Gioacchino Micheli scite author profile

M.Falconi and B.Colonna contributed equally to this workThe expression of plasmid-borne virF of Shigella encoding a transcriptional regulator of the AraC family, is required to initiate a cascade of events resulting in activation of several operons encoding invasion functions. H-NS, one of the main nucleoid-associated proteins, controls the temperature-dependent expression of the virulence genes by repressing the in vivo transcription of virF only below a critical temperature (~32°C). This temperature-dependent transcriptional regulation has been reproduced in vitro and the targets of H-NS on the virF promoter were identified as two sites centred around -250 and -1 separated by an intrinsic DNA curvature. H-NS bound cooperatively to these two sites below 32°C, but not at 37°C. DNA supercoiling within the virF promoter region did not influence H-NS binding but was necessary for the H-NS-mediated transcriptional repression. Electrophoretic analysis between 4 and 60°C showed that the virF promoter fragment, comprising the two H-NS sites, undergoes a specific and temperature-dependent conformational transition at~32°C. Our results suggest that this modification of the DNA target may modulate a cooperative interaction between H-NS molecules bound at two distant sites in the virF promoter region and thus represents the physical basis for the H-NS-dependent thermoregulation of virulence gene expression.

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ThevirFpromoter inShigella: more than just a curved DNA stretch

Prosseda

Falconi

Giangrossi

et al. 2004

Molecular Microbiology

150

161

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SummaryIn the human enteropathogen Shigella transcription of virF , the primary regulator of the invasion functions, is strictly temperature-dependent and is antagonistically mediated by H-NS and FIS, which bind to specific sites on the virF promoter. Here we report on the relevance of DNA geometry to the themoregulation of virF and demonstrate that the virF promoter hosts a major DNA bend halfway between two H-NS sites. The bent region has been mutagenized in vitro to mimic temperature-induced changes of DNA curvature. Functional analysis of curvature mutants and of promoter constructs in which the two H-NS sites are phased-out by a half-helix turn reveals that modifying the spatial relationships between these sites severely affects the interaction of H-NS with the virF promoter, as well as its in vivo and in vitro temperature-dependent activity. The role of promoter curvature as thermosensor is also compatible with the present observation that, with increasing temperature, the virF bending centre moves downstream at a rate having its maximum around the transition temperature, abruptly unmasking a binding site for the transcriptional activator FIS.

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A relationship between replicon size and supercoiled loop domains in the eukaryotic genome

Buongiorno-Nardelli¹,

Micheli²,

Carrı̀³

et al. 1982

Nature

198

107

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Polyamines: Emerging players in bacteria–host interactions

Martino

Campilongo

Casalino

et al. 2013

International Journal of Medical Microbiology

141

103

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A role for H-NS in the regulation of the virF gene of Shigella and enteroinvasive Escherichia coli

Prosseda

Fradiani

Lorenzo

et al. 1998

Research in Microbiology

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