Your search keyword '"Sarah C. Emerson"' showing total 2 results

1. Deciphering the Function of New Gonococcal Vaccine Antigens Using Phenotypic Microarrays

Author

Philip Proteau, Benjamin I. Baarda, Aleksandra E. Sikora, and Sarah C. Emerson

Subjects

0301 basic medicine, Fastidious organism, Membrane permeability, 030106 microbiology, Reverse vaccinology, Phenotype microarray, Computational biology, Biology, medicine.disease_cause, Microbiology, Phenotype, 03 medical and health sciences, Neisseria gonorrhoeae, medicine, DNA microarray, Bacterial outer membrane, Molecular Biology, Research Article

Abstract

The function and extracellular location of cell envelope proteins make them attractive candidates for developing vaccines against bacterial diseases, including challenging drug-resistant pathogens, such as Neisseria gonorrhoeae . A proteomics-driven reverse vaccinology approach has delivered multiple gonorrhea vaccine candidates; however, the biological functions of many of them remain to be elucidated. Herein, the functions of six gonorrhea vaccine candidates—NGO2121, NGO1985, NGO2054, NGO2111, NGO1205, and NGO1344—in cell envelope homeostasis were probed using phenotype microarrays under 1,056 conditions and a Δ bamE mutant (Δ ngo1780 ) as a reference of perturbed outer membrane integrity. Optimal growth conditions for an N. gonorrhoeae phenotype microarray assay in defined liquid medium were developed, which can be useful in other applications, including rapid and thorough antimicrobial susceptibility assessment. Our studies revealed 91 conditions having uniquely positive or negative effects on one of the examined mutants. A cluster analysis of 37 and 57 commonly beneficial and detrimental compounds, respectively, revealed three separate phenotype groups: NGO2121 and NGO1985; NGO1344 and BamE; and the trio of NGO1205, NGO2111, and NGO2054, with the last protein forming an independent branch of this cluster. Similar phenotypes were associated with loss of these vaccine candidates in the highly antibiotic-resistant WHO X strain. Based on their extensive sensitivity phenomes, NGO1985 and NGO2121 appear to be the most promising vaccine candidates. This study establishes the principle that phenotype microarrays can be successfully applied to a fastidious bacterial organism, such as N. gonorrhoeae . IMPORTANCE Innovative approaches are required to develop vaccines against prevalent and neglected sexually transmitted infections, such as gonorrhea. Herein, we have utilized phenotype microarrays in the first such investigation into Neisseria gonorrhoeae to probe the function of proteome-derived vaccine candidates in cell envelope homeostasis. Information gained from this screening can feed the vaccine candidate decision tree by providing insights into the roles these proteins play in membrane permeability, integrity, and overall N. gonorrhoeae physiology. The optimized screening protocol can be applied in investigations into the function of other hypothetical proteins of N. gonorrhoeae discovered in the expanding number of whole-genome sequences, in addition to revealing phenotypic differences between clinical and laboratory strains.

Published

2017

2. The Type II Secretion Pathway in Vibrio cholerae Is Characterized by Growth Phase-Dependent Expression of Exoprotein Genes and Is Positively Regulated by σE

Author

Ryan S. Simmons, Bo R. Park, Sarah C. Emerson, Ryszard A. Zielke, Mariko Nonogaki, and Aleksandra E. Sikora

Subjects

Time Factors, Transcription, Genetic, Operon, Immunology, Sigma Factor, Biology, medicine.disease_cause, Microbiology, Bacterial Proteins, Transcription (biology), medicine, Secretion, Cloning, Molecular, Gene, Vibrio cholerae, Regulation of gene expression, Cholera toxin, Gene Expression Regulation, Bacterial, Molecular Pathogenesis, Cell biology, Infectious Diseases, Regulon, Parasitology, Gene Deletion

Abstract

Vibrio cholerae , an etiological agent of cholera, circulates between aquatic reservoirs and the human gastrointestinal tract. The type II secretion (T2S) system plays a pivotal role in both stages of the lifestyle by exporting multiple proteins, including cholera toxin. Here, we studied the kinetics of expression of genes encoding the T2S system and its cargo proteins. We have found that under laboratory growth conditions, the T2S complex was continuously expressed throughout V. cholerae growth, whereas there was growth phase-dependent transcriptional activity of genes encoding different cargo proteins. Moreover, exposure of V. cholerae to different environmental cues encountered by the bacterium in its life cycle induced transcriptional expression of T2S. Subsequent screening of a V. cholerae genomic library suggested that σ E stress response, phosphate metabolism, and the second messenger 3′,5′-cyclic diguanylic acid (c-di-GMP) are involved in regulating transcriptional expression of T2S. Focusing on σ E , we discovered that the upstream region of the T2S operon possesses both the consensus σ E and σ 70 signatures, and deletion of the σ E binding sequence prevented transcriptional activation of T2S by RpoE. Ectopic overexpression of σ E stimulated transcription of T2S in wild-type and isogenic Δ rpoE strains of V. cholerae , providing additional support for the idea that the T2S complex belongs to the σ E regulon. Together, our results suggest that the T2S pathway is characterized by the growth phase-dependent expression of genes encoding cargo proteins and requires a multifactorial regulatory network to ensure appropriate kinetics of the secretory traffic and the fitness of V. cholerae in different ecological niches.

Published

2014