Various gram-negative animal and plant pathogens use a novel, sec-independent protein secretion system as a basic virulence mechanism. It is becoming increasingly clear that these so-called type III secretion systems inject (translocate) proteins into the cytosol of eukaryotic cells, where the translocated proteins facilitate bacterial pathogenesis by specifically interfering with host cell signal transduction and other cellular processes. Accordingly, some type III secretion systems are activated by bacterial contact with host cell surfaces. Individual type III secretion systems direct the secretion and translocation of a variety of unrelated proteins, which account for species-specific pathogenesis phenotypes. In contrast to the secreted virulence factors, most of the 15 to 20 membrane-associated proteins which constitute the type III secretion apparatus are conserved among different pathogens. Most of the inner membrane components of the type III secretion apparatus show additional homologies to flagellar biosynthetic proteins, while a conserved outer membrane factor is similar to secretins from type II and other secretion pathways. Structurally conserved chaperones which specifically bind to individual secreted proteins play an important role in type III protein secretion, apparently by preventing premature interactions of the secreted factors with other proteins. The genes encoding type III secretion systems are clustered, and various pieces of evidence suggest that these systems have been acquired by horizontal genetic transfer during evolution. Expression of type III secretion systems is coordinately regulated in response to host environmental stimuli by networks of transcription factors. This review comprises a comparison of the structure, function, regulation, and impact on host cells of the type III secretion systems in the animal pathogens Yersinia spp., Pseudomonas aeruginosa, Shigella flexneri, Salmonella typhimurium, enteropathogenic Escherichia coli, and Chlamydia spp. and the plant pathogens Pseudomonas syringae, Erwinia spp., Ralstonia solanacearum, Xanthomonas campestris, and Rhizobium spp.

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Type III Protein Secretion Systems in Bacterial Pathogens of Animals and Plants

FLS2: an LRR receptor-like kinase involved in the perception of the bacterial elicitor flagellin in Arabidopsis.

The rice Xa21 gene, which confers resistance to Xanthomonas oryzae pv. oryzae race 6, was isolated by positional cloning. Fifty transgenic rice plants carrying the cloned Xa21 gene display high levels of resistance to the pathogen. The sequence of the predicted protein, which carries both a leucine-rich repeat motif and a serine-threonine kinase-like domain, suggests a role in cell surface recognition of a pathogen ligand and subsequent activation of an intracellular defense response. Characterization of Xa21 should facilitate understanding of plant disease resistance and lead to engineered resistance in rice.

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A Receptor Kinase-Like Protein Encoded by the Rice Disease Resistance Gene, Xa21

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A receptor kinase-like protein encoded by the rice disease resistance gene, Xa21. - eScholarship

Recognizing the enormous potential of DNA markers in plant breeding, many agricultural research centers and plant breeding institutes have adopted the capacity for marker development and marker-assisted selection (MAS). However, due to rapid developments in marker technology, statistical methodology for identifying quantitative trait loci (QTLs) and the jargon used by molecular biologists, the utility of DNA markers in plant breeding may not be clearly understood by non-molecular biologists. This review provides an introduction to DNA markers and the concept of polymorphism, linkage analysis and map construction, the principles of QTL analysis and how markers may be applied in breeding programs using MAS. This review has been specifically written for readers who have only a basic knowledge of molecular biology and/or plant genetics. Its format is therefore ideal for conventional plant breeders, physiologists, pathologists, other plant scientists and students.

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An introduction to markers, quantitative trait loci (QTL) mapping and marker-assisted selection for crop improvement: The basic concepts

The Pto gene in tomato confers resistance to races of Pseudomonas syringae pv. tomato that carry the avirulence gene avrPto. A yeast artificial chromosome clone that spans the Pto region was identified and used to probe a leaf complementary DNA (cDNA) library. A cDNA clone was isolated that represents a gene family, at least six members of which genetically cosegregate with Pto. When susceptible tomato plants were transformed with a cDNA from this family, they were resistant to the pathogen. Analysis of the amino acid sequence revealed similarity to serine-threonine protein kinases, suggesting a role for Pto in a signal transduction pathway.

https://science.sciencemag.org/content/sci/262/5138/1432.full.pdf

Map-based cloning of a protein kinase gene conferring disease resistance in tomato

T he extraction of DNA from plant tissue is a critical and often very time-consuming step in many plant molecular biology procedures. This is especially true for studies of molecular genetics, QTLs, or molecular-marker-based breeding where hundreds or even thousands of plant samples need to be analyzed in a short period of time. Many protocols are laborious and are limited by the need for large amounts of plant tissue. Based on the methods originally described by Murray et al. (1980), we have developed a procedure in our laboratory that maximizes the number of plant samples one person can extract and that yields sufficient DNA for 50 to 100 PCR reactions or two to four Southern blots. The use of very small, new leaves makes it possible to extract DNA from seedlings only one to three weeks old, reducing the need for large amounts of greenhouse space. The entire procedure can be done in 1.5-mL microcentrifuge tubes, eliminating the need for large centrifuges. Using this procedure, one person can isolate DNA from several hundred plants per day. Materials and Solut ions

Microprep protocol for extraction of DNA from tomato and other herbaceous plants

Leaves of tomato cultivars that contain the Pto bacterial resistance locus develop small necrotic lesions within 24 hr after exposure to fenthion, an organophosphorous insecticide. Recently, the Pto gene was isolated and shown to be a putative serine/threonine protein kinase. Pto is one member of a multigene family that is clustered within a 400-kb region on chromosome 5. Here, we report that another member of this gene family, termed Fen, is responsible for the sensitivity to fenthion. Fen was isolated by map-based cloning using closely linked DNA markers to identify a yeast artificial chromosome clone that spanned the Pto region. After transformation with the Fen gene under control of the cauliflower mosaic virus (CaMV) 35S promoter, tomato plants that are normally insensitive to fenthion rapidly developed extensive necrotic lesions upon exposure to fenthion. Two related insecticides, fensulfothion and fenitrothion, also elicited necrotic lesions specifically on Fen-transformed plants. Transgenic tomato plants harboring integrated copies of the Pto gene under control of the CaMV 35S promoter displayed sensitivity to fenthion but to a lesser extent than did wild-type fenthion-sensitive plants. The Fen protein shares 80% identity (87% similarity) with Pto but does not confer resistance to Pseudomonas syringae pv tomato. These results suggest that Pto and Fen participate in the same signal transduction pathway.

A member of the tomato Pto gene family confers sensitivity to fenthion resulting in rapid cell death.

A simple and rapid PCR-based method has been developed for determining the genotype of seeds before germination. Single half-seeds of rice (Oryza sativa L.) and wheat (Triticum aestivum L. em. Thell.) were preincubated, without grinding, in an aqueous extraction buffer. The resulting supernatants were then used in polymerase chain reaction (PCR) with oligonucleotide primers corresponding to rice single-copy sequences or a wheat microsatellite repeat. PCR products of identical size were amplified using either the half-seed extract or DNA isolated from leaf tissue. The remnant half-seeds can be maintained in ordered arrays using microtiter plates allowing the recovery of selected genotypes. Pre-germination genotypic screening of seed populations as described in this report should be useful for a variety of applications in plant breeding and genetics studies.

Pre-germination genotypic screening using PCR amplification of half-seeds.

We report the tagging of a powdery mildew [Leveillula taurica (Lev.) Arnaud.] resistance gene (Lv) in tomato using RAPD and RFLP markers. DNA from a resistant (cv Laurica) and a susceptible cultivar were screened with 300 random primers that were used to amplify DNA of resistant and susceptible plants. Four primers yielded fragments that were unique to the resistant line and linked to the resistance gene in an F2 population. One of these amplified fragments, OP248, with a molecular weight of 0.7 kb, was subsequently mapped to chromosome 12, 1 cM away from CT134. Using RFLP markers located on chromosome 12, it was shown that approximately one half of chromosome 12 (about 42 cM), in the resistant variety is comprised of foreign DNA, presumably introgressed with the resistance gene from the wild species L. chilense. Further analysis of a backcross population revealed that the Lv gene lies in the 5.5-cM interval between RFLP markers, CT211 and CT219. As a prelude to map-based cloning of the Lv gene, we are currently enriching the density of markers in this region by a combination of RAPD primers and other techniques.

Julapark Chunwongse

Papers

Map-based cloning of a protein kinase gene conferring disease resistance in tomato

Microprep protocol for extraction of DNA from tomato and other herbaceous plants

A member of the tomato Pto gene family confers sensitivity to fenthion resulting in rapid cell death.

Pre-germination genotypic screening using PCR amplification of half-seeds.

Chromosomal localization and molecular-marker tagging of the powdery mildew resistance gene (Lv) in tomato