Okura VK

References (2)

Title : Comparison of the genomes of two Xanthomonas pathogens with differing host specificities - da Silva_2002_Nature_417_459
Author(s) : da Silva ACR , Ferro JA , Reinach FC , Farah CS , Furlan LR , Quaggio RB , Monteiro-Vitorello CB , Van Sluys MA , Almeida Jr NF , Alves LMC , do Amaral AM , Bertolini MC , Camargo LEA , Camarotte G , Cannavan F , Cardozo J , Chambergo F , Ciapina LP , Cicarelli RMB , Coutinho LL , Cursino-Santos JR , El-Dorry H , Faria JB , Ferreira AJS , Ferreira RCC , Ferro MIT , Formighieri EF , Franco MC , Greggio CC , Gruber A , Katsuyama AM , Kishi LT , Leite JrRP , Lemos EGM , Lemos MVF , Locali EC , Machado MA , Madeira AMBN , Martinez-Rossi NM , Martins EC , Meidanis J , Menck CFM , Miyaki CY , Moon DH , Moreira LM , Novo MTM , Okura VK , Oliveira MC , Oliveira VR , Pereira Jr HA , Rossi A , Sena JAD , Silva C , de Souza RF , Spinola LAF , Takita MA , Tamura RE , Teixeira EC , Tezza RID , Trindade dos Santos M , Truffi D , Tsai SM , White FF , Setubal JC , Kitajima JP
Ref : Nature , 417 :459 , 2002
Abstract : The genus Xanthomonas is a diverse and economically important group of bacterial phytopathogens, belonging to the gamma-subdivision of the Proteobacteria. Xanthomonas axonopodis pv. citri (Xac) causes citrus canker, which affects most commercial citrus cultivars, resulting in significant losses worldwide. Symptoms include canker lesions, leading to abscission of fruit and leaves and general tree decline. Xanthomonas campestris pv. campestris (Xcc) causes black rot, which affects crucifers such as Brassica and Arabidopsis. Symptoms include marginal leaf chlorosis and darkening of vascular tissue, accompanied by extensive wilting and necrosis. Xanthomonas campestris pv. campestris is grown commercially to produce the exopolysaccharide xanthan gum, which is used as a viscosifying and stabilizing agent in many industries. Here we report and compare the complete genome sequences of Xac and Xcc. Their distinct disease phenotypes and host ranges belie a high degree of similarity at the genomic level. More than 80% of genes are shared, and gene order is conserved along most of their respective chromosomes. We identified several groups of strain-specific genes, and on the basis of these groups we propose mechanisms that may explain the differing host specificities and pathogenic processes.
ESTHER : da Silva_2002_Nature_417_459
PubMedSearch : da Silva_2002_Nature_417_459
PubMedID: 12024217
Gene_locus related to this paper: xanac-q8phx9 , xanac-q8pmm6 , xanax-ACVB , xanax-BIOH , xanax-CATD , xanax-CPO , xanax-DHAA , xancp-OleB , xanax-ENTF2 , xanax-estA1 , xanax-GAA , xanax-META , xanax-METX , xanax-PCAD , xanax-PHBC , xanax-PTRB , xanax-Q8PMQ8 , xanax-Q8PQP0 , xanax-XAC0198 , xanax-XAC0262 , xanax-XAC0279 , xanax-XAC0319 , xanax-XAC0372 , xanax-XAC0375 , xanax-XAC0501 , xanax-XAC0515 , xanax-XAC0574 , xanax-XAC0591 , xanax-XAC0619 , xanax-XAC0628 , xanax-XAC0736 , xanax-XAC0753 , xanax-XAC0805 , xanax-XAC0874 , xanax-XAC0916 , xanax-XAC1200 , xanax-XAC1213 , xanax-XAC1591 , xanax-XAC1713 , xanax-XAC1752 , xanax-XAC2126 , xanax-XAC2393 , xanax-XAC2532 , xanax-XAC2541 , xanax-XAC2907 , xanax-XAC2981 , xanax-XAC2987 , xanax-XAC2990 , xanax-XAC3037 , xanax-XAC3053 , xanax-XAC3152 , xanax-XAC3173 , xanax-XAC3315 , xanax-XAC3371 , xanax-XAC3619 , xanax-XAC3674 , xanax-XAC3770 , xanax-XAC3967 , xanax-XAC3999 , xanax-XAC4046 , xanax-XAC4055 , xanax-XAC4106 , xanax-XAC4221 , xanax-XAC4316 , xanax-XYNB , xanca-acvB , xanca-BIOH , xanca-CATD , xanca-CPO , xanca-estA1 , xanca-impep , xanca-META , xanca-METX , xanca-PCAD , xanca-PHBC , xanca-Q8PB04 , xanca-W78 , xanca-XCC0080 , xanca-XCC0180 , xanca-XCC0243 , xanca-XCC0260 , xanca-XCC0266 , xanca-XCC0372 , xanca-XCC0375 , xanca-XCC0753 , xanca-XCC0757 , xanca-XCC0800 , xanca-XCC0843 , xanca-XCC1105 , xanca-XCC1541 , xanca-XCC1734 , xanca-XCC2285 , xanca-XCC2374 , xanca-XCC2397 , xanca-XCC2405 , xanca-XCC2566 , xanca-XCC2722 , xanca-XCC2737 , xanca-XCC2811 , xanca-XCC2817 , xanca-XCC2854 , xanca-XCC2869 , xanca-XCC2957 , xanca-XCC3028 , xanca-XCC3164 , xanca-XCC3219 , xanca-XCC3296 , xanca-XCC3300 , xanca-XCC3308 , xanca-XCC3320 , xanca-XCC3514 , xanca-XCC3548 , xanca-XCC3555 , xanca-XCC3623 , xanca-XCC3885 , xanca-XCC3915 , xanca-XCC3961 , xanca-XCC3970 , xanca-XCC4016 , xanca-XCC4096 , xanca-XCC4180 , xanca-XYNB , xanca-XYNB2 , xancb-b0rq23 , xancp-q8pax3 , xancp-y2094

Title : The genome of the natural genetic engineer Agrobacterium tumefaciens C58 - Wood_2001_Science_294_2317
Author(s) : Wood DW , Setubal JC , Kaul R , Monks DE , Kitajima JP , Okura VK , Zhou Y , Chen L , Wood GE , Almeida NF, Jr. , Woo L , Chen Y , Paulsen IT , Eisen JA , Karp PD , Bovee D, Sr. , Chapman P , Clendenning J , Deatherage G , Gillet W , Grant C , Kutyavin T , Levy R , Li MJ , McClelland E , Palmieri A , Raymond C , Rouse G , Saenphimmachak C , Wu Z , Romero P , Gordon D , Zhang S , Yoo H , Tao Y , Biddle P , Jung M , Krespan W , Perry M , Gordon-Kamm B , Liao L , Kim S , Hendrick C , Zhao ZY , Dolan M , Chumley F , Tingey SV , Tomb JF , Gordon MP , Olson MV , Nester EW
Ref : Science , 294 :2317 , 2001
Abstract : The 5.67-megabase genome of the plant pathogen Agrobacterium tumefaciens C58 consists of a circular chromosome, a linear chromosome, and two plasmids. Extensive orthology and nucleotide colinearity between the genomes of A. tumefaciens and the plant symbiont Sinorhizobium meliloti suggest a recent evolutionary divergence. Their similarities include metabolic, transport, and regulatory systems that promote survival in the highly competitive rhizosphere; differences are apparent in their genome structure and virulence gene complement. Availability of the A. tumefaciens sequence will facilitate investigations into the molecular basis of pathogenesis and the evolutionary divergence of pathogenic and symbiotic lifestyles.
ESTHER : Wood_2001_Science_294_2317
PubMedSearch : Wood_2001_Science_294_2317
PubMedID: 11743193
Gene_locus related to this paper: agrt5-a9cf94 , agrt5-a9cfa9 , agrt5-a9cfs8 , agrt5-a9cfu7 , agrt5-a9cie7 , agrt5-a9cj11 , agrt5-a9cjp2 , agrt5-a9cki2 , agrt5-a9ckr2 , agrt5-a9ckt2 , agrt5-a9cle4 , agrt5-a9clq8 , agrt5-a9clq9 , agrt5-q7cx24 , agrt5-q7d1j0 , agrt5-q7d1j3 , agrt5-q7d3m5 , agrt5-y5261 , agrtu-ACVB , agrtu-ATTS , agrtu-ATU0253 , agrtu-ATU0403 , agrtu-ATU0841 , agrtu-ATU1045 , agrtu-ATU1102 , agrtu-ATU1572 , agrtu-ATU1617 , agrtu-ATU1826 , agrtu-ATU1842 , agrtu-ATU2061 , agrtu-ATU2126 , agrtu-ATU2171 , agrtu-ATU2409 , agrtu-ATU2452 , agrtu-ATU2481 , agrtu-ATU2497 , agrtu-ATU2576 , agrtu-ATU3428 , agrtu-ATU3651 , agrtu-ATU3652 , agrtu-ATU4238 , agrtu-ATU5190 , agrtu-ATU5193 , agrtu-ATU5275 , agrtu-ATU5296 , agrtu-ATU5348 , agrtu-ATU5389 , agrtu-ATU5446 , agrtu-ATU5495 , agrtu-CPO , agrtu-DHAA , agrtu-DLHH , agrtu-EPHA , agrtu-GRST , agrtu-PCA , agrtu-PCAD , agrtu-PHBC , agrtu-PTRB , agrt5-a9cji8