To test the hypothesis that auxin-binding protein 1 (ABP1) is a receptor controlling auxin-mediated plant cell expansion, ABP1 complementary DNAs were expressed in a controllable fashion in tobacco plants and constitutively in maize cell lines. Induction of Arabidopsis ABP1 expression in tobacco leaf strips resulted in an increased capacity for auxin-mediated cell expansion, whereas induction of ABP1 in intact plants resulted in leaves with a normal morphology, but larger cells. Similarly, constitutive expression of maize ABP1 in maize cell lines conferred on them the capacity to respond to auxin by increasing cell size. These results support a role of ABP1 as an auxin receptor controlling plant growth.
Host recognition and macromolecular transfer of virulence-mediating effectors represent critical steps in the successful transformation of plant cells by Agrobacterium tumefaciens. This review focuses on bacterial and plant-encoded components that interact to mediate these two processes. First, we examine the means by which Agrobacterium recognizes the host, via both diffusible plant-derived chemicals and cell-cell contact, with emphasis on the mechanisms by which multiple host signals are recognized and activate the virulence process. Second, we characterize the recognition and transfer of protein and protein-DNA complexes through the bacterial and plant cell membrane and wall barriers, emphasizing the central role of a type IV secretion system-the VirB complex-in this process.
Agrobacterium tumefaciens is capable of transferring and integrating an oncogenic T-DNA (transferred DNA) from its tumor-inducing (Ti) plasmid into dicotyledonous plants. This transfer requires that the virulence genes (vir regulon) be induced by plant signals such as acetosyringone in an acidic environment. Salicylic acid (SA) is a key signal molecule in regulating plant defense against pathogens. However, how SA influences Agrobacterium and its interactions with plants is poorly understood. Here we show that SA can directly shut down the expression of the vir regulon. SA specifically inhibited the expression of the Agrobacterium virA/G two-component regulatory system that tightly controls the expression of the vir regulon including the repABC operon on the Ti plasmid. We provide evidence suggesting that SA attenuates the function of the VirA kinase domain. Independent of its effect on the vir regulon, SA up-regulated the attKLM operon, which functions in degrading the bacterial quormone N-acylhomoserine lactone. Plants defective in SA accumulation were more susceptible to Agrobacterium infection, whereas plants overproducing SA were relatively recalcitrant to tumor formation. Our results illustrate that SA, besides its well known function in regulating plant defense, can also interfere directly with several aspects of the Agrobacterium infection process.two-component system ͉ tumorigenesis ͉ defense response ͉ rhizosphere ͉ plant-microbe interaction
The genetic manipulation of Agrobacterium tumefaciens is used to facilitate studies of bacterial gene functions or as a first step in introducing genetic material into transformable plant cells through the use of T-DNA binary vectors. Three methods are commonly used. Transformation with purified plasmid can be done with either electroporation or a simple freeze/thaw transformation method. Alternatively, a mobilizable plasmid can be placed into Agrobacterium using the triparental mating method. Here we present three detailed protocols for Agrobacterium strain construction using electroporation, the freeze/thaw method of transformation, and triparental mating.
The transfer of DNA from Agrobacterium tumefaciens into a plant cell requires the activities of several virulence (vir) genes that reside on the tumor-inducing (Ti) plasmid. The putative transferred intermediate is a single-stranded DNA (T strand), covalently attached to the VirD2 protein and coated with the single-stranded DNA-binding protein, VirE2. The movement of this intermediate out of Agrobacterium cells and into plant cells requires the expression of the virB operon, which encodes 11 proteins that localize to the membrane system. Our earlier studies showed that the IncQ broad-host-range plasmid RSF1010, which can be transferred from Agrobacterium cells to plant cells, inhibits the transfer of T-DNA from pTiA6 in a fashion that is reversed by overexpression of virB9, virB10, and virB11. Here, we examined the specificity of this inhibition by following the transfer of other T-DNA molecules. By using extracellular complementation assays, the effects of RSF1010 on movement of either VirE2 or an uncoated T strand from A. tumefaciens were also monitored. The RSF1010 derivative plasmid pJW323 drastically inhibited the capacity of strains to serve as VirE2 donors but only partially inhibited T-strand transfer from virE2 mutants. Further, we show that all the virB genes tested are required for the movement of VirE2 and the uncoated T strand as assayed by extracellular complementation. Our results are consistent with a model in which the RSF1010 plasmid, or intermediates from it, compete with the T strand and VirE2 for a common transport site.Agrobacterium tumefaciens has the capacity to transfer DNA from its Ti plasmid into plant cells, where the DNA is integrated and transcribed (for reviews, see references 5, 22, 58, and 63). In the case of wild-type tumor-inducing (Ti) plasmids, the transferred DNA (T-DNA) encodes two types of proteins: those that synthesize novel amino acid and sugar conjugates (opines) and those that affect the accumulation of plant hormones responsible for the tumorous growth of the transformed cells. The virulence (vir) genes of the Ti plasmid are necessary for the production and transfer of the T-DNA. vir gene expression is activated by plant wound-released phenolics and sugars, resulting in the accumulation of Vir proteins responsible for T-DNA processing and transfer (58). One of these proteins, VirD2, produces a single-stranded nick at the 25-bp direct repeat border sequences of the Ti plasmid. This is followed by release of a single strand (the T strand) due, apparently, to replacement strand synthesis (45,49,50). The T strand is covalently attached to VirD2 and can associate with the singlestranded DNA-binding protein VirE2 (9-11, 15, 39), resulting in the formation of the T (transfer) complex which is thought to be the transferred intermediate (22,48,61,63). In addition to the T-DNA on Ti plasmids, DNA on plasmids that can replicate in Agrobacterium cells and carry the border sequences of a Ti plasmid, often termed binary vectors, can be mobilized into plant cells by strains of Agro...
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