Pilin

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[[Image:N_Teeerminal_Hydrophobic.png|alt text]]
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Highly Conserved N-Terminal Helix of the Type IVb Pilin
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Highly Conserved N-Terminal Helix of the Type IVb Pilin

Revision as of 03:23, 26 March 2010

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Contents

Salmonella typhi type IVb pilin (PilS)


Introduction

Type IV pili play an important role in the pathogenesis of many bacterial species; they are a required component for the adhesion of bacteria to their target cells. For example, Type IV pili are required for infection by the pathogens that cause cholera, typhoid, pneumonia, gonorrhea, and meningitis [1]. They may also mediate transformation, modulate target-cell specificity and play a role in twitching motility [2].

Structure

Type IV pilin are homopolymers, composed of a single-chain pilin protein. A conserved 25 residue hydrophobic N terminal sequence is shared by all type IV pilins, as well as conserved pilus assembly machinery, and a unique N-methylated N-terminus. Type IVb pilins also contain a pair of conserved cysteines that form an intrachain disulphide bond. The type IVb pilus operon of S. typhi contains the piLS gene, which encodes a structural pilin [1]. The cysteine-containing region in the C-terminus is thought to play function via the formation of disulfides in CFTR adhesion and in the assembly of PilS to make the pilus of the bacterium. The highly conserved N-terminal hydrophobic tail functions as a oligomerization domain for fibre formation. Different protein folds for the type IVb pilins have been identified [2].


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                                                                     Highly Conserved N-Terminal Helix of the Type IVb  Pilin          


Function

Type IV pili are diverse in function; they mediate numerous cellular functions via their polymeric machinery. These functions include cell adhesion, signaling, phage attachment, surface motility, biofilm formation and DNA uptake by natural transformation. Specifically, the type IVb pilus of Salmonella typhi is the adhesion factor that allows the pathogen to enter into the gastrointestinal cells of humans with ease. The first step in S.typhi pathogenesis is the type IVb pilus self-mediated self-association in the anerobic human small intestine preceding the entry into the human intestine epithelium [1]. The target receptor for the S. typhi pilus is a sequence of ten residues from the first extracellular domain of cystic fibrosis transmembrane conductance regulator [2].





References

  1. 1.0 1.1 1.2 Balakrishna AM, Saxena AM, Mok HY, Swaminathan K. Structural basis of typhoid: Salmonella typhi type IVb pilin (PilS) and cystic fibrosis transmembrane conductance regulator interaction. Proteins. 2009 Nov 1;77(2):253-61. PMID:19626704 doi:10.1002/prot.22500
  2. 2.0 2.1 2.2 Asha M. Balakrishna,Yvonne Yih-Wan Tan, Henry Yu-Keung Mok,Anand M. Saxena,and Kunchithapadam Swaminathan. Crystallization and preliminary X-ray diffraction analysis of Salmonella typhi PilS. 2006 October 1; 62(Pt 10): 1024–1026
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