Abstract
Bordetella pertussis is an obligate human respiratory pathogen that causes the disease whooping cough. A whole cell vaccine (DTP) was developed in the 1940s and was subsequently replaced in the 1990s with a protein-based subunit acellular vaccine (DTaP; tdap). Today, we are observing a resurgence of whooping cough due to evolution of the pathogen and waning vaccine immunity. The use of vaccines decreased the need for basic research on this pathogen. As a result, numerous questions on the basic pathogenesis of B. pertussis remain to be answered. Microarrays and more recently, RNA sequencing (RNAseq), have allowed the field to describe the in vitro gene expression profiles of the pathogen growing in both virulent and avirulent phases; however, no published studies have described an in vivo transcriptome of the pathogen. To address this need, we have designed and evaluated workflows to characterize the in vivo transcriptome of B. pertussis during infection of the murine lung. During our initial studies, we observed that only 0.014% of the ~100 million 2x50bp illumina reads corresponded to the pathogen, which is insufficient for analysis. Therefore, we developed a simple protocol to filter the bacteria out of the tissue homogenates and separate bacterial cells from the host tissue. RNA is then prepared, quantified, and the B. pertussis to host RNA ratio is determined. Here, we present the protocol and discuss the uses and next directions for which this RNAseq workflow can be applied. With this strategy we plan to fully characterize the B. pertussis transcriptome when the pathogen is infecting the murine lung in order to identify expressed genes that encode potential new vaccine antigens that will facilitate the development of the next generation of pertussis vaccines.