BackgroundSolanum lycopersicum, an economically important crop grown worldwide, has been used as a model for the study of arbuscular mycorrhizal (AM) symbiosis in non-legume plants for several years and several cDNA array hybridization studies have revealed specific transcriptomic profiles of mycorrhizal tomato roots. However, a method to easily screen candidate genes which could play an important role during tomato mycorrhization is required.ResultsWe have developed an optimized procedure for composite tomato plant obtaining achieved through Agrobacterium rhizogenes-mediated transformation. This protocol involves the unusual in vitro culture of composite plants between two filter papers placed on the culture media. In addition, we show that DsRed is an appropriate molecular marker for the precise selection of cotransformed tomato hairy roots. S. lycopersicum composite plant hairy roots appear to be colonized by the AM fungus Rhizophagus irregularis in a manner similar to that of normal roots, and a modified construct useful for localizing the expression of promoters putatively associated with mycorrhization was developed and tested.ConclusionsIn this study, we present an easy, fast and low-cost procedure to study AM symbiosis in tomato roots.
D14 and KAI2 receptors enable plants to distinguish between strigolactones (SLs) and karrikins (KARs), respectively, in order to trigger appropriate environmental and developmental responses. Both receptors are related to the regulation of arbuscular mycorrhiza (AM) formation and are members of the RsbQ-like family of a,b-hydrolases. DLK2 proteins, whose function remains unknown, constitute a third clade from the RsbQ-like protein family. We investigated whether the tomato SlDLK2 is a new regulatory component in the AM symbiosis. Genetic approaches were conducted to analyze SlDLK2 expression and to understand SlDLK2 function in AM symbiosis. We show that SlDLK2 expression in roots is AM-dependent and is associated with cells containing arbuscules. SlDLK2 ectopic expression arrests arbuscule branching and downregulates AM-responsive genes, even in the absence of symbiosis; while the opposite effect was observed upon SlDLK2 silencing. Moreover, SlDLK2 overexpression in Medicago truncatula roots showed the same altered phenotype observed in tomato roots. Interestingly, SlDLK2 interacts with DELLA, a protein that regulates arbuscule formation/degradation in AM roots. We propose that SlDLK2 is a new component of the complex plant-mediated mechanism regulating the life cycle of arbuscules in AM symbiosis.
Histochemical staining and light microscopy-based techniques have been widely used to detect and quantify Arbuscular Mycorrhizal fungi (AMF) in roots. Here we describe a standardized method for staining of AMF in colonized roots, and we provide possible modifications to adjust the protocol according to particular requirements, such as the type of root material or the reduction of toxic products. In addition, we also summarize some of the most common ways to quantify arbuscular mycorrhizal colonization.
Ralstonia solanacearum is a devastating soil borne vascular pathogen that is able to infect a large range of plant species, causing an important threat to agriculture. However, the Ralstonia model is considerably under-explored in comparison to other models involving bacterial plant pathogens, such as Pseudomonas syringae in Arabidopsis. Research targeted to understanding the interaction between Ralstonia and crop plants is essential to develop sustainable solutions to fight against bacterial wilt disease, but is currently hindered by the lack of straightforward
17 18 KEYWORDS: 19 Tomato root transformation, Ralstonia solanacearum, bacterial wilt disease, Agrobacterium 20 rhizogenes, plant immunity, plant-microbe interaction, soil borne bacteria. 21 22 SUMMARY: 23 A versatile method for tomato root transformation followed by inoculation with Ralstonia 24 solanacearum to perform straightforward genetic analysis for the study of bacterial wilt 25 disease. 26 27 ABSTRACT: 28 Ralstonia solanacearum is a devastating soil borne vascular pathogen that is able to infect a 29 large range of plant species, causing an important threat to agriculture. However, the Ralstonia 30 model is considerably under-explored in comparison to other models involving bacterial plant 31 pathogens, such as Pseudomonas syringae in Arabidopsis. Research targeted to understanding 32 the interaction between Ralstonia and crop plants is essential to develop sustainable solutions 33 to fight against bacterial wilt disease, but is currently hindered by the lack of straightforward 34
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