abundant throughout the genome and reveal a complex evolutionary history. Comparative genomic analysis indicates vertebrate expansions of genes associated with neuronal function, with tissue-specific developmental regulation, and with the hemostasis and immune systems. DNA sequence comparisons between the consensus sequence and publicly funded genome data provided locations of 2.1 million single-nucleotide polymorphisms (SNPs). A random pair of human haploid genomes differed at a rate of 1 bp per 1250 on average, but there was marked heterogeneity in the level of polymorphism across the genome. Less than 1% of all SNPs resulted in variation in proteins, but the task of determining which SNPs have functional consequences remains an open challenge.



        

Title: The genome sequence of Drosophila melanogaster
Adams MD, Celniker SE, Holt RA, Evans CA, Gocayne JD, Amanatides PG, Scherer SE, Li PW, Hoskins RA and Venter JC <185 more author(s)> Adams MD, Celniker SE, Holt RA, Evans CA, Gocayne JD, Amanatides PG, Scherer SE, Li PW, Hoskins RA, Galle RF, George RA, Lewis SE, Richards S, Ashburner M, Henderson SN, Sutton GG, Wortman JR, Yandell MD, Zhang Q, Chen LX, Brandon RC, Rogers YH, Blazej RG, Champe M, Pfeiffer BD, Wan KH, Doyle C, Baxter EG, Helt G, Nelson CR, Gabor GL, Abril JF, Agbayani A, An HJ, Andrews-Pfannkoch C, Baldwin D, Ballew RM, Basu A, Baxendale J, Bayraktaroglu L, Beasley EM, Beeson KY, Benos PV, Berman BP, Bhandari D, Bolshakov S, Borkova D, Botchan MR, Bouck J, Brokstein P, Brottier P, Burtis KC, Busam DA, Butler H, Cadieu E, Center A, Chandra I, Cherry JM, Cawley S, Dahlke C, Davenport LB, Davies P, de Pablos B, Delcher A, Deng Z, Mays AD, Dew I, Dietz SM, Dodson K, Doup LE, Downes M, Dugan-Rocha S, Dunkov BC, Dunn P, Durbin KJ, Evangelista CC, Ferraz C, Ferriera S, Fleischmann W, Fosler C, Gabrielian AE, Garg NS, Gelbart WM, Glasser K, Glodek A, Gong F, Gorrell JH, Gu Z, Guan P, Harris M, Harris NL, Harvey D, Heiman TJ, Hernandez JR, Houck J, Hostin D, Houston KA, Howland TJ, Wei MH, Ibegwam C, Jalali M, Kalush F, Karpen GH, Ke Z, Kennison JA, Ketchum KA, Kimmel BE, Kodira CD, Kraft C, Kravitz S, Kulp D, Lai Z, Lasko P, Lei Y, Levitsky AA, Li J, Li Z, Liang Y, Lin X, Liu X, Mattei B, McIntosh TC, McLeod MP, McPherson D, Merkulov G, Milshina NV, Mobarry C, Morris J, Moshrefi A, Mount SM, Moy M, Murphy B, Murphy L, Muzny DM, Nelson DL, Nelson DR, Nelson KA, Nixon K, Nusskern DR, Pacleb JM, Palazzolo M, Pittman GS, Pan S, Pollard J, Puri V, Reese MG, Reinert K, Remington K, Saunders RD, Scheeler F, Shen H, Shue BC, Siden-Kiamos I, Simpson M, Skupski MP, Smith T, Spier E, Spradling AC, Stapleton M, Strong R, Sun E, Svirskas R, Tector C, Turner R, Venter E, Wang AH, Wang X, Wang ZY, Wassarman DA, Weinstock GM, Weissenbach J, Williams SM, WoodageT, Worley KC, Wu D, Yang S, Yao QA, Ye J, Yeh RF, Zaveri JS, Zhan M, Zhang G, Zhao Q, Zheng L, Zheng XH, Zhong FN, Zhong W, Zhou X, Zhu S, Zhu X, Smith HO, Gibbs RA, Myers EW, Rubin GM, Venter JC (- 185)
Ref: Science, 287:2185, 2000 : PubMed
Abstract


ESTHER: Adams_2000_Science_287_2185
PubMedSearch: Adams 2000 Science 287 2185
PubMedID: 10731132
Gene_locus related to this paper: drome-1vite, drome-2vite, drome-3vite, drome-a1z6g9, drome-abhd2, drome-ACHE, drome-b6idz4, drome-BEM46, drome-CG5707, drome-CG5704, drome-CG1309, drome-CG1882, drome-CG1986, drome-CG2059, drome-CG2493, drome-CG2528, drome-CG2772, drome-CG3160, drome-CG3344, drome-CG3523, drome-CG3524, drome-CG3734, drome-CG3739, drome-CG3744, drome-CG3841, drome-CG4267, drome-CG4382, drome-CG4390, drome-CG4572, drome-CG4582, drome-CG4851, drome-CG4979, drome-CG5068, drome-CG5162, drome-CG5355, drome-CG5377, drome-CG5397, drome-CG5412, drome-CG5665, drome-CG5932, drome-CG5966, drome-CG6018, drome-CG6113, drome-CG6271, drome-CG6283, drome-CG6295, drome-CG6296, drome-CG6414, drome-CG6431, drome-CG6472, drome-CG6567, drome-CG6675, drome-CG6753, drome-CG6847, drome-CG7329, drome-CG7367, drome-CG7529, drome-CG7632, drome-CG8058, drome-CG8093, drome-CG8233, drome-CG8424, drome-CG8425, drome-CG9059, drome-CG9186, drome-CG9287, drome-CG9289, drome-CG9542, drome-CG9858, drome-CG9953, drome-CG9966, drome-CG10116, drome-CG10163, drome-CG10175, drome-CG10339, drome-CG10357, drome-CG10982, drome-CG11034, drome-CG11055, drome-CG11309, drome-CG11319, drome-CG11406, drome-CG11598, drome-CG11600, drome-CG11608, drome-CG11626, drome-CG11935, drome-CG12108, drome-CG12869, drome-CG13282, drome-CG13562, drome-CG13772, drome-CG14034, drome-nlg3, drome-CG14717, drome-CG15101, drome-CG15102, drome-CG15106, drome-CG15111, drome-CG15820, drome-CG15821, drome-CG15879, drome-CG17097, drome-CG17099, drome-CG17101, drome-CG17191, drome-CG17192, drome-CG17292, drome-CG18258, drome-CG18284, drome-CG18301, drome-CG18302, drome-CG18493, drome-CG18530, drome-CG18641, drome-CG18815, drome-CG31089, drome-CG31091, drome-CG32333, drome-CG32483, drome-CG33174, drome-dnlg1, drome-este4, drome-este6, drome-GH02384, drome-GH02439, drome-glita, drome-KRAKEN, drome-lip1, drome-LIP2, drome-lip3, drome-MESK2, drome-nrtac, drome-OME, drome-q7k274, drome-Q9VJN0, drome-Q8IP31, drome-q9vux3

Abstract

The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the approximately 120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes approximately 13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.



        

Title: Complete genome sequence of Neisseria meningitidis serogroup B strain MC58
Tettelin H, Saunders NJ, Heidelberg J, Jeffries AC, Nelson KE, Eisen JA, Ketchum KA, Hood DW, Peden JF and Venter JC <32 more author(s)> Tettelin H, Saunders NJ, Heidelberg J, Jeffries AC, Nelson KE, Eisen JA, Ketchum KA, Hood DW, Peden JF, Dodson RJ, Nelson WC, Gwinn ML, Deboy R, Peterson JD, Hickey EK, Haft DH, Salzberg SL, White O, Fleischmann RD, Dougherty BA, Mason T, Ciecko A, Parksey DS, Blair E, Cittone H, Clark EB, Cotton MD, Utterback TR, Khouri H, Qin H, Vamathevan J, Gill J, Scarlato V, Masignani V, Pizza M, Grandi G, Sun L, Smith HO, Fraser CM, Moxon ER, Rappuoli R, Venter JC (- 32)
Ref: Science, 287:1809, 2000 : PubMed
Abstract


ESTHER: Tettelin_2000_Science_287_1809
PubMedSearch: Tettelin 2000 Science 287 1809
PubMedID: 10710307
Gene_locus related to this paper: neigo-pip, neima-metx, neimb-q9k0t9, neime-ESD, neime-NMA2216, neime-NMB0276, neime-NMB0868, neime-NMB1828, neime-NMB1877

Abstract

The 2,272,351-base pair genome of Neisseria meningitidis strain MC58 (serogroup B), a causative agent of meningitis and septicemia, contains 2158 predicted coding regions, 1158 (53.7%) of which were assigned a biological role. Three major islands of horizontal DNA transfer were identified; two of these contain genes encoding proteins involved in pathogenicity, and the third island contains coding sequences only for hypothetical proteins. Insights into the commensal and virulence behavior of N. meningitidis can be gleaned from the genome, in which sequences for structural proteins of the pilus are clustered and several coding regions unique to serogroup B capsular polysaccharide synthesis can be identified. Finally, N. meningitidis contains more genes that undergo phase variation than any pathogen studied to date, a mechanism that controls their expression and contributes to the evasion of the host immune system.



        

Title: Sequence and analysis of chromosome 2 of the plant Arabidopsis thaliana
Lin X, Kaul S, Rounsley S, Shea TP, Benito MI, Town CD, Fujii CY, Mason T, Bowman CL and Venter JC <27 more author(s)> Lin X, Kaul S, Rounsley S, Shea TP, Benito MI, Town CD, Fujii CY, Mason T, Bowman CL, Barnstead M, Feldblyum TV, Buell CR, Ketchum KA, Lee J, Ronning CM, Koo HL, Moffat KS, Cronin LA, Shen M, Pai G, Van Aken S, Umayam L, Tallon LJ, Gill JE, Adams MD, Carrera AJ, Creasy TH, Goodman HM, Somerville CR, Copenhaver GP, Preuss D, Nierman WC, White O, Eisen JA, Salzberg SL, Fraser CM, Venter JC (- 27)
Ref: Nature, 402:761, 1999 : PubMed
Abstract


ESTHER: Lin_1999_Nature_402_761
PubMedSearch: Lin 1999 Nature 402 761
PubMedID: 10617197
Gene_locus related to this paper: arath-At2g45610, arath-AT2G03550, arath-AT2G05260, arath-AT2G12480, arath-At2g15230, arath-At2g18360, arath-At2g19550, arath-At2g19620, arath-At2g24280, arath-AT2G24320, arath-At2g26740, arath-At2g26750, arath-SCP51, arath-AT2G36290, arath-At2g42450, arath-AT2G42690, arath-AT2G44970, arath-At2g47630, arath-AT3g62590, arath-CGEP, arath-F12L6.6, arath-F12L6.7, arath-F12L6.8, arath-At3g50790, arath-MES6, arath-MES7, arath-MES4, arath-MES8, arath-MES2, arath-MES3, arath-MES1, arath-o80731, arath-pip, arath-PLA11, arath-PLA13, arath-PLA16, arath-PLA19, arath-q84w08, arath-SCP8, arath-SCP9, arath-SCP10, arath-SCP11, arath-SCP12, arath-SCP13, arath-SCP23, arath-SCP26, arath-SCP28, arath-SCP46, arath-T26B15.8, arath-SCP22, arath-SFGH, arath-MES19

Abstract

Arabidopsis thaliana (Arabidopsis) is unique among plant model organisms in having a small genome (130-140 Mb), excellent physical and genetic maps, and little repetitive DNA. Here we report the sequence of chromosome 2 from the Columbia ecotype in two gap-free assemblies (contigs) of 3.6 and 16 megabases (Mb). The latter represents the longest published stretch of uninterrupted DNA sequence assembled from any organism to date. Chromosome 2 represents 15% of the genome and encodes 4,037 genes, 49% of which have no predicted function. Roughly 250 tandem gene duplications were found in addition to large-scale duplications of about 0.5 and 4.5 Mb between chromosomes 2 and 1 and between chromosomes 2 and 4, respectively. Sequencing of nearly 2 Mb within the genetically defined centromere revealed a low density of recognizable genes, and a high density and diverse range of vestigial and presumably inactive mobile elements. More unexpected is what appears to be a recent insertion of a continuous stretch of 75% of the mitochondrial genome into chromosome 2.



        

Title: Evidence for lateral gene transfer between Archaea and bacteria from genome sequence of Thermotoga maritima
Nelson KE, Clayton RA, Gill SR, Gwinn ML, Dodson RJ, Haft DH, Hickey EK, Peterson JD, Nelson WC and Fraser CM <19 more author(s)> Nelson KE, Clayton RA, Gill SR, Gwinn ML, Dodson RJ, Haft DH, Hickey EK, Peterson JD, Nelson WC, Ketchum KA, McDonald L, Utterback TR, Malek JA, Linher KD, Garrett MM, Stewart AM, Cotton MD, Pratt MS, Phillips CA, Richardson D, Heidelberg J, Sutton GG, Fleischmann RD, Eisen JA, White O, Salzberg SL, Smith HO, Venter JC, Fraser CM (- 19)
Ref: Nature, 399:323, 1999 : PubMed
Abstract


ESTHER: Nelson_1999_Nature_399_323
PubMedSearch: Nelson 1999 Nature 399 323
PubMedID: 10360571
Gene_locus related to this paper: thema-ESTA, thema-q9x0d6, thema-q9x042, thema-TM0033, thema-TM0053, thema-TM0077, thema-TM0336, thema-TM1160, thema-TM1350

Abstract

The 1,860,725-base-pair genome of Thermotoga maritima MSB8 contains 1,877 predicted coding regions, 1,014 (54%) of which have functional assignments and 863 (46%) of which are of unknown function. Genome analysis reveals numerous pathways involved in degradation of sugars and plant polysaccharides, and 108 genes that have orthologues only in the genomes of other thermophilic Eubacteria and Archaea. Of the Eubacteria sequenced to date, T. maritima has the highest percentage (24%) of genes that are most similar to archaeal genes. Eighty-one archaeal-like genes are clustered in 15 regions of the T. maritima genome that range in size from 4 to 20 kilobases. Conservation of gene order between T. maritima and Archaea in many of the clustered regions suggests that lateral gene transfer may have occurred between thermophilic Eubacteria and Archaea.



        

Title: Genome sequence of the radioresistant bacterium Deinococcus radiodurans R1
White O, Eisen JA, Heidelberg JF, Hickey EK, Peterson JD, Dodson RJ, Haft DH, Gwinn ML, Nelson WC and Fraser CM <22 more author(s)> White O, Eisen JA, Heidelberg JF, Hickey EK, Peterson JD, Dodson RJ, Haft DH, Gwinn ML, Nelson WC, Richardson DL, Moffat KS, Qin H, Jiang L, Pamphile W, Crosby M, Shen M, Vamathevan JJ, Lam P, McDonald L, Utterback T, Zalewski C, Makarova KS, Aravind L, Daly MJ, Minton KW, Fleischmann RD, Ketchum KA, Nelson KE, Salzberg S, Smith HO, Venter JC, Fraser CM (- 22)
Ref: Science, 286:1571, 1999 : PubMed
Abstract


ESTHER: White_1999_Science_286_1571
PubMedSearch: White 1999 Science 286 1571
PubMedID: 10567266
Gene_locus related to this paper: deira-aryla, deira-DR0165, deira-DR0334, deira-DR0553, deira-DR0593, deira-DR0654, deira-DR0657, deira-DR0779, deira-DR0791, deira-DR0945, deira-DR0964, deira-DR1053, deira-DR1064, deira-DR1326, deira-DR1351, deira-DR1352, deira-DR1403, deira-DR1537, deira-DR1915, deira-DR1931, deira-DR2078, deira-DR2248, deira-DR2478, deira-DR2503, deira-DR2506, deira-DR2522, deira-DR2549, deira-DR2551, deira-DRA0060, deira-DRA0150, deira-DRA0307, deira-DRA0340, deira-DRB0023, deira-DRB0097, deira-este1, deira-este2, deira-lip1, deira-lip2, deira-lipest, deira-metx

Abstract

The complete genome sequence of the radiation-resistant bacterium Deinococcus radiodurans R1 is composed of two chromosomes (2,648,638 and 412,348 base pairs), a megaplasmid (177,466 base pairs), and a small plasmid (45,704 base pairs), yielding a total genome of 3,284, 156 base pairs. Multiple components distributed on the chromosomes and megaplasmid that contribute to the ability of D. radiodurans to survive under conditions of starvation, oxidative stress, and high amounts of DNA damage were identified. Deinococcus radiodurans represents an organism in which all systems for DNA repair, DNA damage export, desiccation and starvation recovery, and genetic redundancy are present in one cell.



        

Title: Complete Genome Sequence of Treponema pallidum, the Syphilis Spirochete
Fraser CM, Norris SJ, Weinstock GM, White O, Sutton GG, Dodson R, Gwinn M, Hickey EK, Clayton R and Venter JC <23 more author(s)> Fraser CM, Norris SJ, Weinstock GM, White O, Sutton GG, Dodson R, Gwinn M, Hickey EK, Clayton R, Ketchum KA, Sodergren E, Hardham JM, McLeod MP, Salzberg S, Peterson J, Khalak H, Richardson D, Howell JK, Chidambaram M, Utterback T, McDonald L, Artiach P, Bowman C, Cotton MD, Fujii C, Garland S, Hatch B, Horst K, Roberts K, Sandusky M, Weidman J, Smith HO, Venter JC (- 23)
Ref: Science, 281:375, 1998 : PubMed
Abstract


ESTHER: Fraser_1998_Science_281_375
PubMedSearch: Fraser 1998 Science 281 375
PubMedID: 9665876
Gene_locus related to this paper: trepa-naptd, trepa-TP0902, trepa-TP0952

Abstract

The complete genome sequence of Treponema pallidum was determined and shown to be 1,138,006 base pairs containing 1041 predicted coding sequences (open reading frames). Systems for DNA replication, transcription, translation, and repair are intact, but catabolic and biosynthetic activities are minimized. The number of identifiable transporters is small, and no phosphoenolpyruvate:phosphotransferase carbohydrate transporters were found. Potential virulence factors include a family of 12 potential membrane proteins and several putative hemolysins. Comparison of the T. pallidum genome sequence with that of another pathogenic spirochete, Borrelia burgdorferi, the agent of Lyme disease, identified unique and common genes and substantiates the considerable diversity observed among pathogenic spirochetes.



        

Title: Genomic sequence of a Lyme disease spirochaete, Borrelia burgdorferi
Fraser CM, Casjens S, Huang WM, Sutton GG, Clayton R, Lathigra R, White O, Ketchum KA, Dodson R and Venter JC <28 more author(s)> Fraser CM, Casjens S, Huang WM, Sutton GG, Clayton R, Lathigra R, White O, Ketchum KA, Dodson R, Hickey EK, Gwinn M, Dougherty B, Tomb JF, Fleischmann RD, Richardson D, Peterson J, Kerlavage AR, Quackenbush J, Salzberg S, Hanson M, van Vugt R, Palmer N, Adams MD, Gocayne J, Weidman J, Utterback T, Watthey L, McDonald L, Artiach P, Bowman C, Garland S, Fujii C, Cotton MD, Horst K, Roberts K, Hatch B, Smith HO, Venter JC (- 28)
Ref: Nature, 390:580, 1997 : PubMed
Abstract


ESTHER: Fraser_1997_Nature_390_580
PubMedSearch: Fraser 1997 Nature 390 580
PubMedID: 9403685
Gene_locus related to this paper: borbu-BB0646

Abstract

The genome of the bacterium Borrelia burgdorferi B31, the aetiologic agent of Lyme disease, contains a linear chromosome of 910,725 base pairs and at least 17 linear and circular plasmids with a combined size of more than 533,000 base pairs. The chromosome contains 853 genes encoding a basic set of proteins for DNA replication, transcription, translation, solute transport and energy metabolism, but, like Mycoplasma genitalium, it contains no genes for cellular biosynthetic reactions. Because B. burgdorferi and M. genitalium are distantly related eubacteria, we suggest that their limited metabolic capacities reflect convergent evolution by gene loss from more metabolically competent progenitors. Of 430 genes on 11 plasmids, most have no known biological function; 39% of plasmid genes are paralogues that form 47 gene families. The biological significance of the multiple plasmid-encoded genes is not clear, although they may be involved in antigenic variation or immune evasion.



        

Title: The complete genome sequence of the hyperthermophilic, sulphate-reducing archaeon Archaeoglobus fulgidus
Klenk HP, Clayton RA, Tomb JF, White O, Nelson KE, Ketchum KA, Dodson RJ, Gwinn M, Hickey EK and Venter JC <41 more author(s)> Klenk HP, Clayton RA, Tomb JF, White O, Nelson KE, Ketchum KA, Dodson RJ, Gwinn M, Hickey EK, Peterson JD, Richardson DL, Kerlavage AR, Graham DE, Kyrpides NC, Fleischmann RD, Quackenbush J, Lee NH, Sutton GG, Gill S, Kirkness EF, Dougherty BA, McKenney K, Adams MD, Loftus B, Peterson S, Reich CI, McNeil LK, Badger JH, Glodek A, Zhou L, Overbeek R, Gocayne JD, Weidman JF, McDonald L, Utterback T, Cotton MD, Spriggs T, Artiach P, Kaine BP, Sykes SM, Sadow PW, D'Andrea KP, Bowman C, Fujii C, Garland SA, Mason TM, Olsen GJ, Fraser CM, Smith HO, Woese CR, Venter JC (- 41)
Ref: Nature, 390:364, 1997 : PubMed
Abstract


ESTHER: Klenk_1997_Nature_390_364
PubMedSearch: Klenk 1997 Nature 390 364
PubMedID: 9389475
Gene_locus related to this paper: arcfu-AF0514, arcfu-AF0675, arcfu-AF1134, arcfu-AF1563, arcfu-AF1753, arcfu-AF1763, arcfu-est1, arcfu-est2, arcfu-est3, arcfu-estea, arcfu-o28594, arcfu-o29442, arcfu-pcbd

Abstract

Archaeoglobus fulgidus is the first sulphur-metabolizing organism to have its genome sequence determined. Its genome of 2,178,400 base pairs contains 2,436 open reading frames (ORFs). The information processing systems and the biosynthetic pathways for essential components (nucleotides, amino acids and cofactors) have extensive correlation with their counterparts in the archaeon Methanococcus jannaschii. The genomes of these two Archaea indicate dramatic differences in the way these organisms sense their environment, perform regulatory and transport functions, and gain energy. In contrast to M. jannaschii, A. fulgidus has fewer restriction-modification systems, and none of its genes appears to contain inteins. A quarter (651 ORFs) of the A. fulgidus genome encodes functionally uncharacterized yet conserved proteins, two-thirds of which are shared with M. jannaschii (428 ORFs). Another quarter of the genome encodes new proteins indicating substantial archaeal gene diversity.



        

Title: The complete genome sequence of the gastric pathogen Helicobacter pylori.
Tomb J-F, White O, Kerlavage AR, Clayton RA, Sutton GG, Fleischmann RD, Ketchum KA, Klenk H-P, Gill S and Venter JC <32 more author(s)> Tomb J-F, White O, Kerlavage AR, Clayton RA, Sutton GG, Fleischmann RD, Ketchum KA, Klenk H-P, Gill S, Dougherty BA, Nelson K, Quackenbush J, Zhou L, Kirkness EF, Peterson S, Loftus B, Richardson D, Dodson R, Khalak HG, Glodek A, McKenney K, FitzGerald LM, Lee N, Adams MD, Hickey EK, Berg DE, Gocayne JD, Utterback TR, Peterson JD, Kelley JM, Cotton MD, Weidman JM, Fujii C, Bowman C, Watthey L, Wallin E, Hayes WS, Borodovsky M, Karp PD, Smith HO, Fraser CM, Venter JC (- 32)
Ref: Nature, 388:539, 1997 : PubMed
Abstract


ESTHER: Tomb_1997_Nature_388_539
PubMedSearch: Tomb 1997 Nature 388 539
PubMedID: 9252185
Gene_locus related to this paper: helpy-HP0739, helpy-o25061

Abstract

Helicobacter pylori, strain 26695, has a circular genome of 1,667,867 base pairs and 1,590 predicted coding sequences. Sequence analysis indicates that H. pylori has well-developed systems for motility, for scavenging iron, and for DNA restriction and modification. Many putative adhesins, lipoproteins and other outer membrane proteins were identified, underscoring the potential complexity of host-pathogen interaction. Based on the large number of sequence-related genes encoding outer membrane proteins and the presence of homopolymeric tracts and dinucleotide repeats in coding sequences, H. pylori, like several other mucosal pathogens, probably uses recombination and slipped-strand mispairing within repeats as mechanisms for antigenic variation and adaptive evolution. Consistent with its restricted niche, H. pylori has a few regulatory networks, and a limited metabolic repertoire and biosynthetic capacity. Its survival in acid conditions depends, in part, on its ability to establish a positive inside-membrane potential in low pH.