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| Registros recuperados : 7 | |
| 1. |  | STEENKAMP, E.; BRITZ, H.; COUTINHO, T.; WINGFIELD, B.; MARASAS, W.; WINGFIELD, M. Molecular characterization of Fusarium subglutinans associated with mango malformation. Molecular Plant Pathology, v.1, n.3, p.187-193, 2000.| Biblioteca(s): Embrapa Semiárido. |
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| 2. | | LAJUDIE, P. M. de; ANDREWS, M.; ARDLEY, J.; EARDLY, B.; JUMAS-BILAK, E.; KUZMANOVIC, N.; LASSALE, F.; LINDSTRÖM, K.; MHAMDI, R.; MARTINEZ-ROMERO, E.; MOULIN, L.; MOUSAVI, S. A.; NESME, X.; PEIX, A.; PULAWSKA, J.; STEENKAMP, E.; STEPKOWSKI, T.; TIAN, C-F; VINUESA, P.; WEI, G.; WILLEMS, A.; ZILLI, J. E.; YOUNG, P. Minimal standards for the description of new genera and species of rhizobia and agrobacteria. International Journal of Systematic and Evolutionary Microbiology, v 69, p. 1852-1863, 2019.| Biblioteca(s): Embrapa Agrobiologia. |
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| 3. | | ESTRADA DE LOS DANTOS, P.; PALMER, M.; CHAVEZ-RAMIREZ, B.; BEUKES, C.; STEENKAMP, E. T.; BRISCOE, L.; KHAN, N.; MALUK, M.; LAFOS, M.; HUMM, E.; ARRABIT, M.; CROOK, M.; GROSS, E.; SIMON, M. F.; REIS JUNIOR, F. B. dos; WHITMAN, W. B.; SHAPIRO, N.; POOLE, P. S.; HIRSCH, A. M.; VENTER, S. N.; JAMES, E. K. Whole genome analyses suggests that Burkholderiasensu lato contains two additional novel genera (Mycetohabitans gen. nov., and Trinickia gen. nov.): implications for the evolution of diazotrophy and nodulation in the Burkholderiaceae. Genes, v. 9, n. 8, article 389, 2018.| Biblioteca(s): Embrapa Cerrados. |
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| 4. | | ESTRADA DE LOS SANTOS, P.; PALMER, M.; CHAVEZ-RAMIREZ, B.; BEUKES, C.; STEENKAMP, E. T.; BRISCOE, L.; KHAN, N.; MALUK, M.; LAFOS, M.; HUMM, E.; ARRABIT, M.; CROOK, M.; GROSS, E.; SIMON, M. F.; REIS JUNIOR, F. B. dos; WHITMAN, W. B.; SHAPIRO, N.; POOLE, P. S.; HIRSCH, A. M.; VENTER, S. N.; JAMES, E. K. Whole genome analyses suggests that Burkholderiasensu lato contains two additional novel genera (Mycetohabitans gen. nov., and Trinickia gen. nov.): implications for the evolution of diazotrophy and nodulation in the Burkholderiaceae. Genes, v. 9, n. 8, article 389, 2018.| Biblioteca(s): Embrapa Recursos Genéticos e Biotecnologia. |
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| 5. | | JAMES, E. K.; FARIA, S. M. de; HUGHE, C. E.; VENTER, S. N.; AMETSITSI, G. K. D.; ARDLEY, J.; BEUKES, C. W.; CARDOSO, D.; CHAN, A.; CHIMPHANG, S.; REIS JUNIOR, F. B. dos; GEHLO, H. S.; ROSS, E.; KOENEN, E. J. M.; LIMA, H. de C.; MALUK, M.; MAVIMA, L.; DE MEYER, S. E.; MUASYA, M.; PRIN, Y.; RINGELBERG, J. J.; SIMON, M. F.; SPRENT, J. I.; STEENKAMP, E.; TAK, N.; YOUNG, P. W.; ZARTMANN, C. What can the diversity of nodulation phenotypes and rhizobial symbionts in the caesalpinioideae tell us about the evolution of the legume-rhizobium symbiosis? In: INTERNATIONAL LEGUME CONFERENCE, 8., 2023, Pirenópolis. Integrating knowledge on the legume family: [abstracts]. Pirenópolis: [s.n.], 2023.| Biblioteca(s): Embrapa Cerrados. |
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| 6. | | JAMES, E. K.; FARIA, S. M. de; HUGHE, C. E.; VENTER, S. N.; AMETSITSI, G. K. D.; ARDLEY, J.; BEUKES, C. W.; CARDOSO, D.; CHAN, A.; CHIMPHANG, S.; REIS JUNIOR, F. B. dos; GEHLO, H. S.; ROSS, E.; KOENEN, E. J. M.; LIMA, H. de C.; MALUK, M.; MAVIMA, L.; DE MEYER, S. E.; MUASYA, M.; PRIN, Y.; RINGELBERG, J. J.; SIMON, M. F.; SPRENT, J. I.; STEENKAMP, E.; TAK, N.; YOUNG, P. W.; ZARTMANN, C. What can the diversity of nodulation phenotypes and rhizobial symbionts in the caesalpinioideae tell us about the evolution of the legume-rhizobium symbiosis? In: INTERNATIONAL LEGUME CONFERENCE, 8., 2023, Pirenópolis. Integrating knowledge on the legume family: [abstracts]. Pirenópolis: [s.n.], 2023.| Biblioteca(s): Embrapa Agrobiologia; Embrapa Recursos Genéticos e Biotecnologia. |
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| 7. | | GEISER, D. M.; AL-HATMI, A. M. S.; AOKI, T.; ARIE, T.; BALMAS, V.; BARNES, I.; BERGSTROM, G. C.; BHATTACHARYYA, M. K.; BLOMQUIST, C. L.; BOWDEN, R. L.; BRANKOVICS, B.; BROWN, D. W.; BURGESS, L. W.; BUSHLEY, K.; BUSMAN, M.; CANO-LIRA, J. F.; CARRILLO, J. D.; CHANG, H. X.; CHEN, C. Y.; CHEN, W.; CHILVERS, M.; CHULZE, S.; COLEMAN, J. J.; CUOMO, C. A.; BEER, Z. W. de; HOOG, G. S. de; CASTILLO-MÚNERA, J. del; PONTE, E. M. del; DIÉGUEZ-URIBEONDO, J.; PIETRO, A. di; EDEL-HERMANN, V.; ELMER, W. H.; EPSTEIN, L.; ESKALEN, A.; ESPOSTO, M. C.; EVERTS, K. L.; FERNÁNDEZ-PAVÍA, S. P.; SILVA, G. F. da; FOROUD, N. A.; FOURIE, G.; FRANDSEN, R. J. N.; FREEMAN, S.; FREITAG, M.; FRENKEL, O.; FULLER, K. K.; GAGKAEVA, T.; GARDINER, D. M.; GLENN, A. E.; GOLD, S. E.; GORDON, T. R.; GREGORY, N. F.; GRYZENHOUT, M.; GUARRO, J.; GUGINO, B. K.; GUTIERREZ, S.; HAMMOND-KOSACK, K. E.; HARRIS, L. J.; HOMA, M.; HONG, C. F.; HORNOK, L.; HUANG, J. W.; ILKIT, M.; JACOBS, A.; JIANG, C.; JIMÉNEZ-GASCO, M. del M.; KANG, S.; KASSON, M. T.; KAZAN, K.; KENNELL, J. C.; KIM, H. S.; KISTLER, H. C.; KULDAU, G. A.; KULIK, T.; KURZAI, O.; LARABA, I.; LAURENCE, M. H.; LEE, T.; LEE, Y. W.; LESLIE, J. F.; LIEW, E. C. Y.; LOFTON, L. W.; LOGRIECO, A. F.; LÓPEZ-BERGES, M. S.; LUQUE, A. G.; LYSØE, E.; MA, L. J.; MARRA, R. E.; MARTIN, F. N.; MAY, S. R.; McCORMICK, S. P.; McGEE, C.; MEIS, J. F.; MIGHELI, Q.; NOR, N. M. I. M.; MONOD, M.; MORETTI, A.; MOSTERT, D.; MULÈ, G.; MUNAUT, F.; MUNKVOLD, G. P.; NICHOLSON, P.; NUCCI, M.; O'DONNELL, K.; PASQUALI, M.; PFENNING, L. H.; PRIGITANO, A.; PROCTOR, R. H.; RANQUE, S.; REHNER, S. A.; REP, M.; RODRÍGUEZ-ALVARADO, G.; ROSE, L. J.; ROTH, M. G.; RUIZ-ROLDÁN, C.; SALEH, A. A.; SALLEH, B.; SANG, H.; SCANDIANI, M. M.; SCAUFLAIRE, J.; SCHMALE III, D. G.; SHORT, D. P. G.; SISIC, A.; SMITH, J. A.; SMYTH, C. W.; SON, H.; SPAHR, E.; STAJICH, J. E.; STEENKAMP, E.; STEINBERG, C.; SUBRAMANIAM, R.; SUGA, H.; SUMMERELL, B. A.; SUSCA, A.; SWETT, C. L.; TOOMAJIAN, C.; TORRES-CRUZ, T. J.; TORTORANO, A. M.; URBAN, M.; VAILLANCOURT, L. J.; VALLAD, G. E.; LEE, T. A. J. van der; VANDERPOOL, D.; DIEPENINGEN, A. D. van; VAUGHAN, M. M.; VENTER, E.; VERMEULEN, M.; VERWEIJ, P. E.; VILJOEN, A.; WAALWIJK, C.; WALLACE, E. C.; WALTHER, G.; WANG, J.; WARD, T. J.; WICKES, B. L.; WIEDERHOLD, N. P.; WINGFIELD, M. J.; WOOD, A. K. M.; XU, J. R.; YANG, X. B.; YLI-MATTILA, T.; YUN, S. H.; ZAKARIA, L.; ZHANG, H.; ZHANG, N.; ZHAN, S. X.; ZHAN, X. Phylogenomic analysis of a 55.1 kb 19-gene dataset resolves a monophyletic Fusarium that includes the Fusarium solani Species Complex. Phytopathology, v. 111, n. 7, p. 1064-1079, 2021.| Biblioteca(s): Embrapa Amazônia Ocidental. |
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| Registros recuperados : 7 | |
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Registro Completo
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Biblioteca(s): |
Embrapa Recursos Genéticos e Biotecnologia. |
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Data corrente: |
05/10/2018 |
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Data da última atualização: |
23/06/2022 |
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Tipo da produção científica: |
Artigo em Periódico Indexado |
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Circulação/Nível: |
A - 2 |
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Autoria: |
ESTRADA DE LOS SANTOS, P.; PALMER, M.; CHAVEZ-RAMIREZ, B.; BEUKES, C.; STEENKAMP, E. T.; BRISCOE, L.; KHAN, N.; MALUK, M.; LAFOS, M.; HUMM, E.; ARRABIT, M.; CROOK, M.; GROSS, E.; SIMON, M. F.; REIS JUNIOR, F. B. dos; WHITMAN, W. B.; SHAPIRO, N.; POOLE, P. S.; HIRSCH, A. M.; VENTER, S. N.; JAMES, E. K. |
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Afiliação: |
Paulina Estrada-de los Santos, Instituto Politécnico Nacional, Escuela Nacional de Ciencias Biológica; Marike Palmer, University of Pretoria; Belén Chávez-Ramírez, Instituto Politécnico Nacional, Escuela Nacional de Ciencias Biológicas; Chrizelle Beukes, University of Pretoria; Emma T. Steenkamp, University of Pretoria; Leah Briscoe, University of California; Noor Khan, University of California; Marta Maluk, The James Hutton Institute; Marcel Lafos, The James Hutton Institute; Ethan Humm, University of California; Monique Arrabit, University of California; Matthew Crook, Weber State University; Eduardo Gross, Santa Cruz State University; MARCELO FRAGOMENI SIMON, Cenargen; FABIO BUENO DOS REIS JUNIOR, CPAC; William B. Whitman, University of Georgia; Nicole Shapiro, Walnut Creek; Philip S. Poole, University of Oxford; Ann M. Hirsch, University of California; Stephanus N. Venter, University of Pretoria; Euan K. James, The James Hutton Institute. |
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Título: |
Whole genome analyses suggests that Burkholderiasensu lato contains two additional novel genera (Mycetohabitans gen. nov., and Trinickia gen. nov.): implications for the evolution of diazotrophy and nodulation in the Burkholderiaceae. |
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Ano de publicação: |
2018 |
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Fonte/Imprenta: |
Genes, v. 9, n. 8, article 389, 2018. |
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DOI: |
https://doi.org/10.3390/genes9080389 |
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Idioma: |
Inglês |
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Conteúdo: |
Burkholderia sensu lato is a large and complex group, containing pathogenic, phytopathogenic, symbiotic and non-symbiotic strains from a very wide range of environmental (soil, water, plants, fungi) and clinical (animal, human) habitats. Its taxonomy has been evaluated several times through the analysis of 16S rRNA sequences, concantenated 4?7 housekeeping gene sequences, and lately by genome sequences. Currently, the division of this group into Burkholderia, Caballeronia, Paraburkholderia, and Robbsia is strongly supported by genome analysis. These new genera broadly correspond to the various habitats/lifestyles of Burkholderia s.l., e.g., all the plant beneficial and environmental (PBE) strains are included in Paraburkholderia (which also includes all the N2-fixing legume symbionts) and Caballeronia, while most of the human and animal pathogens are retained in Burkholderia sensu stricto. However, none of these genera can accommodate two important groups of species. One of these includes the closely related Paraburkholderia rhizoxinica and Paraburkholderia endofungorum, which are both symbionts of the fungal phytopathogen Rhizopus microsporus. The second group comprises the Mimosa-nodulating bacterium Paraburkholderia symbiotica, the phytopathogen Paraburkholderia caryophylli, and the soil bacteria Burkholderia dabaoshanensis and Paraburkholderia soli. In order to clarify their positions within Burkholderia sensu lato, a phylogenomic approach based on a maximum likelihood analysis of conserved genes from more than 100 Burkholderia sensu lato species was carried out. Additionally, the average nucleotide identity (ANI) and amino acid identity (AAI) were calculated. The data strongly supported the existence of two distinct and unique clades, which in fact sustain the description of two novel genera Mycetohabitans gen. nov. and Trinickia gen. nov. The newly proposed combinations are Mycetohabitans endofungorum comb. nov., Mycetohabitansrhizoxinica comb. nov., Trinickia caryophylli comb. nov., Trinickiadabaoshanensis comb. nov., Trinickia soli comb. nov., and Trinickiasymbiotica comb. nov. Given that the division between the genera that comprise Burkholderia s.l. in terms of their lifestyles is often complex, differential characteristics of the genomes of these new combinations were investigated. In addition, two important lifestyle-determining traits?diazotrophy and/or symbiotic nodulation, and pathogenesis?were analyzed in depth i.e., the phylogenetic positions of nitrogen fixation and nodulation genes in Trinickia via-à-vis other Burkholderiaceae were determined, and the possibility of pathogenesis in Mycetohabitans and Trinickia was tested by performing infection experiments on plants and the nematode Caenorhabditis elegans. It is concluded that (1) T. symbiotica nif and nod genes fit within the wider Mimosa-nodulating Burkholderiaceae but appear in separate clades and that T. caryophyllinif genes are basal to the free-living Burkholderia s.l. strains, while with regard to pathogenesis (2) none of the Mycetohabitans and Trinickia strains tested are likely to be pathogenic, except for the known phytopathogen T. caryophylli. MenosBurkholderia sensu lato is a large and complex group, containing pathogenic, phytopathogenic, symbiotic and non-symbiotic strains from a very wide range of environmental (soil, water, plants, fungi) and clinical (animal, human) habitats. Its taxonomy has been evaluated several times through the analysis of 16S rRNA sequences, concantenated 4?7 housekeeping gene sequences, and lately by genome sequences. Currently, the division of this group into Burkholderia, Caballeronia, Paraburkholderia, and Robbsia is strongly supported by genome analysis. These new genera broadly correspond to the various habitats/lifestyles of Burkholderia s.l., e.g., all the plant beneficial and environmental (PBE) strains are included in Paraburkholderia (which also includes all the N2-fixing legume symbionts) and Caballeronia, while most of the human and animal pathogens are retained in Burkholderia sensu stricto. However, none of these genera can accommodate two important groups of species. One of these includes the closely related Paraburkholderia rhizoxinica and Paraburkholderia endofungorum, which are both symbionts of the fungal phytopathogen Rhizopus microsporus. The second group comprises the Mimosa-nodulating bacterium Paraburkholderia symbiotica, the phytopathogen Paraburkholderia caryophylli, and the soil bacteria Burkholderia dabaoshanensis and Paraburkholderia soli. In order to clarify their positions within Burkholderia sensu lato, a phylogenomic approach based on a maximum likelihood a... Mostrar Tudo |
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Palavras-Chave: |
Genes conservados. |
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Thesagro: |
Análise Comparativa; Filogenia; Genoma. |
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Thesaurus NAL: |
Burkholderiaceae. |
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Categoria do assunto: |
V Taxonomia de Organismos |
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URL: |
https://ainfo.cnptia.embrapa.br/digital/bitstream/item/183636/1/Whole-Genome-Analyses-Suggests-that-Burkholderia-sensu-lato-Contains-Two-Additional-Novel-Genera-apagar.pdf
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Marc: |
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008 2018 bl uuuu u00u1 u #d
024 7 $ahttps://doi.org/10.3390/genes9080389$2DOI
100 1 $aESTRADA DE LOS SANTOS, P.
245 $aWhole genome analyses suggests that Burkholderiasensu lato contains two additional novel genera (Mycetohabitans gen. nov., and Trinickia gen. nov.)$bimplications for the evolution of diazotrophy and nodulation in the Burkholderiaceae.$h[electronic resource]
260 $c2018
520 $aBurkholderia sensu lato is a large and complex group, containing pathogenic, phytopathogenic, symbiotic and non-symbiotic strains from a very wide range of environmental (soil, water, plants, fungi) and clinical (animal, human) habitats. Its taxonomy has been evaluated several times through the analysis of 16S rRNA sequences, concantenated 4?7 housekeeping gene sequences, and lately by genome sequences. Currently, the division of this group into Burkholderia, Caballeronia, Paraburkholderia, and Robbsia is strongly supported by genome analysis. These new genera broadly correspond to the various habitats/lifestyles of Burkholderia s.l., e.g., all the plant beneficial and environmental (PBE) strains are included in Paraburkholderia (which also includes all the N2-fixing legume symbionts) and Caballeronia, while most of the human and animal pathogens are retained in Burkholderia sensu stricto. However, none of these genera can accommodate two important groups of species. One of these includes the closely related Paraburkholderia rhizoxinica and Paraburkholderia endofungorum, which are both symbionts of the fungal phytopathogen Rhizopus microsporus. The second group comprises the Mimosa-nodulating bacterium Paraburkholderia symbiotica, the phytopathogen Paraburkholderia caryophylli, and the soil bacteria Burkholderia dabaoshanensis and Paraburkholderia soli. In order to clarify their positions within Burkholderia sensu lato, a phylogenomic approach based on a maximum likelihood analysis of conserved genes from more than 100 Burkholderia sensu lato species was carried out. Additionally, the average nucleotide identity (ANI) and amino acid identity (AAI) were calculated. The data strongly supported the existence of two distinct and unique clades, which in fact sustain the description of two novel genera Mycetohabitans gen. nov. and Trinickia gen. nov. The newly proposed combinations are Mycetohabitans endofungorum comb. nov., Mycetohabitansrhizoxinica comb. nov., Trinickia caryophylli comb. nov., Trinickiadabaoshanensis comb. nov., Trinickia soli comb. nov., and Trinickiasymbiotica comb. nov. Given that the division between the genera that comprise Burkholderia s.l. in terms of their lifestyles is often complex, differential characteristics of the genomes of these new combinations were investigated. In addition, two important lifestyle-determining traits?diazotrophy and/or symbiotic nodulation, and pathogenesis?were analyzed in depth i.e., the phylogenetic positions of nitrogen fixation and nodulation genes in Trinickia via-à-vis other Burkholderiaceae were determined, and the possibility of pathogenesis in Mycetohabitans and Trinickia was tested by performing infection experiments on plants and the nematode Caenorhabditis elegans. It is concluded that (1) T. symbiotica nif and nod genes fit within the wider Mimosa-nodulating Burkholderiaceae but appear in separate clades and that T. caryophyllinif genes are basal to the free-living Burkholderia s.l. strains, while with regard to pathogenesis (2) none of the Mycetohabitans and Trinickia strains tested are likely to be pathogenic, except for the known phytopathogen T. caryophylli.
650 $aBurkholderiaceae
650 $aAnálise Comparativa
650 $aFilogenia
650 $aGenoma
653 $aGenes conservados
700 1 $aPALMER, M.
700 1 $aCHAVEZ-RAMIREZ, B.
700 1 $aBEUKES, C.
700 1 $aSTEENKAMP, E. T.
700 1 $aBRISCOE, L.
700 1 $aKHAN, N.
700 1 $aMALUK, M.
700 1 $aLAFOS, M.
700 1 $aHUMM, E.
700 1 $aARRABIT, M.
700 1 $aCROOK, M.
700 1 $aGROSS, E.
700 1 $aSIMON, M. F.
700 1 $aREIS JUNIOR, F. B. dos
700 1 $aWHITMAN, W. B.
700 1 $aSHAPIRO, N.
700 1 $aPOOLE, P. S.
700 1 $aHIRSCH, A. M.
700 1 $aVENTER, S. N.
700 1 $aJAMES, E. K.
773 $tGenes$gv. 9, n. 8, article 389, 2018.
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Embrapa Recursos Genéticos e Biotecnologia (CENARGEN) |
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