Streptococcus Pneumoniae Cell-Wall-Localized Phosphoenolpyruvate Protein Phosphotransferase Can Function As an Adhesin: Identification of Its Host Target Molecules and Evaluation of Its Potential As a Vaccine

Overview

Journal PLoS One

Specialties General Medicine
Science

Date 2016 Mar 19

PMID 26990554

Citations 12

Authors

Yaffa Mizrachi Nebenzahl

Karin Blau

Tatyana Kushnir

Marilou Shagan

Maxim Portnoi

Aviad Cohen

Shalhevet Azriel

Itai Malka

Asad Adawi

Daniel Kafka

Shahar Dotan

Gali Guterman

Shany Troib

Tali Fishilevich

Jonathan M Gershoni

Alex Braiman

Andrea M Mitchell

Timothy J Mitchell

Nurith Porat

Inna Goliand

Vered Chalifa Caspi

Edwin Swiatlo

Michael Tal

Ronald Ellis

Natalie Elia

Ron Dagan

Affiliations

Soon will be listed here.

Abstract

In Streptococcus pneumonia, phosphoenolpyruvate protein phosphotransferase (PtsA) is an intracellular protein of the monosaccharide phosphotransferase systems. Biochemical and immunostaining methods were applied to show that PtsA also localizes to the bacterial cell-wall. Thus, it was suspected that PtsA has functions other than its main cytoplasmic enzymatic role. Indeed, recombinant PtsA and anti-rPtsA antiserum were shown to inhibit adhesion of S. pneumoniae to cultured human lung adenocarcinoma A549 cells. Screening of a combinatorial peptide library expressed in a filamentous phage with rPtsA identified epitopes that were capable of inhibiting S. pneumoniae adhesion to A549 cells. The insert peptides in the phages were sequenced, and homologous sequences were found in human BMPER, multimerin1, protocadherin19, integrinβ4, epsin1 and collagen type VIIα1 proteins, all of which can be found in A549 cells except the latter. Six peptides, synthesized according to the homologous sequences in the human proteins, specifically bound rPtsA in the micromolar range and significantly inhibited pneumococcal adhesion in vitro to lung- and tracheal-derived cell lines. In addition, the tested peptides inhibited lung colonization after intranasal inoculation of mice with S. pneumoniae. Immunization with rPtsA protected the mice against a sublethal intranasal and a lethal intravenous pneumococcal challenge. In addition, mouse anti rPtsA antiserum reduced bacterial virulence in the intravenous inoculation mouse model. These findings showed that the surface-localized PtsA functions as an adhesin, PtsA binding peptides derived from its putative target molecules can be considered for future development of therapeutics, and rPtsA should be regarded as a candidate for vaccine development.

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