Studies on the agrocin 84 plasmid of `Agrobacterium radiobacter`

Shim, Je-Seop.

January 1987

Includes two journal articles with contributions by the author Bibliography: leaves 145-154

Pathogenic bacteria

Crown-gall disease

Plasmids

Insertion elements, DNA

Rhizobiaceae Biological control

Isolation of putative pAgK84 transconjugants from commerical cherry and raspberry plants treated with Agrobacterium radiobacter strain K84

Lu, Shu-Fen

25 August 1994

Graduation date: 1995

Agrobacterium radiobacter

Crown-gall disease

Cherry -- Diseases and pests

Raspberries -- Diseases and pests

Two of the Mechanims Used by Bacteria to Modify the Environment: Quorum Sensing and ACC Deaminase

Hao, Youai

January 2009

Quorum sensing (QS) cell-cell communication systems are utilized by bacteria to coordinate their behaviour according to cell density. Several different types of QS signal molecules have been identified, among which acyl-homoserine lactones (AHLs) produced by Proteobacteria have been studied to the greatest extent. QS has been shown to be involved in many aspects of bacterial life, including virulence, bioluminescence, symbiosis, antibiotic production, swarming and swimming motility, biofilm formation, conjugation and growth inhibition. Although QS has been studied extensively in cultured microorganisms, little is known about the QS systems of uncultured microorganisms and the roles of these systems in microbial communities. To extend our knowledge of QS systems and to better understand the signalling that takes place in the natural environment, in the first part of this thesis, isolation and characterization of new QS systems from metagenomic libraries constructed using DNA from activated sludge and soil were described. Using an Agrobacterium biosensor strain, three cosmids (QS6-1, QS10-1 and QS10-2) that encode the production of QS signals were identified and DNA sequence analysis revealed that all three clones encode a novel luxI family AHL synthase and a luxR family transcriptional regulator. Thin layer chromatography revealed that these LuxI homolog proteins are able to synthesize multiple AHL signals. Tandem mass spectrometry analysis revealed that LuxIQS6-1 directs the synthesis of at least three AHLs, 3-O-C14:1 HSL, 3-O-C16:1 HSL and 3-O-C14 HSL; LuxIQS10-1 directs the synthesis of at least 3-O-C12 HSL and 3-O-C14 HSL; while LuxIQS10-2 directs the synthesis of at least C8 HSL and C10 HSL. Two possible new AHLs, C14:3 HSL and (?)-hydroxymethyl-3-O-C14 HSL, were also found to be synthesized by LuxIQS6-1. Agrobacterium tumefaciens is a plant pathogen that causes crown gall disease. Its ability to transfer and integrate foreign DNA into plant genome also makes it a useful tool for plant genetic engineering. Ethylene, the gaseous plant hormone, has been reported to be important for both crown gall development and A. tumefaciens mediated transformation efficiency to plants. ACC deaminase, an enzyme that can break down ACC, the direct precursor of ethylene biosynthesis in plants, is a mechanism used by some plant growth promoting bacteria (PGPB) to promote plant growth by reducing stress ethylene levels. In the second part of this thesis, the effect of ACC deaminase on A. tumefaciens induced crown gall development and on A. tumefaciens mediated transformation efficiency was studied. By either introduction of an ACC deaminase encoding gene into the virulent strain A. tumefaciens C58 or co-inoculation of A. tumefaciens C58 with an ACC deaminase containing PGPB P. putida UW4, using different plant systems including tomato plants and castor bean plants, it was found that the presence of an ACC deaminase significantly inhibited crown gall development. It was also found that introduction of an acdS gene into the disarmed A. tumefaciens strain GV3101::pMP90 reduced the ethylene levels evolved by plants during infection and cocultivation process and increased the transformation efficiency of commercialized canola cultivars. The A. tumefaciens D3 strain was reported to contain an ACC deaminase encoding gene (acdS). In this study it was determined that this strain is an avirulent strain and shows plant growth promoting activity. When co-inoculated with A. tumefaciens C58 on castor bean stems, both the wild type and the acdS knockout mutant showed biocontrol activity and were able to significantly inhibit crown gall formation, with the wild type strain showing slightly better tumor inhibition effects. The mutation of acdS and its regulatory gene lrpL in A. tumefaciens D3 was also found to affect QS signal production of this strain, which indicates a cross talk between the two sets of genes.

Quorum sensing

Metagenomics

LuxI/LuxR

AHL

ACC deaminase

Transformation efficiency

Crown gall

Canola

Agrobacterium tumefaciens

Biology

Two of the Mechanims Used by Bacteria to Modify the Environment: Quorum Sensing and ACC Deaminase

Hao, Youai

January 2009

Quorum sensing (QS) cell-cell communication systems are utilized by bacteria to coordinate their behaviour according to cell density. Several different types of QS signal molecules have been identified, among which acyl-homoserine lactones (AHLs) produced by Proteobacteria have been studied to the greatest extent. QS has been shown to be involved in many aspects of bacterial life, including virulence, bioluminescence, symbiosis, antibiotic production, swarming and swimming motility, biofilm formation, conjugation and growth inhibition. Although QS has been studied extensively in cultured microorganisms, little is known about the QS systems of uncultured microorganisms and the roles of these systems in microbial communities. To extend our knowledge of QS systems and to better understand the signalling that takes place in the natural environment, in the first part of this thesis, isolation and characterization of new QS systems from metagenomic libraries constructed using DNA from activated sludge and soil were described. Using an Agrobacterium biosensor strain, three cosmids (QS6-1, QS10-1 and QS10-2) that encode the production of QS signals were identified and DNA sequence analysis revealed that all three clones encode a novel luxI family AHL synthase and a luxR family transcriptional regulator. Thin layer chromatography revealed that these LuxI homolog proteins are able to synthesize multiple AHL signals. Tandem mass spectrometry analysis revealed that LuxIQS6-1 directs the synthesis of at least three AHLs, 3-O-C14:1 HSL, 3-O-C16:1 HSL and 3-O-C14 HSL; LuxIQS10-1 directs the synthesis of at least 3-O-C12 HSL and 3-O-C14 HSL; while LuxIQS10-2 directs the synthesis of at least C8 HSL and C10 HSL. Two possible new AHLs, C14:3 HSL and (?)-hydroxymethyl-3-O-C14 HSL, were also found to be synthesized by LuxIQS6-1. Agrobacterium tumefaciens is a plant pathogen that causes crown gall disease. Its ability to transfer and integrate foreign DNA into plant genome also makes it a useful tool for plant genetic engineering. Ethylene, the gaseous plant hormone, has been reported to be important for both crown gall development and A. tumefaciens mediated transformation efficiency to plants. ACC deaminase, an enzyme that can break down ACC, the direct precursor of ethylene biosynthesis in plants, is a mechanism used by some plant growth promoting bacteria (PGPB) to promote plant growth by reducing stress ethylene levels. In the second part of this thesis, the effect of ACC deaminase on A. tumefaciens induced crown gall development and on A. tumefaciens mediated transformation efficiency was studied. By either introduction of an ACC deaminase encoding gene into the virulent strain A. tumefaciens C58 or co-inoculation of A. tumefaciens C58 with an ACC deaminase containing PGPB P. putida UW4, using different plant systems including tomato plants and castor bean plants, it was found that the presence of an ACC deaminase significantly inhibited crown gall development. It was also found that introduction of an acdS gene into the disarmed A. tumefaciens strain GV3101::pMP90 reduced the ethylene levels evolved by plants during infection and cocultivation process and increased the transformation efficiency of commercialized canola cultivars. The A. tumefaciens D3 strain was reported to contain an ACC deaminase encoding gene (acdS). In this study it was determined that this strain is an avirulent strain and shows plant growth promoting activity. When co-inoculated with A. tumefaciens C58 on castor bean stems, both the wild type and the acdS knockout mutant showed biocontrol activity and were able to significantly inhibit crown gall formation, with the wild type strain showing slightly better tumor inhibition effects. The mutation of acdS and its regulatory gene lrpL in A. tumefaciens D3 was also found to affect QS signal production of this strain, which indicates a cross talk between the two sets of genes.

Quorum sensing

Metagenomics

LuxI/LuxR

AHL

ACC deaminase

Transformation efficiency

Crown gall

Canola

Agrobacterium tumefaciens

Biology

Studies on the agrocin 84 plasmid of `Agrobacterium radiobacter` / by Je-Seop Shim

Shim, Je-Seop

January 1987

Includes two journal articles with contributions by the author / Bibliography: leaves 145-154 / vii, 164 leaves : ill ; 30 cm. / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (Ph.D.)--University of Adelaide, Dept. of Plant Pathology, 1988

589.90873 19

Pathogenic bacteria.

Crown-gall disease.

Plasmids.

Insertion elements, DNA.

Rhizobiaceae Biological control.

Silencing the Agrobacterium tumefaciens oncogenes

Pitrak, Jennifer

06 June 2005

Crown gall disease is an agricultural problem caused by the soil-borne bacterium, Agrobacterium tumefaciens. A. tumefaciens oncogenes cause transformed plant cells to overproduce the hormones, auxin and cytokinin. High hormone levels cause unorganized plant cell growth resulting in a gall. Control of crown gall disease is difficult because after plant cell transformation has occurred, the bacterium is no longer required for the disease to progress. Apple trees engineered to express double-stranded RNA of two A. tumefaciens oncogenes, ipt and iaaM, silenced the expression of the wild-type oncogenes and prevented crown gall disease. Only the iaaM oncogene was targeted for posttranscriptional gene silencing (PTGS) as measured by biological assays and by quantitative reverse-transcription polymerase chain reaction (q-RTPCR) on transgenic tissue. However, if the translation initiation sequence of the iaaM construction was eliminated, gall formation was not prevented, indicating that translatable RNA initiates silencing whereas untranslatable RNA does not. Other data indicate that the Arabidopsis thaliana micro-RNA pathway gene is involved in A. tumefaciens-mediated tumorigenesis. A. thaliana plants with a mutation in HEN1, a gene required for micro-RNA maturation, demonstrated a tenfold reduction in tumorigenesis upon A. tumefaciens infection compared to wild-type. The same plant line showed no difference in T-DNA transfer and nuclear uptake. / Graduation date: 2006

Agrobacterium tumefaciens -- Genetics

Crown-gall disease -- Genetic aspects

Oncogenes

Gene silencing

Apples -- Genetic engineering

La galle du collet chez la vigne : de la diversité des pathogènes à l'étude des plasmides et du quorum sensing d'Allorhizobium vitis S4 / Crown gall disease in grapevine : from the diversity of pathogens to the study of plasmids and quorum sensing of Allorhizobium vitis S4

Duplay, Quentin

09 March 2018

La galle du collet, caractérisée par la formation d'une tumeur, représente la bactériose la plus répandue chez la vigne et entraine d'importantes pertes économiques à travers le monde. L'agent responsable de cette maladie est le plasmide Ti (pTi) qui confère à ces bactéries hôtes, telles que des Allorhizobium vitis, leur pouvoir pathogène. En plus du pTi, les A. vitis sont aussi les hôtes d'autres plasmides dont les fonctions et les modes de dissémination sont peu documentés. Afin d'étudier l'adaptation particulière des souches d'A. vitis à la vigne, nous nous sommes intéressés à la diversité de ces pathogènes ainsi qu'au rôle de ces plasmides et à la régulation de leur dissémination. Tout d'abord, nous avons analysé la diversité des isolats provenant de vignobles du Maroc atteints par la galle du collet. Nous avons pu mettre en évidence que l'ensemble des isolats pathogènes (e.g. porteur d'un pTi) forme 4 groupes génétiques se distinguant par le type d'opine produit. Nous nous sommes par la suite intéressés à la souche A. vitis S4 qui héberge 5 plasmides dont 3 possèdent un mécanisme de transfert pouvant être régulé par un système de communication bactérienne nommé quorum sensing (QS). Nous avons montré que le système QS du plasmide p130 (renommé pApi) contrôle non seulement le transfert conjugatif du pApi mais aussi d'autres fonctions plasmidiques non caractérisées. Ce système QS nécessite la synthèse d'une molécule signal de type N-acyl-homosérine lactone qui d'après nos travaux de caractérisation possède une structure atypique. De plus, des analyses génomiques couplées à des tests de résistance au cuivre nous ont permis d'identifier, sur le plasmide p79 d'A. vitis S4, un îlot de gènes potentiellement impliqués dans la résistance au cuivre de cette souche. Via des analyses de diversité ainsi que l'étude d'une souche modèle, nos travaux fournissent des connaissances sur l'adaptation d'Allorhizobium vitis à son unique plante hôte, la vigne / Crown gall disease, characterized by the formation of a tumor, represents the most widespread bacteriosis in the vineyard and causes significant economic losses throughout the world. The causing agent is the Ti plasmid (pTi) which confers pathogenicity to their bacterial hosts, such as Allorhizobium vitis. In addition to pTi, A. vitis harbours other plasmids whose functions and ways of dissemination are poorly documented. In order to study the peculiar adaptation of A. vitis strains to grapevine, we studied the diversity of these pathogens as well as the role of plasmids and the regulation of their dissemination.First, we analyzed the diversity of isolates from vineyards of Morocco affected by crown gall. We highlighted that all the pathogenic isolates (e.g. carrying a pTi) form 4 genetic groups that are distinguished by the type of opine produced and the ability to induce a hypersensitive response. We then focused on strain A. vitis S4, which contains 5 plasmids, including 3 possessing a transfer mechanism that can be regulated by a bacterial communication system called quorum sensing (QS). We demonstrated that the QS system of plasmid p130 (renamed pApi) controls not only the conjugative transfer of the pApi but also other uncharacterized plasmid-encoded functions. This QS system requires the synthesis of a N-acyl-homoserine lactone signal molecule with an atypical structure. In addition, genomic analyzes combined with copper resistance assays allowed us to identify, on plasmid p79 of A. vitis S4, a genomic island that is likely involved in copper resistance of this strain.Through analyzes of diversity and study of a model strain, our work provides insight into adaptation of Allorhizobium vitis to its unique host plant, grapevine

Allorhizobium vitis

Galle du collet

Quorum sensing

Plasmide

Résistance au cuivre

Allorhizobium vitis

Crown gall

Quorum sensing

Plasmid

Copper resistance

577