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Agrobacterium tumefaciens

February 16, 2024

Agrobacterium tumefaciens[3][2] is the causal agent of crown gall disease (the formation of tumours) in over 140 species of eudicots. It is a rod-shaped, Gram-negative soil bacterium.[4] Symptoms are caused by the insertion of a small segment of DNA (known as T-DNA, for 'transfer DNA', not to be confused with tRNA that transfers amino acids during protein synthesis), from a plasmid into the plant cell,[8] which is incorporated at a semi-random location into the plant genome. Plant genomes can be engineered by use of Agrobacterium for the delivery of sequences hosted in T-DNA binary vectors.

Agrobacterium tumefaciens
Agrobacterium tumefaciens attaching itself to a carrot cell
Scientific classification
Domain: Bacteria
Phylum: Pseudomonadota
Class: Alphaproteobacteria
Order: Hyphomicrobiales
Family: Rhizobiaceae
Genus: Agrobacterium
Species:
A. tumefaciens
Binomial name
Agrobacterium tumefaciens
(Smith and Townsend 1907) Conn 1942 (Approved Lists 1980)
Type strain
ATCC 4720[1][2][a]
Synonyms[6][7][2]

Homotypic synonyms

  • Bacterium tumefaciens Smith and Townsend 1907[4]
  • Pseudomonas tumefaciens (Smith and Townsend 1907) Duggar 1909
  • Phytomonas tumefaciens (Smith and Townsend 1907) Bergey et al. 1923
  • Polymonas tumefaciens (Smith and Townsend 1900) Lieske 1928

Heterotypic synonyms

  • Agrobacterium fabacearum Delamuta et al 2020 (by ANI)[3]

Agrobacterium radiobacter (Beijerinck and van Delden 1902) Conn 1942 (Approved Lists 1980) is NOT a synonym.[2] The two used to be synonimized[5] on the basis of an unjustified type strain change in the Approved Lists of 1980, now reverted.[2]

Agrobacterium tumefaciens is an Alphaproteobacterium of the family Rhizobiaceae, which includes the nitrogen-fixing legume symbionts. Unlike the nitrogen-fixing symbionts, tumor-producing Agrobacterium species are pathogenic and do not benefit the plant. The wide variety of plants affected by Agrobacterium makes it of great concern to the agriculture industry.[9]

Economically, A. tumefaciens is a serious pathogen of walnuts, grape vines, stone fruits, nut trees, sugar beets, horse radish, and rhubarb, and the persistent nature of the tumors or galls caused by the disease make it particularly harmful for perennial crops.[10]

Agrobacterium tumefaciens grows optimally at 28 °C (82 °F). The doubling time can range from 2.5–4h depending on the media, culture format, and level of aeration.[11] At temperatures above 30 °C (86 °F), A. tumefaciens begins to experience heat shock which is likely to result in errors in cell division.[11]

Conjugation edit

To be virulent, the bacterium contains a tumour-inducing plasmid (Ti plasmid or pTi) 200 kbp long, which contains the T-DNA and all the genes necessary to transfer it to the plant cell.[12] Many strains of A. tumefaciens do not contain a pTi.

Since the Ti plasmid is essential to cause disease, prepenetration events in the rhizosphere occur to promote bacterial conjugation - exchange of plasmids amongst bacteria. In the presence of opines, A. tumefaciens produces a diffusible conjugation signal called N-(3-oxo-octanoyl)-L-homoserine lactone (3OC8HSL) or the Agrobacterium autoinducer.[13] This activates the transcription factor TraR, positively regulating the transcription of genes required for conjugation.[14]

Infection methods edit

Agrobacterium tumefaciens infects the plant through its Ti plasmid. The Ti plasmid integrates a segment of its DNA, known as T-DNA, into the chromosomal DNA of its host plant cells. A. tumefaciens has flagella that allow it to swim through the soil towards photoassimilates that accumulate in the rhizosphere around roots. Some strains may chemotactically move towards chemical exudates from plants, such as acetosyringone and sugars, which indicate the presence of a wound in the plant through which the bacteria may enter. Phenolic compounds are recognised by the VirA protein, a transmembrane protein encoded in the virA gene on the Ti plasmid. Sugars are recognised by the chvE protein, a chromosomal gene-encoded protein located in the periplasmic space.[15]

At least 25 vir genes on the Ti plasmid are necessary for tumor induction.[16] In addition to their perception role, virA and chvE induce other vir genes. The VirA protein has autokinase activity: it phosphorylates itself on a histidine residue. Then the VirA protein phosphorylates the VirG protein on its aspartate residue. The virG protein is a cytoplasmic protein produced from the virG Ti plasmid gene. It is a transcription factor, inducing the transcription of the vir operons. The ChvE protein regulates the second mechanism of the vir genes' activation. It increases VirA protein sensitivity to phenolic compounds.[15]

Attachment is a two-step process. Following an initial weak and reversible attachment, the bacteria synthesize cellulose fibrils that anchor them to the wounded plant cell to which they were attracted. Four main genes are involved in this process: chvA, chvB, pscA, and att. The products of the first three genes apparently are involved in the actual synthesis of the cellulose fibrils. These fibrils also anchor the bacteria to each other, helping to form a microcolony.[citation needed]

VirC, the most important virulent protein, is a necessary step in the recombination of illegitimate recolonization. It selects the section of the DNA in the host plant that will be replaced and it cuts into this strand of DNA.[citation needed]

After production of cellulose fibrils, a calcium-dependent outer membrane protein called rhicadhesin is produced, which also aids in sticking the bacteria to the cell wall. Homologues of this protein can be found in other rhizobia. Currently, there are several reports on standardisation of protocol for the Agrobacterium-mediated transformation. The effect of different parameters such as infection time, acetosyringone, DTT, and cysteine have been studied in soybean (Glycine max).[17]

Possible plant compounds that initiate Agrobacterium to infect plant cells:[18]

Formation of the T-pilus edit

To transfer T-DNA into a plant cell, A. tumefaciens uses a type IV secretion mechanism, involving the production of a T-pilus. When acetosyringone and other substances are detected, a signal transduction event activates the expression of 11 genes within the VirB operon which are responsible for the formation of the T-pilus.

The pro-pilin is formed first. This is a polypeptide of 121 amino acids which requires processing by the removal of 47 residues to form a T-pilus subunit. The subunit was though to be circularized by the formation of a peptide bond between the two ends of the polypeptide. However, high-resolution structure of the T-pilus revealed no cyclization of the pilin, with the overall organization of the pilin subunits being highly similar to those of other conjugative pili, such as F-pilus.[19]

Products of the other VirB genes are used to transfer the subunits across the plasma membrane. Yeast two-hybrid studies provide evidence that VirB6, VirB7, VirB8, VirB9 and VirB10 may all encode components of the transporter. An ATPase for the active transport of the subunits would also be required.

Transfer of T-DNA into the plant cell edit

 
  1. Agrobacterium cell
  2. Agrobacterium chromosome
  3. Ti Plasmid (a. T-DNA, b. vir genes, c. replication origin, d. opines catabolism)
  4. Plant cell
  5. Plant mitochondria
  6. Plant chloroplast
  7. Plant nucleus
  1. VirA recognition
  2. VirA phosphorylates VirG
  3. VirG causes transcription of Vir genes
  4. Vir genes cut out T-DNA and form nucleoprotein complex ("T-complex")
  5. T-complex enters plant cytoplasm through T-pilus
  6. T-DNA enters into plant nucleus through nuclear pore
  7. T-DNA achieves integration

The T-DNA must be cut out of the circular plasmid. This is typically done by the Vir genes within the helper plasmid.[20] A VirD1/D2 complex nicks the DNA at the left and right border sequences. The VirD2 protein is covalently attached to the 5' end. VirD2 contains a motif that leads to the nucleoprotein complex being targeted to the type IV secretion system (T4SS). The structure of the T-pilus showed that the central channel of the pilus is too narrow to allow the transfer of the folded VirD2, suggesting that VirD2 must be partially unfolded during the conjugation process.[19]

In the cytoplasm of the recipient cell, the T-DNA complex becomes coated with VirE2 proteins, which are exported through the T4SS independently from the T-DNA complex. Nuclear localization signals, or NLSs, located on the VirE2 and VirD2, are recognised by the importin alpha protein, which then associates with importin beta and the nuclear pore complex to transfer the T-DNA into the nucleus. VIP1 also appears to be an important protein in the process, possibly acting as an adapter to bring the VirE2 to the importin. Once inside the nucleus, VIP2 may target the T-DNA to areas of chromatin that are being actively transcribed, so that the T-DNA can integrate into the host genome.

Genes in the T-DNA edit

Hormones edit

To cause gall formation, the T-DNA encodes genes for the production of auxin or indole-3-acetic acid via the IAM pathway. This biosynthetic pathway is not used in many plants for the production of auxin, so it means the plant has no molecular means of regulating it and auxin will be produced constitutively. Genes for the production of cytokinins are also expressed. This stimulates cell proliferation and gall formation.

Opines edit

The T-DNA contains genes for encoding enzymes that cause the plant to create specialized amino acid derivatives which the bacteria can metabolize, called opines.[21] Opines are a class of chemicals that serve as a source of nitrogen for A. tumefaciens, but not for most other organisms. The specific type of opine produced by A. tumefaciens C58 infected plants is nopaline.[22]

Two nopaline type Ti plasmids, pTi-SAKURA and pTiC58, were fully sequenced. "A. fabrum" C58, the first fully sequenced pathovar, was first isolated from a cherry tree crown gall. The genome was simultaneously sequenced by Goodner et al.[23] and Wood et al.[24] in 2001. The genome of A. tumefaciens C58 consists of a circular chromosome, two plasmids, and a linear chromosome. The presence of a covalently bonded circular chromosome is common to Bacteria, with few exceptions. However, the presence of both a single circular chromosome and single linear chromosome is unique to a group in this genus. The two plasmids are pTiC58, responsible for the processes involved in virulence, and pAtC58,[b] once dubbed the "cryptic" plasmid.[23][24]

The pAtC58 plasmid has been shown to be involved in the metabolism of opines and to conjugate with other bacteria in the absence of the pTiC58 plasmid.[25] If the Ti plasmid is removed, the tumor growth that is the means of classifying this species of bacteria does not occur.

Biotechnological uses edit

 
Transformed plant tissue cultures

The Asilomar Conference in 1975 established widespread agreement that recombinant techniques were insufficiently understood and needed to be tightly controlled.[26][27] The DNA transmission capabilities of Agrobacterium have been vastly explored in biotechnology as a means of inserting foreign genes into plants. Shortly after the Asilomar Conference, Marc Van Montagu and Jeff Schell discovered the gene transfer mechanism between Agrobacterium and plants, which resulted in the development of methods to alter the bacterium into an efficient delivery system for genetic engineering in plants.[28] The plasmid T-DNA that is transferred to the plant is an ideal vehicle for genetic engineering.[29] This is done by cloning a desired gene sequence into T-DNA binary vectors that will be used to deliver a sequence of interest into eukaryotic cells. This process has been performed using the firefly luciferase gene to produce glowing plants.[30] This luminescence has been a useful device in the study of plant chloroplast function and as a reporter gene.[30] It is also possible to transform Arabidopsis thaliana by dipping flowers into a broth of Agrobacterium: the seed produced will be transgenic. Under laboratory conditions, T-DNA has also been transferred to human cells, demonstrating the diversity of insertion application.[31]

The mechanism by which Agrobacterium inserts materials into the host cell is by a type IV secretion system which is very similar to mechanisms used by pathogens to insert materials (usually proteins) into human cells by type III secretion. It also employs a type of signaling conserved in many Gram-negative bacteria called quorum sensing.[citation needed] This makes Agrobacterium an important topic of medical research, as well.[citation needed]

Natural genetic transformation edit

Natural genetic transformation in bacteria is a sexual process involving the transfer of DNA from one cell to another through the intervening medium, and the integration of the donor sequence into the recipient genome by homologous recombination. A. tumefaciens can undergo natural transformation in soil without any specific physical or chemical treatment.[32]

Disease cycle edit

 
Disease cycle

Agrobacterium tumefaciens overwinters in infested soils. Agrobacterium species live predominantly saprophytic lifestyles, so its common even for plant-parasitic species of this genus to survive in the soil for lengthy periods of time, even without host plant presence.[33] When there is a host plant present, however, the bacteria enter the plant tissue via recent wounds or natural openings of roots or stems near the ground. These wounds may be caused by cultural practices, grafting, insects, etc. Once the bacteria have entered the plant, they occur intercellularly and stimulate surrounding tissue to proliferate due to cell transformation. Agrobacterium performs this control by inserting the plasmid T-DNA into the plant's genome. See above for more details about the process of plasmid DNA insertion into the host genome. Excess growth of the plant tissue leads to gall formation on the stem and roots. These tumors exert significant pressure on the surrounding plant tissue, which causes this tissue to become crushed and/or distorted. The crushed vessels lead to reduced water flow in the xylem. Young tumors are soft and therefore vulnerable to secondary invasion by insects and saprophytic microorganisms. This secondary invasion causes the breakdown of the peripheral cell layers as well as tumor discoloration due to decay. Breakdown of the soft tissue leads to release of the Agrobacterium tumefaciens into the soil allowing it to restart the disease process with a new host plant.[34]

Disease management edit

Crown gall disease caused by Agrobacterium tumefaciens can be controlled by using various methods. The best way to control this disease is to take preventative measures, such as sterilizing pruning tools so as to avoid infecting new plants. Performing mandatory inspections of nursery stock and rejecting infected plants as well as not planting susceptible plants in infected fields are also valuable practices. Avoiding wounding the crowns/roots of the plants during cultivation is important for preventing disease. In horticultural techniques in which multiple plants are joined to grow as one, such as budding and grafting[35] these techniques lead to plant wounds. Wounds are the primary location of bacterial entry into the host plant. Therefore, it is advisable to perform these techniques during times of the year when Agrobacteria are not active. Control of root-chewing insects is also helpful to reduce levels of infection, since these insects cause wounds (aka bacterial entryways) in the plant roots.[34] It is recommended that infected plant material be burned rather than placed in a compost pile due to the bacteria's ability to live in the soil for many years.[36]

Biological control methods are also utilized in managing this disease. During the 1970s and 1980s, a common practice for treating germinated seeds, seedlings, and rootstock was to soak them in a suspension of K84. K84 is composed of A. radiobacter, which is a species related to A. tumefaciens but is not pathogenic. K84 produces a bacteriocin (agrocin 84) which is an antibiotic specific against related bacteria, including A. tumefaciens. This method, which was successful at controlling the disease on a commercial scale, had the risk of K84 transferring its resistance gene to the pathogenic Agrobacteria. Thus, in the 1990s, the use of a genetically engineering strain of K84, known as K-1026, was created. This strain is just as successful in controlling crown gall as K84 without the caveat of resistance gene transfer.[37]

Environment edit

 
Crown gall of sunflower caused by A. tumefaciens

Host, environment, and pathogen are extremely important concepts in regards to plant pathology. Agrobacteria have the widest host range of any plant pathogen,[38] so the main factor to take into consideration in the case of crown gall is environment. There are various conditions and factors that make for a conducive environment for A. tumefaciens when infecting its various hosts. The bacterium can't penetrate the host plant without an entry point such as a wound. Factors leading to wounds in plants include cultural practices, grafting, freezing injury, growth cracks, soil insects, and other animals in the environment causing damage to the plant. Consequently, in exceptionally harsh winters, it is common to have an increased incidence of crown gall due to the weather-related damage.[39] Along with this, there are methods of mediating infection of the host plant. For example, nematodes can act as a vector to introduce Agrobacterium into plant roots. More specifically, the root parasitic nematodes damage the plant cell, creating a wound for the bacteria to enter through.[40] Finally, temperature is a factor when considering A. tumefaciens infection. The optimal temperature for crown gall formation due to this bacterium is 22 °C (72 °F) because of the thermosensitivity of T-DNA transfer. Tumor formation is significantly reduced at higher temperature conditions.[41]

See also edit

References edit

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  2. ^ "At plasmid" or "pAt" when talking about related plasmids
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Further reading edit

  • Dickinson M (2003). Molecular Plant Pathology. BIOS Scientific Publishers.
  • Lai EM, Kado CI (August 2000). "The T-pilus of Agrobacterium tumefaciens". Trends in Microbiology. 8 (8): 361–9. doi:10.1016/s0966-842x(00)01802-3. PMID 10920395.
  • Ward DV, Zupan JR, Zambryski PC (January 2002). "Agrobacterium VirE2 gets the VIP1 treatment in plant nuclear import". Trends in Plant Science. 7 (1): 1–3. doi:10.1016/s1360-1385(01)02175-6. PMID 11804814.
  • Webster J, Thomson J (1988). "Genetic Analysis of an Agrobacterium tumefaciens strain producing an agrocin active against biotype 3 Pathogen". Molecular and General Genetics. 214 (1): 142–147. doi:10.1007/BF00340192. S2CID 180063.

External links edit

  •   Media related to Agrobacterium tumefaciens at Wikimedia Commons
  • "Agrobacterium fabrum" C58 Genome Page — as sequenced by Cereon Genomics/University of Richmond

February 16, 2024
agrobacterium, tumefaciens, causal, agent, crown, gall, disease, formation, tumours, over, species, eudicots, shaped, gram, negative, soil, bacterium, symptoms, caused, insertion, small, segment, known, transfer, confused, with, trna, that, transfers, amino, a. Agrobacterium tumefaciens 3 2 is the causal agent of crown gall disease the formation of tumours in over 140 species of eudicots It is a rod shaped Gram negative soil bacterium 4 Symptoms are caused by the insertion of a small segment of DNA known as T DNA for transfer DNA not to be confused with tRNA that transfers amino acids during protein synthesis from a plasmid into the plant cell 8 which is incorporated at a semi random location into the plant genome Plant genomes can be engineered by use of Agrobacterium for the delivery of sequences hosted in T DNA binary vectors Agrobacterium tumefaciensAgrobacterium tumefaciens attaching itself to a carrot cellScientific classificationDomain BacteriaPhylum PseudomonadotaClass AlphaproteobacteriaOrder HyphomicrobialesFamily RhizobiaceaeGenus AgrobacteriumSpecies A tumefaciensBinomial nameAgrobacterium tumefaciens Smith and Townsend 1907 Conn 1942 Approved Lists 1980 Type strainATCC 4720 1 2 a Synonyms 6 7 2 Homotypic synonyms Bacterium tumefaciens Smith and Townsend 1907 4 Pseudomonas tumefaciens Smith and Townsend 1907 Duggar 1909 Phytomonas tumefaciens Smith and Townsend 1907 Bergey et al 1923 Polymonas tumefaciens Smith and Townsend 1900 Lieske 1928Heterotypic synonyms Agrobacterium fabacearum Delamuta et al 2020 by ANI 3 Agrobacterium radiobacter Beijerinck and van Delden 1902 Conn 1942 Approved Lists 1980 is NOT a synonym 2 The two used to be synonimized 5 on the basis of an unjustified type strain change in the Approved Lists of 1980 now reverted 2 Agrobacterium tumefaciens is an Alphaproteobacterium of the family Rhizobiaceae which includes the nitrogen fixing legume symbionts Unlike the nitrogen fixing symbionts tumor producing Agrobacterium species are pathogenic and do not benefit the plant The wide variety of plants affected by Agrobacterium makes it of great concern to the agriculture industry 9 Economically A tumefaciens is a serious pathogen of walnuts grape vines stone fruits nut trees sugar beets horse radish and rhubarb and the persistent nature of the tumors or galls caused by the disease make it particularly harmful for perennial crops 10 Agrobacterium tumefaciens grows optimally at 28 C 82 F The doubling time can range from 2 5 4h depending on the media culture format and level of aeration 11 At temperatures above 30 C 86 F A tumefaciens begins to experience heat shock which is likely to result in errors in cell division 11 Contents 1 Conjugation 2 Infection methods 2 1 Formation of the T pilus 2 2 Transfer of T DNA into the plant cell 3 Genes in the T DNA 3 1 Hormones 3 2 Opines 4 Biotechnological uses 5 Natural genetic transformation 6 Disease cycle 7 Disease management 8 Environment 9 See also 10 References 11 Further reading 12 External linksConjugation editTo be virulent the bacterium contains a tumour inducing plasmid Ti plasmid or pTi 200 kbp long which contains the T DNA and all the genes necessary to transfer it to the plant cell 12 Many strains of A tumefaciens do not contain a pTi Since the Ti plasmid is essential to cause disease prepenetration events in the rhizosphere occur to promote bacterial conjugation exchange of plasmids amongst bacteria In the presence of opines A tumefaciens produces a diffusible conjugation signal called N 3 oxo octanoyl L homoserine lactone 3OC8HSL or the Agrobacterium autoinducer 13 This activates the transcription factor TraR positively regulating the transcription of genes required for conjugation 14 Infection methods editAgrobacterium tumefaciens infects the plant through its Ti plasmid The Ti plasmid integrates a segment of its DNA known as T DNA into the chromosomal DNA of its host plant cells A tumefaciens has flagella that allow it to swim through the soil towards photoassimilates that accumulate in the rhizosphere around roots Some strains may chemotactically move towards chemical exudates from plants such as acetosyringone and sugars which indicate the presence of a wound in the plant through which the bacteria may enter Phenolic compounds are recognised by the VirA protein a transmembrane protein encoded in the virA gene on the Ti plasmid Sugars are recognised by the chvE protein a chromosomal gene encoded protein located in the periplasmic space 15 At least 25 vir genes on the Ti plasmid are necessary for tumor induction 16 In addition to their perception role virA and chvE induce other vir genes The VirA protein has autokinase activity it phosphorylates itself on a histidine residue Then the VirA protein phosphorylates the VirG protein on its aspartate residue The virG protein is a cytoplasmic protein produced from the virG Ti plasmid gene It is a transcription factor inducing the transcription of the vir operons The ChvE protein regulates the second mechanism of the vir genes activation It increases VirA protein sensitivity to phenolic compounds 15 Attachment is a two step process Following an initial weak and reversible attachment the bacteria synthesize cellulose fibrils that anchor them to the wounded plant cell to which they were attracted Four main genes are involved in this process chvA chvB pscA and att The products of the first three genes apparently are involved in the actual synthesis of the cellulose fibrils These fibrils also anchor the bacteria to each other helping to form a microcolony citation needed VirC the most important virulent protein is a necessary step in the recombination of illegitimate recolonization It selects the section of the DNA in the host plant that will be replaced and it cuts into this strand of DNA citation needed After production of cellulose fibrils a calcium dependent outer membrane protein called rhicadhesin is produced which also aids in sticking the bacteria to the cell wall Homologues of this protein can be found in other rhizobia Currently there are several reports on standardisation of protocol for the Agrobacterium mediated transformation The effect of different parameters such as infection time acetosyringone DTT and cysteine have been studied in soybean Glycine max 17 Possible plant compounds that initiate Agrobacterium to infect plant cells 18 Acetosyringone and other phenolic compounds alpha Hydroxyacetosyringone Catechol Ferulic acid Gallic acid p Hydroxybenzoic acid Protocatechuic acid Pyrogallic acid Resorcylic acid Sinapinic acid Syringic acid VanillinFormation of the T pilus edit To transfer T DNA into a plant cell A tumefaciens uses a type IV secretion mechanism involving the production of a T pilus When acetosyringone and other substances are detected a signal transduction event activates the expression of 11 genes within the VirB operon which are responsible for the formation of the T pilus The pro pilin is formed first This is a polypeptide of 121 amino acids which requires processing by the removal of 47 residues to form a T pilus subunit The subunit was though to be circularized by the formation of a peptide bond between the two ends of the polypeptide However high resolution structure of the T pilus revealed no cyclization of the pilin with the overall organization of the pilin subunits being highly similar to those of other conjugative pili such as F pilus 19 Products of the other VirB genes are used to transfer the subunits across the plasma membrane Yeast two hybrid studies provide evidence that VirB6 VirB7 VirB8 VirB9 and VirB10 may all encode components of the transporter An ATPase for the active transport of the subunits would also be required Transfer of T DNA into the plant cell edit nbsp Agrobacterium cellAgrobacterium chromosomeTi Plasmid a T DNA b vir genes c replication origin d opines catabolism Plant cellPlant mitochondriaPlant chloroplastPlant nucleus VirA recognitionVirA phosphorylates VirGVirG causes transcription of Vir genesVir genes cut out T DNA and form nucleoprotein complex T complex T complex enters plant cytoplasm through T pilusT DNA enters into plant nucleus through nuclear poreT DNA achieves integrationThe T DNA must be cut out of the circular plasmid This is typically done by the Vir genes within the helper plasmid 20 A VirD1 D2 complex nicks the DNA at the left and right border sequences The VirD2 protein is covalently attached to the 5 end VirD2 contains a motif that leads to the nucleoprotein complex being targeted to the type IV secretion system T4SS The structure of the T pilus showed that the central channel of the pilus is too narrow to allow the transfer of the folded VirD2 suggesting that VirD2 must be partially unfolded during the conjugation process 19 In the cytoplasm of the recipient cell the T DNA complex becomes coated with VirE2 proteins which are exported through the T4SS independently from the T DNA complex Nuclear localization signals or NLSs located on the VirE2 and VirD2 are recognised by the importin alpha protein which then associates with importin beta and the nuclear pore complex to transfer the T DNA into the nucleus VIP1 also appears to be an important protein in the process possibly acting as an adapter to bring the VirE2 to the importin Once inside the nucleus VIP2 may target the T DNA to areas of chromatin that are being actively transcribed so that the T DNA can integrate into the host genome Genes in the T DNA editHormones edit To cause gall formation the T DNA encodes genes for the production of auxin or indole 3 acetic acid via the IAM pathway This biosynthetic pathway is not used in many plants for the production of auxin so it means the plant has no molecular means of regulating it and auxin will be produced constitutively Genes for the production of cytokinins are also expressed This stimulates cell proliferation and gall formation Opines edit The T DNA contains genes for encoding enzymes that cause the plant to create specialized amino acid derivatives which the bacteria can metabolize called opines 21 Opines are a class of chemicals that serve as a source of nitrogen for A tumefaciens but not for most other organisms The specific type of opine produced by A tumefaciens C58 infected plants is nopaline 22 Two nopaline type Ti plasmids pTi SAKURA and pTiC58 were fully sequenced A fabrum C58 the first fully sequenced pathovar was first isolated from a cherry tree crown gall The genome was simultaneously sequenced by Goodner et al 23 and Wood et al 24 in 2001 The genome of A tumefaciens C58 consists of a circular chromosome two plasmids and a linear chromosome The presence of a covalently bonded circular chromosome is common to Bacteria with few exceptions However the presence of both a single circular chromosome and single linear chromosome is unique to a group in this genus The two plasmids are pTiC58 responsible for the processes involved in virulence and pAtC58 b once dubbed the cryptic plasmid 23 24 The pAtC58 plasmid has been shown to be involved in the metabolism of opines and to conjugate with other bacteria in the absence of the pTiC58 plasmid 25 If the Ti plasmid is removed the tumor growth that is the means of classifying this species of bacteria does not occur Biotechnological uses edit nbsp Transformed plant tissue culturesThe Asilomar Conference in 1975 established widespread agreement that recombinant techniques were insufficiently understood and needed to be tightly controlled 26 27 The DNA transmission capabilities of Agrobacterium have been vastly explored in biotechnology as a means of inserting foreign genes into plants Shortly after the Asilomar Conference Marc Van Montagu and Jeff Schell discovered the gene transfer mechanism between Agrobacterium and plants which resulted in the development of methods to alter the bacterium into an efficient delivery system for genetic engineering in plants 28 The plasmid T DNA that is transferred to the plant is an ideal vehicle for genetic engineering 29 This is done by cloning a desired gene sequence into T DNA binary vectors that will be used to deliver a sequence of interest into eukaryotic cells This process has been performed using the firefly luciferase gene to produce glowing plants 30 This luminescence has been a useful device in the study of plant chloroplast function and as a reporter gene 30 It is also possible to transform Arabidopsis thaliana by dipping flowers into a broth of Agrobacterium the seed produced will be transgenic Under laboratory conditions T DNA has also been transferred to human cells demonstrating the diversity of insertion application 31 The mechanism by which Agrobacterium inserts materials into the host cell is by a type IV secretion system which is very similar to mechanisms used by pathogens to insert materials usually proteins into human cells by type III secretion It also employs a type of signaling conserved in many Gram negative bacteria called quorum sensing citation needed This makes Agrobacterium an important topic of medical research as well citation needed Natural genetic transformation editNatural genetic transformation in bacteria is a sexual process involving the transfer of DNA from one cell to another through the intervening medium and the integration of the donor sequence into the recipient genome by homologous recombination A tumefaciens can undergo natural transformation in soil without any specific physical or chemical treatment 32 Disease cycle edit nbsp Disease cycleAgrobacterium tumefaciens overwinters in infested soils Agrobacterium species live predominantly saprophytic lifestyles so its common even for plant parasitic species of this genus to survive in the soil for lengthy periods of time even without host plant presence 33 When there is a host plant present however the bacteria enter the plant tissue via recent wounds or natural openings of roots or stems near the ground These wounds may be caused by cultural practices grafting insects etc Once the bacteria have entered the plant they occur intercellularly and stimulate surrounding tissue to proliferate due to cell transformation Agrobacterium performs this control by inserting the plasmid T DNA into the plant s genome See above for more details about the process of plasmid DNA insertion into the host genome Excess growth of the plant tissue leads to gall formation on the stem and roots These tumors exert significant pressure on the surrounding plant tissue which causes this tissue to become crushed and or distorted The crushed vessels lead to reduced water flow in the xylem Young tumors are soft and therefore vulnerable to secondary invasion by insects and saprophytic microorganisms This secondary invasion causes the breakdown of the peripheral cell layers as well as tumor discoloration due to decay Breakdown of the soft tissue leads to release of the Agrobacterium tumefaciens into the soil allowing it to restart the disease process with a new host plant 34 Disease management editCrown gall disease caused by Agrobacterium tumefaciens can be controlled by using various methods The best way to control this disease is to take preventative measures such as sterilizing pruning tools so as to avoid infecting new plants Performing mandatory inspections of nursery stock and rejecting infected plants as well as not planting susceptible plants in infected fields are also valuable practices Avoiding wounding the crowns roots of the plants during cultivation is important for preventing disease In horticultural techniques in which multiple plants are joined to grow as one such as budding and grafting 35 these techniques lead to plant wounds Wounds are the primary location of bacterial entry into the host plant Therefore it is advisable to perform these techniques during times of the year when Agrobacteria are not active Control of root chewing insects is also helpful to reduce levels of infection since these insects cause wounds aka bacterial entryways in the plant roots 34 It is recommended that infected plant material be burned rather than placed in a compost pile due to the bacteria s ability to live in the soil for many years 36 Biological control methods are also utilized in managing this disease During the 1970s and 1980s a common practice for treating germinated seeds seedlings and rootstock was to soak them in a suspension of K84 K84 is composed of A radiobacter which is a species related to A tumefaciens but is not pathogenic K84 produces a bacteriocin agrocin 84 which is an antibiotic specific against related bacteria including A tumefaciens This method which was successful at controlling the disease on a commercial scale had the risk of K84 transferring its resistance gene to the pathogenic Agrobacteria Thus in the 1990s the use of a genetically engineering strain of K84 known as K 1026 was created This strain is just as successful in controlling crown gall as K84 without the caveat of resistance gene transfer 37 Environment edit nbsp Crown gall of sunflower caused by A tumefaciensHost environment and pathogen are extremely important concepts in regards to plant pathology Agrobacteria have the widest host range of any plant pathogen 38 so the main factor to take into consideration in the case of crown gall is environment There are various conditions and factors that make for a conducive environment for A tumefaciens when infecting its various hosts The bacterium can t penetrate the host plant without an entry point such as a wound Factors leading to wounds in plants include cultural practices grafting freezing injury growth cracks soil insects and other animals in the environment causing damage to the plant Consequently in exceptionally harsh winters it is common to have an increased incidence of crown gall due to the weather related damage 39 Along with this there are methods of mediating infection of the host plant For example nematodes can act as a vector to introduce Agrobacterium into plant roots More specifically the root parasitic nematodes damage the plant cell creating a wound for the bacteria to enter through 40 Finally temperature is a factor when considering A tumefaciens infection The optimal temperature for crown gall formation due to this bacterium is 22 C 72 F because of the thermosensitivity of T DNA transfer Tumor formation is significantly reduced at higher temperature conditions 41 See also editsuhBReferences edit also known as CCM 1000 CCUG 3555 CFBP 2412 CIP 104335 DSM 30150 ICMP 5793 BCCM LMG 182 NCIMB 8150 NCPPB 2992 IAM 14141 IAM 1524 JCM 21034 personal A1 3 At plasmid or pAt when talking about related plasmids Velazquez E Flores Felix JD Sanchez Juanes F Igual JM Peix A 2020 Strain ATCC 4720T is the authentic type strain of Agrobacterium tumefaciens which is not a later heterotypic synonym of Agrobacterium radiobacter Int J Syst Evol Microbiol 70 9 5172 5176 doi 10 1099 ijsem 0 004443 PMID 32915125 a b c d e Arahal DR Bull CT Busse H Christensen H Chuvochina M Dedysh SN Fournier P Konstantinidis KT Parker CT Rossello Mora R Ventosa A Goker M 27 April 2023 Judicial Opinions 123 127 International Journal of Systematic and Evolutionary Microbiology 72 12 doi 10 1099 ijsem 0 005708 hdl 10261 295959 PMID 36748499 N B Judicial Opinion 127 assigns the strain ATCC 4720 as the type strain of Agrobacterium tumefaciens a b c Taxonomy browser Agrobacterium tumefaciens National Center for Biotechnology Information Retrieved 7 January 2024 a b Smith EF Townsend CO April 1907 A Plant Tumor of Bacterial Origin Science 25 643 671 3 Bibcode 1907Sci 25 671S doi 10 1126 science 25 643 671 PMID 17746161 Tindall BJ et al Judicial Commission 2014 Judicial Opinion No 94 Agrobacterium radiobacter Beijerinck and van Delden 1902 Conn 1942 has priority over Agrobacterium tumefaciens Smith and Townsend 1907 Conn 1942 when the two are treated as members of the same species based on the principle of priority and Rule 23a Note 1 as applied to the corresponding specific epithets Int J Syst Evol Microbiol 64 Pt 10 3590 3592 doi 10 1099 ijs 0 069203 0 PMID 25288664 Buchanan RE 1965 Proposal for rejection of the generic name Polymonas Lieske 1928 International Bulletin of Bacteriological Nomenclature and Taxonomy 15 1 43 44 doi 10 1099 00207713 15 1 43 Sawada H Ieki H Oyaizu H Matsumoto S 1993 Proposal for rejection of Agrobacterium tumefaciens and revised descriptions for the genus Agrobacterium and for Agrobacterium radiobacter and Agrobacterium rhizogenes Int J Syst Bacteriol 43 4 694 702 doi 10 1099 00207713 43 4 694 PMID 8240952 Chilton M Drummond MH Merlo DJ Sciaky D Montoya AL Gordon MP Nester EW June 1977 Stable incorporation of plasmid DNA into higher plant cells the molecular basis of crown gall tumorigenesis Cell 11 2 263 271 doi 10 1016 0092 8674 77 90043 5 ISSN 0092 8674 PMID 890735 S2CID 7533482 Moore LW Chilton WS Canfield ML January 1997 Diversity of opines and opine catabolizing bacteria isolated from naturally occurring crown gall tumors Applied and Environmental Microbiology 63 1 201 7 Bibcode 1997ApEnM 63 201M doi 10 1128 AEM 63 1 201 207 1997 PMC 1389099 PMID 16535484 Crown Galls Missouri Botanical Garden Retrieved December 2 2019 a b Morton ER Fuqua C February 2012 Laboratory maintenance of Agrobacterium Current Protocols in Microbiology Chapter 1 Unit3D 1 doi 10 1002 9780471729259 mc03d01s24 ISBN 978 0471729259 PMC 3350319 PMID 22307549 Gordon JE Christie PJ December 2014 The Agrobacterium Ti Plasmids Microbiology Spectrum 2 6 doi 10 1128 microbiolspec PLAS 0010 2013 PMC 4292801 PMID 25593788 Oger P Farrand SK 2002 Two Opines Control Conjugal Transfer of an Agrobacterium Plasmid by Regulating Expression of Separate Copies of the Quorum Sensing Activator Gene traR Journal of Bacteriology 184 4 1121 1131 doi 10 1128 jb 184 4 1121 1131 2002 ISSN 0021 9193 PMC 134798 PMID 11807073 Zhang H Wang L Zhang L 2002 Genetic control of quorum sensing signal turnover in Agrobacterium tumefaciens Proceedings of the National Academy of Sciences 99 7 4638 4643 doi 10 1073 pnas 022056699 ISSN 0027 8424 PMC 123700 PMID 11930013 a b Gelvin SB March 2003 Agrobacterium mediated plant transformation the biology behind the gene jockeying tool Microbiology and Molecular Biology Reviews 67 1 16 37 table of contents doi 10 1128 mmbr 67 1 16 37 2003 PMC 150518 PMID 12626681 Winans SC 1992 Two way chemical signaling in Agrobacterium plant interactions Microbiological Reviews 56 1 12 31 doi 10 1128 mr 56 1 12 31 1992 ISSN 0146 0749 PMC 372852 PMID 1579105 Barate PL Kumar RR Waghmare SG Pawar KR Tabe RH 2018 Effect of different parameters on Agrobacterium mediated transformation in Glycine max International Journal of Advanced Biological Research 8 1 99 105 US patent 6483013 Method for agrobacterium mediated transformation of cotton published 2002 11 19 assigned to Bayer BioScience N V BE a b Beltran LC Cvirkaite Krupovic V Miller J Wang F Kreutzberger MA Patkowski JB Costa TR Schouten S Levental I Conticello VP Egelman EH Krupovic M 2023 02 07 Archaeal DNA import apparatus is homologous to bacterial conjugation machinery Nature Communications 14 1 666 Bibcode 2023NatCo 14 666B doi 10 1038 s41467 023 36349 8 ISSN 2041 1723 PMC 9905601 PMID 36750723 Kroemer T A Guide to T DNA Binary Vectors in Plant Transformation GoldBio Retrieved January 9 2024 Zupan J Muth TR Draper O Zambryski P July 2000 The transfer of DNA from agrobacterium tumefaciens into plants a feast of fundamental insights The Plant Journal 23 1 11 28 doi 10 1046 j 1365 313x 2000 00808 x PMID 10929098 Escobar MA Civerolo EL Polito VS Pinney KA Dandekar AM January 2003 Characterization of oncogene silenced transgenic plants implications for Agrobacterium biology and post transcriptional gene silencing Molecular Plant Pathology 4 1 57 65 doi 10 1046 j 1364 3703 2003 00148 x ISSN 1464 6722 a b Goodner B Hinkle G Gattung S Miller N Blanchard M Qurollo B et al December 2001 Genome sequence of the plant pathogen and biotechnology agent Agrobacterium tumefaciens C58 Science 294 5550 2323 2328 Bibcode 2001Sci 294 2323G doi 10 1126 science 1066803 ISSN 0036 8075 PMID 11743194 S2CID 86255214 a b Wood DW Setubal JC Kaul R Monks DE Kitajima JP Okura VK et al December 2001 The genome of the natural genetic engineer Agrobacterium tumefaciens C58 Science 294 5550 2317 23 Bibcode 2001Sci 294 2317W CiteSeerX 10 1 1 7 9501 doi 10 1126 science 1066804 ISSN 0036 8075 PMID 11743193 S2CID 2761564 Vaudequin Dransart V Petit A Chilton WS Dessaux Y 1998 The cryptic plasmid of Agrobacterium tumefaciens cointegrates with the Ti plasmid and cooperates for opine degradation Molecular Plant Microbe Interactions 11 7 583 591 doi 10 1094 mpmi 1998 11 7 583 Berg P Baltimore D Brenner S Roblin RO Singer MF 1975 06 06 Asilomar Conference on Recombinant DNA Molecules Science 188 4192 991 994 doi 10 1126 science 1056638 ISSN 0036 8075 National Research Council Board on Agriculture and Natural Resources Committee on Genetically Modified Pest Protected Plants 2000 Genetically Modified Pest Protected Plants Science and Regulation Washington D C National Academies Press pp xxiii 263 doi 10 17226 9795 ISBN 978 0 309 06930 4 OCLC 894124744 Schell J Van Montagu M 1977 The Ti Plasmid of Agrobacterium Tumefaciens A Natural Vector for the Introduction of NIF Genes in Plants In Hollaender A Burris RH Day PR Hardy RW eds Genetic Engineering for Nitrogen Fixation Basic Life Sciences Vol 9 pp 159 79 doi 10 1007 978 1 4684 0880 5 12 ISBN 978 1 4684 0882 9 PMID 336023 Zambryski P Joos H Genetello C Leemans J Montagu MV Schell J 1983 Ti plasmid vector for the introduction of DNA into plant cells without alteration of their normal regeneration capacity The EMBO Journal 2 12 2143 50 doi 10 1002 j 1460 2075 1983 tb01715 x PMC 555426 PMID 16453482 a b Root M 1988 Glow in the dark biotechnology BioScience 38 11 745 747 doi 10 2307 1310781 JSTOR 1310781 Kunik T Tzfira T Kapulnik Y Gafni Y Dingwall C Citovsky V February 2001 Genetic transformation of HeLa cells by Agrobacterium Proceedings of the National Academy of Sciences of the United States of America 98 4 1871 6 Bibcode 2001PNAS 98 1871K doi 10 1073 pnas 041327598 PMC 29349 PMID 11172043 Demaneche S Kay E Gourbiere F Simonet P June 2001 Natural transformation of Pseudomonas fluorescens and Agrobacterium tumefaciens in soil Applied and Environmental Microbiology 67 6 2617 21 Bibcode 2001ApEnM 67 2617D doi 10 1128 AEM 67 6 2617 2621 2001 PMC 92915 PMID 11375171 Schroth MN Weinhold AR Mccain AH March 1971 Biology and Control of Agrobacterium tumefaciens Hilgardia 40 15 537 552 doi 10 3733 hilg v40n15p537 a b Agrios GN 2005 Plant pathology 5th ed Amsterdam Elsevier Academic Press doi 10 1016 C2009 0 02037 6 ISBN 9780120445653 OCLC 55488155 Bilderback T Bir RE Ranney TG June 30 2014 Grafting and Budding Nursery Crop Plants NC State Extension Publications Retrieved December 12 2017 Koetter R Grabowski M Crown gall University of Minnesota Extension Archived from the original on October 16 2017 Retrieved October 15 2017 Ryder MH Jones DA October 1 1991 Biological Control of Crown Gall Using Using Agrobacterium Strains K84 and K1026 Functional Plant Biology 18 5 571 579 doi 10 1071 pp9910571 Ellis MA Apr 15 2016 Bacterial Crown Gall of Fruit Crops Ohioline Ohio State University Extension Retrieved October 20 2017 Crown Gall A Growing Concern in Vineyards Penn State Extension October 19 2017 Archived from the original on October 20 2017 Retrieved October 20 2017 Karimi M Van Montagu M Gheysen G November 2000 Nematodes as vectors to introduce Agrobacterium into plant roots Molecular Plant Pathology 1 6 383 7 doi 10 1046 j 1364 3703 2000 00043 x PMID 20572986 S2CID 35932276 Dillen W De Clereq J Kapila J Van Montagu ZM Angenon G 1997 12 01 The effect of temperature on Agrobacterium tumefaciens mediated gene transfer to plants The Plant Journal 12 6 1459 1463 doi 10 1046 j 1365 313x 1997 12061459 x Further reading editDickinson M 2003 Molecular Plant Pathology BIOS Scientific Publishers Lai EM Kado CI August 2000 The T pilus of Agrobacterium tumefaciens Trends in Microbiology 8 8 361 9 doi 10 1016 s0966 842x 00 01802 3 PMID 10920395 Ward DV Zupan JR Zambryski PC January 2002 Agrobacterium VirE2 gets the VIP1 treatment in plant nuclear import Trends in Plant Science 7 1 1 3 doi 10 1016 s1360 1385 01 02175 6 PMID 11804814 Webster J Thomson J 1988 Genetic Analysis of an Agrobacterium tumefaciens strain producing an agrocin active against biotype 3 Pathogen Molecular and General Genetics 214 1 142 147 doi 10 1007 BF00340192 S2CID 180063 External links edit nbsp Media related to Agrobacterium tumefaciens at Wikimedia Commons Agrobacterium fabrum C58 Genome Page as sequenced by Cereon Genomics University of Richmond Retrieved from https en wikipedia org w index php title Agrobacterium tumefaciens amp oldid 1196463084, wikipedia, wiki, book, books, library,

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