Locus of enterocyte effacement-encoded regulator

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The locus of enterocyte effacement-encoded regulator (Ler) is a regulatory protein that controls bacterial pathogenicity of enteropathogenic Escherichia coli (EPEC) and enterohemorrhagic Escherichia coli (EHEC). [1] More specifically, Ler regulates the locus of enterocyte effacement (LEE) pathogenicity island genes, which are responsible for creating intestinal attachment and effacing lesions and subsequent diarrhea: LEE1, LEE2, and LEE3. [1] LEE1, 2, and 3 carry the information necessary for a type III secretion system. The transcript encoding the Ler protein is the open reading frame 1 on the LEE1 operon. [1]

Contents

The mechanism of Ler regulation involves competition with histone-like nucleoid structuring protein (H-NS), a negative regulator of the LEE pathogenicity island. [2] Ler is regulated by many factors such as plasmid encoded regulator (Per), integration host factor, Fis, BipA, a positive regulatory loop involving GrlA, and quorum sensing mediated by luxS. [3] [4]

Mechanism

Ler positively regulates the LEE genes by competition with its homolog, H-NS. [5] H-NS silences LEE genes via rigid filament structures bound to the DNA that Ler disrupts and replaces through unknown mechanisms. [5] [6] Though little is known of the mechanism of Ler regulation, Ler interacts with DNA in specific ways. Ler binds DNA non-cooperatively, bends DNA in low concentrations, stiffens it in high concentration, and forms toroidal nucleoprotein complexes along DNA in vivo. [5] [7]

Regulation

The regulation of Ler and its transcript, ler, is complex and many-fold. The plasmid encoded regulator (per) directly activates the region of the LEE1 operon which encodes Ler. [1] Integration host factor is also a direct activator of ler and binds upstream of its promoter. [8]

Jeannette Barba and her colleagues at the National Autonomous University of Mexico elucidated a positive regulatory loop between Ler, ler, GrlA, and grlRA. GrlA is also a LEE encoded regulator of the LEE pathogenicity island. They found that GrlA activates ler, and that Ler activates grlRA indicating a loop of activation wherein a protein product activates a transcript whose protein product activates the transcript of the original protein. Ler activates grlRA only if H-NS is present, this is not the case for GrlA activation of ler. [4]

Quorum sensing plays a role in Ler regulation. LuxS is an important protein involved in quorum sensing, particularly in the synthesis of autoinducer molecules. Quorum-sensing E. coli regulator A (QseA) is found in LuxS systems and activates transcription of ler. [3] Fis, a nucleoid associated protein essential for EPEC's ability to form attaching and effacing lesions, partly acts through activation of Ler expression. [9] BipA, a ribosomal binding GTPase and prolific regulator of EPEC virulence, transcriptionally regulates Ler from an upstream position where it also regulates other genes. [10]

The Ler protein also represses its own transcript on the LEE1 operon through DNA looping which prevents RNA polymerase from completing transcription. [11] [12]

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References

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