Nabil Arrach scite author profile

BackgroundRecent outbreaks of vegetable-associated gastroenteritis suggest that enteric pathogens colonize, multiply and persist in plants for extended periods of time, eventually infecting people. Genetic and physiological pathways, by which enterics colonize plants, are still poorly understood.Methodology/Principal FindingsTo better understand interactions between Salmonella enterica sv. Typhimurium and tomatoes, a gfp-tagged Salmonella promoter library was screened inside red ripe fruits. Fifty-one unique constructs that were potentially differentially regulated in tomato relative to in vitro growth were identified. The expression of a subset of these promoters was tested in planta using recombinase-based in vivo expression technology (RIVET) and fitness of the corresponding mutants was tested. Gene expression in Salmonella was affected by fruit maturity and tomato cultivar. A putative fadH promoter was upregulated most strongly in immature tomatoes. Expression of the fadH construct depended on the presence of linoleic acid, which is consistent with the reduced accumulation of this compound in mature tomato fruits. The cysB construct was activated in the fruit of cv. Hawaii 7997 (resistant to a race of Ralstonia solanacearum) more strongly than in the universally susceptible tomato cv. Bonny Best. Known Salmonella motility and animal virulence genes (hilA, flhDC, fliF and those encoded on the pSLT virulence plasmid) did not contribute significantly to fitness of the bacteria inside tomatoes, even though deletions of sirA and motA modestly increased fitness of Salmonella inside tomatoes.Conclusions/SignificanceThis study reveals the genetic basis of the interactions of Salmonella with plant hosts. Salmonella relies on a distinct set of metabolic and regulatory genes, which are differentially regulated in planta in response to host genotype and fruit maturity. This enteric pathogen colonizes tissues of tomatoes differently than plant pathogens, and relies little on its animal virulence genes for persistence within the fruit.

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Salmonella Promoters Preferentially Activated Inside Tumors

Arrach

Zhao

Porwollik

et al. 2008

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Salmonella enterica and avirulent derivatives prefer solid tumors over normal tissue in animal models. The identification of endogenous Salmonella promoters that are preferentially activated in tumors could further our understanding of this phenomenon. Toward this goal, a random library of S. enterica typhimurium 14028 genomic DNA was cloned upstream of a promoterless gene encoding the green fluorescent protein (GFP) TurboGFP. A population of Salmonella containing this library was injected i.v. into tumor-free nude mice and into human PC3 prostate tumors growing subcutaneously in nude mice. After 2 days, fluorescence-activated cell sorting was used to enrich for bacterial clones expressing GFP from spleens or tumors. The resulting libraries were hybridized to an oligonucleotide tiling array of the Salmonella genome. Eighty-six intergenic regions were found to be enriched in tumor samples but not in spleen. Twenty of these candidate promoters were also detected in the sequences of 100 random clones from a library enriched for expression in bacteria growing in tumors. Three candidate promoter clones were individually tested in vivo, and enhanced GFP expression in bacteria growing in tumor relative to spleen was confirmed. Two of the three clones (pflE and ansB promoter regions) are known to be induced in hypoxic conditions that pertain to many tumors. For many of the other candidate promoters preferentially induced in bacteria growing in tumors, regulatory mechanisms may not be related to hypoxia. The expression of therapeutics in Salmonella under the regulation of one or more promoters that are activated preferentially in tumors has the potential to improve the targeting of drug delivery. [Cancer Res 2008;68(12):4827–32]

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Mutants of the carotene cyclase domain of al-2 from Neurospora crassa

Arrach

Ávalos

2002

Mol Gen Genomics

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Phytoene synthase and carotene cyclase, two key enzymes in carotenoid biosynthesis, are encoded by two separate genes in bacteria and plants, but by a single bifunctional gene in fungi. The cyclase function has been demonstrated for the products of the genes crtYB from the basidiomycete Xanthophyllomyces dendrorhous, and for carRA and carRP from the zygomycetes Phycomyces blakesleeanus and Mucor circinelloides, respectively. These three genes are highly similar to al-2 from Neurospora crassa. Taking advantage of the high proportion of the final product of the carotenoid pathway that accumulates Neurospora when mycelium is illuminated at low temperature, we have isolated two mutants with a pale reddish pigmentation. Both mutants are complemented by the wild-type al-2 gene, and carry mutations in the al-2 domain to which cyclase activity has been attributed in other fungi. The mutants lack neurosporaxanthin and accumulate an unidentified reddish carotenoid, as shown by column chromatography and HPLC. The chemical and spectrophotometrical properties of this carotenoid are consistent with the absence of carotenoid cyclization, and indicate that the product of al-2 is bifunctional. The existence of a single gene responsible for phytoene synthase and carotene cyclase thus seems to be a widespread trait among filamentous fungi, as shown by the examples now known in a basidiomycete, two zygomycetes and one ascomycete.

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Nabil Arrach

Pushing the limits of detection: investigation of cell-free DNA for aneuploidy screening in embryos

Specific Responses of Salmonella enterica to Tomato Varieties and Fruit Ripeness Identified by In Vivo Expression Technology

Salmonella Promoters Preferentially Activated Inside Tumors

Mutants of the carotene cyclase domain of al-2 from Neurospora crassa

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